Lithium-ion battery

Lithium-ion battery
A 3.6 V Li-ion battery from a Nokia 3310 mobile phone
Specific energy1–270 W⋅h/kg (3.6–972.0 kJ/kg)[1]
Energy density250–693 W⋅h/L (900–2,490 J/cm3)[2][3]
Specific power1–10,000 W/kg[1]
Charge/discharge efficiency80–90%[4]
Energy/consumer-price7.6 Wh/US$ (US$132/kWh)[5]
Self-discharge rate0.35% to 2.5% per month depending on state of charge[6]
Cycle durability400–1,200 cycles [7]
Nominal cell voltage3.6 / 3.7 / 3.8 / 3.85 V, LiFePO4 3.2 V, Li4Ti5O12 2.3 V

A lithium-ion or Li-ion battery is a type of rechargeable battery that uses the reversible intercalation of Li+ ions into electronically conducting solids to store energy. In comparison with other commercial rechargeable batteries, Li-ion batteries are characterized by higher specific energy, higher energy density, higher energy efficiency, a longer cycle life, and a longer calendar life. Also noteworthy is a dramatic improvement in lithium-ion battery properties after their market introduction in 1991: over the following 30 years, their volumetric energy density increased threefold while their cost dropped tenfold.[8]

There are at least 12 different chemistries of Li-ion batteries; see "List of battery types."

The invention and commercialization of Li-ion batteries may have had one of the greatest impacts of all technologies in human history,[9] as recognized by the 2019 Nobel Prize in Chemistry. More specifically, Li-ion batteries enabled portable consumer electronics, laptop computers, cellular phones, and electric cars, or what has been called the e-mobility revolution.[10] It also sees significant use for grid-scale energy storage as well as military and aerospace applications.

Lithium-ion cells can be manufactured to optimize energy or power density.[11] Handheld electronics mostly use lithium polymer batteries (with a polymer gel as an electrolyte), a lithium cobalt oxide (LiCoO
2
) cathode material, and a graphite anode, which together offer high energy density.[12][13] Lithium iron phosphate (LiFePO
4
), lithium manganese oxide (LiMn
2
O
4
spinel, or Li
2
MnO
3
-based lithium-rich layered materials, LMR-NMC), and lithium nickel manganese cobalt oxide (LiNiMnCoO
2
or NMC) may offer longer life and a higher discharge rate. NMC and its derivatives are widely used in the electrification of transport, one of the main technologies (combined with renewable energy) for reducing greenhouse gas emissions from vehicles.[14]

M. Stanley Whittingham conceived intercalation electrodes in the 1970s and created the first rechargeable lithium-ion battery, based on a titanium disulfide cathode and a lithium-aluminum anode, although it suffered from safety problems and was never commercialized.[15] John Goodenough expanded on this work in 1980 by using lithium cobalt oxide as a cathode.[16] The first prototype of the modern Li-ion battery, which uses a carbonaceous anode rather than lithium metal, was developed by Akira Yoshino in 1985 and commercialized by a Sony and Asahi Kasei team led by Yoshio Nishi in 1991.[17] M. Stanley Whittingham, John Goodenough, and Akira Yoshino were awarded the 2019 Nobel Prize in Chemistry for their contributions to the development of lithium-ion batteries.

Lithium-ion batteries can be a safety hazard if not properly engineered and manufactured because they have flammable electrolytes that, if damaged or incorrectly charged, can lead to explosions and fires. Much progress has been made in the development and manufacturing of safe lithium-ion batteries.[18] Lithium-ion solid-state batteries are being developed to eliminate the flammable electrolyte. Improperly recycled batteries can create toxic waste, especially from toxic metals, and are at risk of fire. Moreover, both lithium and other key strategic minerals used in batteries have significant issues at extraction, with lithium being water intensive in often arid regions and other minerals used in some Li-ion chemistries potentially being conflict minerals such as cobalt.[not verified in body] Both environmental issues have encouraged some researchers to improve mineral efficiency and find alternatives such as Lithium iron phosphate lithium-ion chemistries or non-lithium-based battery chemistries like iron-air batteries.

Research areas for lithium-ion batteries include extending lifetime, increasing energy density, improving safety, reducing cost, and increasing charging speed,[19][20] among others. Research has been under way in the area of non-flammable electrolytes as a pathway to increased safety based on the flammability and volatility of the organic solvents used in the typical electrolyte. Strategies include aqueous lithium-ion batteries, ceramic solid electrolytes, polymer electrolytes, ionic liquids, and heavily fluorinated systems.[21][22][23][24]

History

[edit]

Research on rechargeable Li-ion batteries dates to the 1960s; one of the earliest examples is a CuF
2
/Li battery developed by NASA in 1965. The breakthrough that produced the earliest form of the modern Li-ion battery was made by British chemist M. Stanley Whittingham in 1974, who first used titanium disulfide (TiS
2
) as a cathode material, which has a layered structure that can take in lithium ions without significant changes to its crystal structure. Exxon tried to commercialize this battery in the late 1970s, but found the synthesis expensive and complex, as TiS
2
is sensitive to moisture and releases toxic H
2
S
gas on contact with water. More prohibitively, the batteries were also prone to spontaneously catch fire due to the presence of metallic lithium in the cells. For this, and other reasons, Exxon discontinued the development of Whittingham's lithium-titanium disulfide battery.[25]

In 1980, working in separate groups Ned A. Godshall et al.,[26][27][28] and, shortly thereafter, Koichi Mizushima and John B. Goodenough, after testing a range of alternative materials, replaced TiS
2
with lithium cobalt oxide (LiCoO
2
, or LCO), which has a similar layered structure but offers a higher voltage and is much more stable in air. This material would later be used in the first commercial Li-ion battery, although it did not, on its own, resolve the persistent issue of flammability.[25]

These early attempts to develop rechargeable Li-ion batteries used lithium metal anodes, which were ultimately abandoned due to safety concerns, as lithium metal is unstable and prone to dendrite formation, which can cause short-circuiting. The eventual solution was to use an intercalation anode, similar to that used for the cathode, which prevents the formation of lithium metal during battery charging. The first to demonstrate lithium ion reversible intercalation into graphite anodes was Jürgen Otto Besenhard in 1974.[29][30] Besenhard used organic solvents such as carbonates, however these solvents decomposed rapidly providing short battery cycle life. Later, in 1980, Rachid Yazami used a solid organic electrolyte, polyethylene oxide, which was more stable.[31][32]

In 1985, Akira Yoshino at Asahi Kasei Corporation discovered that petroleum coke, a less graphitized form of carbon, can reversibly intercalate Li-ions at a low potential of ~0.5 V relative to Li+ /Li without structural degradation.[33] Its structural stability originates from its amorphous carbon regions, which serving as covalent joints to pin the layers together. Although it has a lower capacity compared to graphite (~Li0.5C6, 186 mAh g–1), it became the first commercial intercalation anode for Li-ion batteries owing to its cycling stability. In 1987, Yoshino patented what would become the first commercial lithium-ion battery using this anode. He used Goodenough's previously reported LiCoO2 as the cathode and a carbonate ester-based electrolyte. The battery was assembled in the discharged state, which made it safer and cheaper to manufacture. In 1991, using Yoshino's design, Sony began producing and selling the world's first rechargeable lithium-ion batteries. The following year, a joint venture between Toshiba and Asashi Kasei Co. also released a lithium-ion battery.[25]

Significant improvements in energy density were achieved in the 1990s by replacing Yoshino's soft carbon anode first with hard carbon and later with graphite. In 1990, Jeff Dahn and two colleagues at Dalhousie University (Canada) reported reversible intercalation of lithium ions into graphite in the presence of ethylene carbonate solvent (which is solid at room temperature and is mixed with other solvents to make a liquid). This represented the final innovation of the era that created the basic design of the modern lithium-ion battery.[34]

In 2010, global lithium-ion battery production capacity was 20 gigawatt-hours.[35] By 2016, it was 28 GWh, with 16.4 GWh in China.[36] Global production capacity was 767 GWh in 2020, with China accounting for 75%.[37] Production in 2021 is estimated by various sources to be between 200 and 600 GWh, and predictions for 2023 range from 400 to 1,100 GWh.[38]

In 2012, John B. Goodenough, Rachid Yazami and Akira Yoshino received the 2012 IEEE Medal for Environmental and Safety Technologies for developing the lithium-ion battery; Goodenough, Whittingham, and Yoshino were awarded the 2019 Nobel Prize in Chemistry "for the development of lithium-ion batteries".[39] Jeff Dahn received the ECS Battery Division Technology Award (2011) and the Yeager award from the International Battery Materials Association (2016).

In April 2023, CATL announced that it would begin scaled-up production of its semi-solid condensed matter battery that produces a then record 500 Wh/kg. They use electrodes made from a gelled material, requiring fewer binding agents. This in turn shortens the manufacturing cycle. One potential application is in battery-powered airplanes.[40][41][42] Another new development of lithium-ion batteries are flow batteries with redox-targeted solids, that use no binders or electron-conducting additives, and allow for completely independent scaling of energy and power.[43]

Design

[edit]
Cylindrical Panasonic 18650 lithium-ion cell before closing.
Lithium-ion battery monitoring electronics (over-charge and deep-discharge protection)
Left: AA alkaline battery. Right: 18650 lithium ion battery

Generally, the negative electrode of a conventional lithium-ion cell is graphite made from carbon. The positive electrode is typically a metal oxide or phosphate. The electrolyte is a lithium salt in an organic solvent.[44] The negative electrode (which is the anode when the cell is discharging) and the positive electrode (which is the cathode when discharging) are prevented from shorting by a separator.[45] The electrodes are connected to the powered circuit through two pieces of metal called current collectors.[46]

The negative and positive electrodes swap their electrochemical roles (anode and cathode) when the cell is charged. Despite this, in discussions of battery design the negative electrode of a rechargeable cell is often just called "the anode" and the positive electrode "the cathode".

In its fully lithiated state of LiC6, graphite correlates to a theoretical capacity of 1339 coulombs per gram (372 mAh/g).[47] The positive electrode is generally one of three materials: a layered oxide (such as lithium cobalt oxide), a polyanion (such as lithium iron phosphate) or a spinel (such as lithium manganese oxide).[48] More experimental materials include graphene-containing electrodes, although these remain far from commercially viable due to their high cost.[49]

Lithium reacts vigorously with water to form lithium hydroxide (LiOH) and hydrogen gas. Thus, a non-aqueous electrolyte is typically used, and a sealed container rigidly excludes moisture from the battery pack. The non-aqueous electrolyte is typically a mixture of organic carbonates such as ethylene carbonate and propylene carbonate containing complexes of lithium ions.[50] Ethylene carbonate is essential for making solid electrolyte interphase on the carbon anode,[51] but since it is solid at room temperature, a liquid solvent (such as propylene carbonate or diethyl carbonate) is added.

The electrolyte salt is almost always[citation needed] lithium hexafluorophosphate (LiPF
6
), which combines good ionic conductivity with chemical and electrochemical stability. The hexafluorophosphate anion is essential for passivating the aluminum current collector used for the positive electrode. A titanium tab is ultrasonically welded to the aluminum current collector. Other salts like lithium perchlorate (LiClO
4
), lithium tetrafluoroborate (LiBF
4
), and lithium bis(trifluoromethanesulfonyl)imide (LiC
2
F
6
NO
4
S
2
) are frequently used in research in tab-less coin cells, but are not usable in larger format cells,[52] often because they are not compatible with the aluminum current collector. Copper (with a spot-welded nickel tab) is used as the current collector at the negative electrode.

Current collector design and surface treatments may take various forms: foil, mesh, foam (dealloyed), etched (wholly or selectively), and coated (with various materials) to improve electrical characteristics.[46]

Depending on materials choices, the voltage, energy density, life, and safety of a lithium-ion cell can change dramatically. Current effort has been exploring the use of novel architectures using nanotechnology to improve performance. Areas of interest include nano-scale electrode materials and alternative electrode structures.[53]

Electrochemistry

[edit]

The reactants in the electrochemical reactions in a lithium-ion cell are the materials of the electrodes, both of which are compounds containing lithium atoms. Although many thousands of different materials have been investigated for use in lithium-ion batteries, only a very small number are commercially usable. All commercial Li-ion cells use intercalation compounds as active materials.[54] The negative electrode is usually graphite, although silicon is often mixed in to increase the capacity. The electrolyte is usually lithium hexafluorophosphate, dissolved in a mixture of organic carbonates. A number of different materials are used for the positive electrode, such as LiCoO2, LiFePO4, and lithium nickel manganese cobalt oxides.

During cell discharge the negative electrode is the anode and the positive electrode the cathode: electrons flow from the anode to the cathode through the external circuit. An oxidation half-reaction at the anode produces positively charged lithium ions and negatively charged electrons. The oxidation half-reaction may also produce uncharged material that remains at the anode. Lithium ions move through the electrolyte; electrons move through the external circuit toward the cathode where they recombine with the cathode material in a reduction half-reaction. The electrolyte provides a conductive medium for lithium ions but does not partake in the electrochemical reaction. The reactions during discharge lower the chemical potential of the cell, so discharging transfers energy from the cell to wherever the electric current dissipates its energy, mostly in the external circuit.

During charging these reactions and transports go in the opposite direction: electrons move from the positive electrode to the negative electrode through the external circuit. To charge the cell the external circuit has to provide electrical energy. This energy is then stored as chemical energy in the cell (with some loss, e. g., due to coulombic efficiency lower than 1).

Both electrodes allow lithium ions to move in and out of their structures with a process called insertion (intercalation) or extraction (deintercalation), respectively.

As the lithium ions "rock" back and forth between the two electrodes, these batteries are also known as "rocking-chair batteries" or "swing batteries" (a term given by some European industries).[55][56]

The following equations exemplify the chemistry (left to right: discharging, right to left: charging).

The negative electrode half-reaction for the graphite is[57][58]

The positive electrode half-reaction in the lithium-doped cobalt oxide substrate is

The full reaction being

The overall reaction has its limits. Overdischarging supersaturates lithium cobalt oxide, leading to the production of lithium oxide,[59] possibly by the following irreversible reaction:

Overcharging up to 5.2 volts leads to the synthesis of cobalt (IV) oxide, as evidenced by x-ray diffraction:[60]

The transition metal in the positive electrode, cobalt (Co), is reduced from Co4+
to Co3+
during discharge, and oxidized from Co3+
to Co4+
during charge.

The cell's energy is equal to the voltage times the charge. Each gram of lithium represents Faraday's constant/6.941, or 13,901 coulombs. At 3 V, this gives 41.7 kJ per gram of lithium, or 11.6 kWh per kilogram of lithium. This is a bit more than the heat of combustion of gasoline but does not consider the other materials that go into a lithium battery and that make lithium batteries many times heavier per unit of energy.

Note that the cell voltages involved in these reactions are larger than the potential at which an aqueous solutions would electrolyze.

Discharging and charging

[edit]

During discharge, lithium ions (Li+
) carry the current within the battery cell from the negative to the positive electrode, through the non-aqueous electrolyte and separator diaphragm.[61]

During charging, an external electrical power source applies an over-voltage (a voltage greater than the cell's own voltage) to the cell, forcing electrons to flow from the positive to the negative electrode. The lithium ions also migrate (through the electrolyte) from the positive to the negative electrode where they become embedded in the porous electrode material in a process known as intercalation.

Energy losses arising from electrical contact resistance at interfaces between electrode layers and at contacts with current collectors can be as high as 20% of the entire energy flow of batteries under typical operating conditions.[62]

The charging procedures for single Li-ion cells, and complete Li-ion batteries, are slightly different:

  • A single Li-ion cell is charged in two stages:[63][64]
  1. Constant current (CC)
  2. Constant voltage (CV)
  • A Li-ion battery (a set of Li-ion cells in series) is charged in three stages:
  1. Constant current
  2. Balance (only required when cell groups become unbalanced during use)
  3. Constant voltage

During the constant current phase, the charger applies a constant current to the battery at a steadily increasing voltage, until the top-of-charge voltage limit per cell is reached.

During the balance phase, the charger/battery reduces the charging current (or cycles the charging on and off to reduce the average current) while the state of charge of individual cells is brought to the same level by a balancing circuit until the battery is balanced. Balancing typically occurs whenever one or more cells reach their top-of-charge voltage before the other(s), as it is generally inaccurate to do so at other stages of the charge cycle. This is most commonly done by passive balancing, which dissipates excess charge as heat via resistors connected momentarily across the cells to be balanced. Active balancing is less common, more expensive, but more efficient, returning excess energy to other cells (or the entire pack) via a DC-DC converter or other circuitry. Balancing most often occurs during the constant voltage stage of charging, switching between charge modes until complete. The pack is usually fully charged only when balancing is complete, as even a single cell group lower in charge than the rest will limit the entire battery's usable capacity to that of its own. Balancing can last hours or even days, depending on the magnitude of the imbalance in the battery.

During the constant voltage phase, the charger applies a voltage equal to the maximum cell voltage times the number of cells in series to the battery, as the current gradually declines towards 0, until the current is below a set threshold of about 3% of initial constant charge current.

Periodic topping charge about once per 500 hours. Top charging is recommended to be initiated when voltage goes below 4.05 V/cell. [dubiousdiscuss]

Failure to follow current and voltage limitations can result in an explosion.[65][66]

Charging temperature limits for Li-ion are stricter than the operating limits. Lithium-ion chemistry performs well at elevated temperatures but prolonged exposure to heat reduces battery life. Li‑ion batteries offer good charging performance at cooler temperatures and may even allow "fast-charging" within a temperature range of 5 to 45 °C (41 to 113 °F).[67][better source needed] Charging should be performed within this temperature range. At temperatures from 0 to 5 °C charging is possible, but the charge current should be reduced. During a low-temperature (under 0 °C) charge, the slight temperature rise above ambient due to the internal cell resistance is beneficial. High temperatures during charging may lead to battery degradation and charging at temperatures above 45 °C will degrade battery performance, whereas at lower temperatures the internal resistance of the battery may increase, resulting in slower charging and thus longer charging times.[67][better source needed]

A lithium-ion battery from a laptop computer

Batteries gradually self-discharge even if not connected and delivering current. Li-ion rechargeable batteries have a self-discharge rate typically stated by manufacturers to be 1.5–2% per month.[68][69]

The rate increases with temperature and state of charge. A 2004 study found that for most cycling conditions self-discharge was primarily time-dependent; however, after several months of stand on open circuit or float charge, state-of-charge dependent losses became significant. The self-discharge rate did not increase monotonically with state-of-charge, but dropped somewhat at intermediate states of charge.[70] Self-discharge rates may increase as batteries age.[71] In 1999, self-discharge per month was measured at 8% at 21 °C, 15% at 40 °C, 31% at 60 °C.[72] By 2007, monthly self-discharge rate was estimated at 2% to 3%, and 2[6]–3% by 2016.[73]

By comparison, the self-discharge rate for NiMH batteries dropped, as of 2017, from up to 30% per month for previously common cells[74] to about 0.08–0.33% per month for low self-discharge NiMH batteries, and is about 10% per month in NiCd batteries.[citation needed]

Cathode

[edit]

There are three classes of commercial cathode materials in lithium-ion batteries: (1) layered oxides, (2) spinel oxides and (3) oxoanion complexes. All of them were discovered by John Goodenough and his collaborators.[75]

Layered Oxides

[edit]

LiCoO2 was used in the first commercial lithium-ion battery made by Sony in 1991. The layered oxides have a pseudo-tetrahedral structure comprising layers made of MO6 octahedra separated by interlayer spaces that allow for two-dimensional lithium-ion diffusion.[citation needed] The band structure of LixCoO2 allows for true electronic (rather than polaronic) conductivity. However, due to an overlap between the Co4+ t2g d-band with the O2- 2p-band, the x must be >0.5, otherwise O2 evolution occurs. This limits the charge capacity of this material to ~140 mA h g−1.[75]

Several other first-row (3d) transition metals also form layered LiMO2 salts. Some can be directly prepared from lithium oxide and M2O3 (e.g. for M=Ti, V, Cr, Co, Ni), while others (M= Mn or Fe) can be prepared by ion exchange from NaMO2. LiVO2, LiMnO2 and LiFeO2 suffer from structural instabilities (including mixing between M and Li sites) due to a low energy difference between octahedral and tetrahedral environments for the metal ion M. For this reason, they are not used in lithium-ion batteries.[75] However, Na+ and Fe3+ have sufficiently different sizes that NaFeO2 can be used in sodium-ion batteries.[76]

Similarly, LiCrO2 shows reversible lithium (de)intercalation around 3.2 V with 170–270 mAh/g.[77] However, its cycle life is short, because of disproportionation of Cr4+ followed by translocation of Cr6+ into tetrahedral sites.[78] On the other hand, NaCrO2 shows a much better cycling stability.[79] LiTiO2 shows Li+ (de)intercalation at a voltage of ~1.5 V, which is too low for a cathode material.

These problems leave LiCoO
2
and LiNiO
2
as the only practical layered oxide materials for lithium-ion battery cathodes. The cobalt-based cathodes show high theoretical specific (per-mass) charge capacity, high volumetric capacity, low self-discharge, high discharge voltage, and good cycling performance. Unfortunately, they suffer from a high cost of the material.[80] For this reason, the current trend among lithium-ion battery manufacturers is to switch to cathodes with higher Ni content and lower Co content.[81]

In addition to a lower (than cobalt) cost, nickel-oxide based materials benefit from the two-electron redox chemistry of Ni: in layered oxides comprising nickel (such as nickel-cobalt-manganese NCM and nickel-cobalt-aluminium oxides NCA), Ni cycles between the oxidation states +2 and +4 (in one step between +3.5 and +4.3 V),[82][75] cobalt- between +2 and +3, while Mn (usually >20%) and Al (typically, only 5% is needed)[83] remain in +4 and 3+, respectively. Thus increasing the Ni content increases the cyclable charge. For example, NCM111 shows 160 mAh/g, while LiNi0.8Co0.1Mn0.1O2 (NCM811) and LiNi0.8Co0.15Al0.05O2 (NCA) deliver a higher capacity of ~200 mAh/g.[84]

It is worth mentioning so-called "lithium-rich" cathodes, that can be produced from traditional NCM (LiMO2, where M=Ni, Co, Mn) layered cathode materials upon cycling them to voltages/charges corresponding to Li:M<0.5. Under such conditions a new semi-reversible redox transition at a higher voltage with ca. 0.4-0.8 electrons/metal site charge appears. This transition involves non-binding electron orbitals centered mostly on O atoms. Despite significant initial interest, this phenomenon did not result in marketable products because of the fast structural degradation (O2 evolution and lattice rearrangements) of such "lithium-rich" phases.[85]

Cubic oxides (spinels)

[edit]

LiMn2O4 adopts a cubic lattice, which allows for three-dimensional lithium-ion diffusion.[86] Manganese cathodes are attractive because manganese is less expensive than cobalt or nickel. The operating voltage of Li-LiMn2O4 battery is 4 V, and ca. one lithium per two Mn ions can be reversibly extracted from the tetrahedral sites, resulting in a practical capacity of <130 mA h g–1. However, Mn3+ is not a stable oxidation state, as it tends to disporportionate into insoluble Mn4+ and soluble Mn2+.[80][87] LiMn2O4 can also intercalate more than 0.5 Li per Mn at a lower voltage around +3.0 V. However, this results in an irreversible phase transition due to Jahn-Teller distortion in Mn3+:t2g3eg1, as well as disproportionation and dissolution of Mn3+.

An important improvement of Mn spinel are related cubic structures of the LiMn1.5Ni0.5O4 type, where Mn exists as Mn4+ and Ni cycles reversibly between the oxidation states +2 and +4.[75] This materials show a reversible Li-ion capacity of ca. 135 mAh/g around 4.7 V. Although such high voltage is beneficial for increasing the specific energy of batteries, the adoption of such materials is currently hindered by the lack of suitable high-voltage electrolytes.[88] In general, materials with a high nickel content are favored in 2023, because of the possibility of a 2-electron cycling of Ni between the oxidation states +2 and +4.

LiV2O4 (lithium vanadium oxide) operates as a lower (ca. +3.0 V) voltage than LiMn2O4, suffers from similar durability issues, is more expensive, and thus is not considered of practical interest.[89]

Oxoanionic/olivins

[edit]

Around 1980 Manthiram discovered that oxoanions (molybdates and tungstates in that particular case) cause a substantial positive shift in the redox potential of the metal-ion compared to oxides.[90] In addition, these oxoanionic cathode materials offer better stability/safety than the corresponding oxides. However, they also suffer from poor electronic conductivity due to the long distance between redox-active metal centers, which slows down the electron transport. This necessitates the use of small (less than 200 nm) cathode particles and coating each particle with a layer of electronically-conducting carbon.[91] This reduces the packing density of these materials.

Although numerous combinations of oxoanions (sulfate, phosphate, silicate) with various metals (mostly Mn, Fe, Co, Ni) have been studied, LiFePO4 is the only one that has been commercialized. Although it was originally used primarily for stationary energy storage due to its lower energy density compared to layered oxides,[92] it has begun to be widely used in electric vehicles since the 2020s.[93]

Positive electrode
Technology Major producers (2023) Target application Advantages
Lithium nickel manganese cobalt oxide
NMC, LiNixMnyCozO2
Ronbay Technology, Easpring, Ecopro, Umicore, L&F, Posco[94] Electric vehicles, power tools, grid energy storage Good specific energy and specific power density
Lithium nickel cobalt aluminium oxide
NCA, LiNiCoAlO2
Ronbay Technology, Ecopro[94] Electric vehicles, power tools, grid energy storage High energy density, good life span
Lithium nickel cobalt manganese aluminum oxide
NCMA, LiNi
0.89
Co
0.05
Mn
0.05
Al
0.01
O
2
LG Chem,[95] Hanyang University[96] Electric vehicles, grid energy storage Good specific energy, improved long-term cycling stability, faster charging
Lithium manganese oxide
LMO, LiMn2O4
Posco, L&F[94] Power tools, electric vehicles[97] Fast charging speed, cheap
Lithium iron phosphate
LFP, LiFePO4
Shenzhen Dynanonic, Hunan Yuneng, LOPAL, Ronbay Technology[94] Electric vehicles,[93] grid energy storage[92] Higher safety compared to layered oxides. Thermal stability >60 °C (140 °F)
Lithium cobalt oxide
LCO, LiCoO2
Easpring, Umicore[94] Handheld electronics[94] High energy density

Anode

[edit]

Negative electrode materials are traditionally constructed from graphite and other carbon materials, although newer silicon-based materials are being increasingly used (see Nanowire battery). In 2016, 89% of lithium-ion batteries contained graphite (43% artificial and 46% natural), 7% contained amorphous carbon (either soft carbon or hard carbon), 2% contained lithium titanate (LTO) and 2% contained silicon or tin-based materials.[98]

These materials are used because they are abundant, electrically conducting and can intercalate lithium ions to store electrical charge with modest volume expansion (~10%).[99] Graphite is the dominant material because of its low intercalation voltage and excellent performance. Various alternative materials with higher capacities have been proposed, but they usually have higher voltages, which reduces energy density.[100] Low voltage is the key requirement for anodes; otherwise, the excess capacity is useless in terms of energy density.

Negative electrode
Technology Energy density Durability Company Target application Comments
Graphite 260 Wh/kg Tesla The dominant negative electrode material used in lithium-ion batteries, limited to a capacity of 372 mAh/g.[47] Low cost and good energy density. Graphite anodes can accommodate one lithium atom for every six carbon atoms. Charging rate is governed by the shape of the long, thin graphene sheets that constitute graphite. While charging, the lithium ions must travel to the outer edges of the graphene sheet before coming to rest (intercalating) between the sheets. The circuitous route takes so long that they encounter congestion around those edges.[101]
Lithium titanate
LTO, Li4Ti5O12
Toshiba, Altairnano Automotive (Phoenix Motorcars), electrical grid (PJM Interconnection Regional Transmission Organization control area,[102] United States Department of Defense[103]), bus (Proterra) Improved output, charging time, durability (safety, operating temperature −50–70 °C (−58–158 °F)).[104]
Hard carbon Energ2[105] Home electronics Greater storage capacity.
Tin/cobalt alloy Sony Consumer electronics (Sony Nexelion battery) Larger capacity than a cell with graphite (3.5 Ah 18650-type cell).
Silicon/carbon 730 Wh/L
450 Wh/kg
Amprius[106] Smartphones, providing 5000 mAh capacity Uses < 10% with silicon nanowires combined with graphite and binders. Energy density: ~74 mAh/g.

Another approach used carbon-coated 15 nm thick crystal silicon flakes. The tested half-cell achieved 1200 mAh/g over 800 cycles.[107]

As graphite is limited to a maximum capacity of 372 mAh/g[47] much research has been dedicated to the development of materials that exhibit higher theoretical capacities and overcoming the technical challenges that presently encumber their implementation. The extensive 2007 Review Article by Kasavajjula et al.[108] summarizes early research on silicon-based anodes for lithium-ion secondary cells. In particular, Hong Li et al.[109] showed in 2000 that the electrochemical insertion of lithium ions in silicon nanoparticles and silicon nanowires leads to the formation of an amorphous Li-Si alloy. The same year, Bo Gao and his doctoral advisor, Professor Otto Zhou described the cycling of electrochemical cells with anodes comprising silicon nanowires, with a reversible capacity ranging from at least approximately 900 to 1500 mAh/g.[110]

Diamond-like carbon coatings can increase retention capacity by 40% and cycle life by 400% for lithium based batteries.[111]

To improve the stability of the lithium anode, several approaches to installing a protective layer have been suggested.[112] Silicon is beginning to be looked at as an anode material because it can accommodate significantly more lithium ions, storing up to 10 times the electric charge, however this alloying between lithium and silicon results in significant volume expansion (ca. 400%),[99] which causes catastrophic failure for the cell.[113] Silicon has been used as an anode material but the insertion and extraction of can create cracks in the material. These cracks expose the Si surface to an electrolyte, causing decomposition and the formation of a solid electrolyte interphase (SEI) on the new Si surface (crumpled graphene encapsulated Si nanoparticles). This SEI will continue to grow thicker, deplete the available , and degrade the capacity and cycling stability of the anode.

In addition to carbon- and silicon- based anode materials for lithium-ion batteries, high-entropy metal oxide materials are being developed. These conversion (rather than intercalation) materials comprise an alloy (or subnanometer mixed phases) of several metal oxides performing different functions. For example, Zn and Co can act as electroactive charge-storing species, Cu can provide an electronically conducting support phase and MgO can prevent pulverization.[114]

Electrolyte

[edit]

Liquid electrolytes in lithium-ion batteries consist of lithium salts, such as LiPF
6
, LiBF
4
or LiClO
4
in an organic solvent, such as ethylene carbonate, dimethyl carbonate, and diethyl carbonate.[115] A liquid electrolyte acts as a conductive pathway for the movement of cations passing from the negative to the positive electrodes during discharge. Typical conductivities of liquid electrolyte at room temperature (20 °C (68 °F)) are in the range of 10 mS/cm, increasing by approximately 30–40% at 40 °C (104 °F) and decreasing slightly at 0 °C (32 °F).[116] The combination of linear and cyclic carbonates (e.g., ethylene carbonate (EC) and dimethyl carbonate (DMC)) offers high conductivity and solid electrolyte interphase (SEI)-forming ability. Organic solvents easily decompose on the negative electrodes during charge. When appropriate organic solvents are used as the electrolyte, the solvent decomposes on initial charging and forms a solid layer called the solid electrolyte interphase,[117] which is electrically insulating, yet provides significant ionic conductivity. The interphase prevents further decomposition of the electrolyte after the second charge. For example, ethylene carbonate is decomposed at a relatively high voltage, 0.7 V vs. lithium, and forms a dense and stable interface.[118] Composite electrolytes based on POE (poly(oxyethylene)) provide a relatively stable interface.[119][120] It can be either solid (high molecular weight) and be applied in dry Li-polymer cells, or liquid (low molecular weight) and be applied in regular Li-ion cells. Room-temperature ionic liquids (RTILs) are another approach to limiting the flammability and volatility of organic electrolytes.[121]

Recent advances in battery technology involve using a solid as the electrolyte material. The most promising of these are ceramics.[122] Solid ceramic electrolytes are mostly lithium metal oxides, which allow lithium-ion transport through the solid more readily due to the intrinsic lithium. The main benefit of solid electrolytes is that there is no risk of leaks, which is a serious safety issue for batteries with liquid electrolytes.[123] Solid ceramic electrolytes can be further broken down into two main categories: ceramic and glassy. Ceramic solid electrolytes are highly ordered compounds with crystal structures that usually have ion transport channels.[124] Common ceramic electrolytes are lithium super ion conductors (LISICON) and perovskites. Glassy solid electrolytes are amorphous atomic structures made up of similar elements to ceramic solid electrolytes but have higher conductivities overall due to higher conductivity at grain boundaries.[125] Both glassy and ceramic electrolytes can be made more ionically conductive by substituting sulfur for oxygen. The larger radius of sulfur and its higher ability to be polarized allow higher conductivity of lithium. This contributes to conductivities of solid electrolytes are nearing parity with their liquid counterparts, with most on the order of 0.1 mS/cm and the best at 10 mS/cm.[126] An efficient and economic way to tune targeted electrolytes properties is by adding a third component in small concentrations, known as an additive.[127] By adding the additive in small amounts, the bulk properties of the electrolyte system will not be affected whilst the targeted property can be significantly improved. The numerous additives that have been tested can be divided into the following three distinct categories: (1) those used for SEI chemistry modifications; (2) those used for enhancing the ion conduction properties; (3) those used for improving the safety of the cell (e.g. prevent overcharging).[citation needed]

Electrolyte alternatives have also played a significant role, for example the lithium polymer battery. Polymer electrolytes are promising for minimizing the dendrite formation of lithium. Polymers are supposed to prevent short circuits and maintain conductivity.[112]

The ions in the electrolyte diffuse because there are small changes in the electrolyte concentration. Linear diffusion is only considered here. The change in concentration c, as a function of time t and distance x, is

In this equation, D is the diffusion coefficient for the lithium ion. It has a value of 7.5×10−10 m2/s in the LiPF
6
electrolyte. The value for ε, the porosity of the electrolyte, is 0.724.[128]

Formats

[edit]
Nissan Leaf's lithium-ion battery pack

Lithium-ion batteries may have multiple levels of structure. Small batteries consist of a single battery cell. Larger batteries connect cells in parallel into a module and connect modules in series and parallel into a pack. Multiple packs may be connected in series to increase the voltage.[129]

Cells

[edit]

Li-ion cells are available in various form factors, which can generally be divided into four types:[130]

  • Small cylindrical (solid body without terminals, such as those used in most e-bikes and most electric vehicle battery and older laptop batteries); they typically come in standard sizes.
  • Large cylindrical (solid body with large threaded terminals)
  • Flat or pouch (soft, flat body, such as those used in cell phones and newer laptops; these are lithium-ion polymer batteries.[131]
  • Rigid plastic case with large threaded terminals (such as electric vehicle traction packs)

Cells with a cylindrical shape are made in a characteristic "swiss roll" manner (known as a "jelly roll" in the US), which means it is a single long "sandwich" of the positive electrode, separator, negative electrode, and separator rolled into a single spool. The result is encased in a container. One advantage of cylindrical cells is faster production speed. One disadvantage can be a large radial temperature gradient at high discharge rates.

The absence of a case gives pouch cells the highest gravimetric energy density; however, many applications require containment to prevent expansion when their state of charge (SOC) level is high,[132] and for general structural stability. Both rigid plastic and pouch-style cells are sometimes referred to as prismatic cells due to their rectangular shapes.[133] Three basic battery types are used in 2020s-era electric vehicles: cylindrical cells (e.g., Tesla), prismatic pouch (e.g., from LG), and prismatic can cells (e.g., from LG, Samsung, Panasonic, and others).[13]

Lithium-ion flow batteries have been demonstrated that suspend the cathode or anode material in an aqueous or organic solution.[134][135]

As of 2014, the smallest Li-ion cell was pin-shaped with a diameter of 3.5 mm and a weight of 0.6 g, made by Panasonic.[136] A coin cell form factor is available for LiCoO2 cells, usually designated with a "LiR" prefix.[137][138]

Batteries may be equipped with temperature sensors, heating/cooling systems, voltage regulator circuits, voltage taps, and charge-state monitors. These components address safety risks like overheating and short circuiting.[139]

Uses

[edit]

Lithium ion batteries are used in a multitude of applications from consumer electronics, toys, power tools and electric vehicles.[140]

More niche uses include backup power in telecommunications applications. Lithium-ion batteries are also frequently discussed as a potential option for grid energy storage,[141] although as of 2020, they were not yet cost-competitive at scale.[142]

Performance

[edit]
Specific energy density100 to 250 W·h/kg (360 to 900 kJ/kg)[143]
Volumetric energy density250 to 680 W·h/L (900 to 2230 J/cm3)[144][145]
Specific power density1 to 10,000 W/kg[1]

Because lithium-ion batteries can have a variety of positive and negative electrode materials, the energy density and voltage vary accordingly.

The open-circuit voltage is higher than in aqueous batteries (such as lead–acid, nickel–metal hydride and nickel–cadmium).[146][failed verification] Internal resistance increases with both cycling and age,[147] although this depends strongly on the voltage and temperature the batteries are stored at.[148] Rising internal resistance causes the voltage at the terminals to drop under load, which reduces the maximum current draw. Eventually, increasing resistance will leave the battery in a state such that it can no longer support the normal discharge currents requested of it without unacceptable voltage drop or overheating.

Batteries with a lithium iron phosphate positive and graphite negative electrodes have a nominal open-circuit voltage of 3.2 V and a typical charging voltage of 3.6 V. Lithium nickel manganese cobalt (NMC) oxide positives with graphite negatives have a 3.7 V nominal voltage with a 4.2 V maximum while charging. The charging procedure is performed at constant voltage with current-limiting circuitry (i.e., charging with constant current until a voltage of 4.2 V is reached in the cell and continuing with a constant voltage applied until the current drops close to zero). Typically, the charge is terminated at 3% of the initial charge current. In the past, lithium-ion batteries could not be fast-charged and needed at least two hours to fully charge. Current-generation cells can be fully charged in 45 minutes or less. In 2015 researchers demonstrated a small 600 mAh capacity battery charged to 68 percent capacity in two minutes and a 3,000 mAh battery charged to 48 percent capacity in five minutes. The latter battery has an energy density of 620 W·h/L. The device employed heteroatoms bonded to graphite molecules in the anode.[149]

Performance of manufactured batteries has improved over time. For example, from 1991 to 2005 the energy capacity per price of lithium-ion batteries improved more than ten-fold, from 0.3 W·h per dollar to over 3 W·h per dollar.[150] In the period from 2011 to 2017, progress has averaged 7.5% annually.[151] Overall, between 1991 and 2018, prices for all types of lithium-ion cells (in dollars per kWh) fell approximately 97%.[152] Over the same time period, energy density more than tripled.[152] Efforts to increase energy density contributed significantly to cost reduction.[153] Energy density can also be increased by improvements in the chemistry if the cell, for instance, by full or partial replacement of graphite with silicon. Silicon anodes enhanced with graphene nanotubes to eliminate the premature degradation of silicon open the door to reaching record-breaking battery energy density of up to 350 Wh/kg and lowering EV prices to be competitive with ICEs.[154]

Differently sized cells with similar chemistry can also have different energy densities. The 21700 cell has 50% more energy than the 18650 cell, and the bigger size reduces heat transfer to its surroundings.[145]

Round-trip efficiency

[edit]

The table below shows the result of an experimental evaluation of a "high-energy" type 3.0 Ah 18650 NMC cell in 2021, round-trip efficiency which compared the energy going into the cell and energy extracted from the cell from 100% (4.2v) SoC to 0% SoC (cut off 2.0v). A roundtrip efficiency is the percent of energy that can be used relative to the energy that went into charging the battery.[155]

C rate efficiency estimated charge efficiency estimated discharged efficiency
0.2 86% 93% 92%
0.4 82% 92% 90%
0.6 81% 91% 89%
0.8 77% 90% 86%
1.0 75% 89% 85%
1.2 73% 89% 83%

Characterization of a cell in a different experiment in 2017 reported round-trip efficiency of 85.5% at 2C and 97.6% at 0.1C[156]

Lifespan

[edit]

The lifespan of a lithium-ion battery is typically defined as the number of full charge-discharge cycles to reach a failure threshold in terms of capacity loss or impedance rise. Manufacturers' datasheet typically uses the word "cycle life" to specify lifespan in terms of the number of cycles to reach 80% of the rated battery capacity.[157] Simply storing lithium-ion batteries in the charged state also reduces their capacity (the amount of cyclable Li+) and increases the cell resistance (primarily due to the continuous growth of the solid electrolyte interface on the anode). Calendar life is used to represent the whole life cycle of battery involving both the cycle and inactive storage operations. Battery cycle life is affected by many different stress factors including temperature, discharge current, charge current, and state of charge ranges (depth of discharge).[158][159] Batteries are not fully charged and discharged in real applications such as smartphones, laptops and electric cars and hence defining battery life via full discharge cycles can be misleading. To avoid this confusion, researchers sometimes use cumulative discharge[158] defined as the total amount of charge (Ah) delivered by the battery during its entire life or equivalent full cycles,[159] which represents the summation of the partial cycles as fractions of a full charge-discharge cycle. Battery degradation during storage is affected by temperature and battery state of charge (SOC) and a combination of full charge (100% SOC) and high temperature (usually > 50 °C) can result in a sharp capacity drop and gas generation.[160] Multiplying the battery cumulative discharge by the rated nominal voltage gives the total energy delivered over the life of the battery. From this one can calculate the cost per kWh of the energy (including the cost of charging).

Over their lifespan batteries degrade gradually leading to reduced cyclable charge (a.k.a. Ah capacity) and increased resistance (the latter translates into a lower operating cell voltage).[161]

Several degradation processes occur in lithium-ion batteries, some during cycling, some during storage, and some all the time:[162][163][161] Degradation is strongly temperature-dependent: degradation at room temperature is minimal but increases for batteries stored or used in high temperature (usually > 35 °C) or low temperature (usually < 5 °C) environments.[164] High charge levels also hasten capacity loss.[165] Frequent over-charging (> 90%) and over-discharging (< 10%) may also hasten capacity loss.

In a study, scientists provided 3D imaging and model analysis to reveal main causes, mechanics, and potential mitigations of the problematic degradation of the batteries over charge cycles. They found "[p]article cracking increases and contact loss between particles and carbon-binder domain are observed to correlate with the cell degradation" and indicates that "the reaction heterogeneity within the thick cathode caused by the unbalanced electron conduction is the main cause of the battery degradation over cycling".[166][167][additional citation(s) needed]

The most common degradation mechanisms in lithium-ion batteries include:[168]

  1. Reduction of the organic carbonate electrolyte at the anode, which results in the growth of Solid Electrolyte Interface (SEI), where Li+ ions get irreversibly trapped, i.e. loss of lithium inventory. This shows as increased ohmic impedance and reduced Ah charge. At constant temperature, the SEI film thickness (and therefore, the SEI resistance and the loss in cyclable Li+) increases as a square root of the time spent in the charged state. The number of cycles is not a useful metric in characterizing this degradation pathway. Under high temperatures or in the presence of a mechanical damage the electrolyte reduction can proceed explosively.
  2. Lithium metal plating also results in the loss of lithium inventory (cyclable Ah charge), as well as internal short-circuiting and ignition of a battery. Once Li plating commences during cycling, it results in larger slopes of capacity loss per cycle and resistance increase per cycle. This degradation mechanism become more prominent during fast charging and low temperatures.
  3. Loss of the (negative or positive) electroactive materials due to dissolution (e.g. of Mn3+ species), cracking, exfoliation, detachment or even simple regular volume change during cycling. It shows up as both charge and power fade (increased resistance). Both positive and negative electrode materials are subject to fracturing due to the volumetric strain of repeated (de)lithiation cycles.
  4. Structural degradation of cathode materials, such as Li+/Ni2+ cation mixing in nickel-rich materials. This manifests as “electrode saturation", loss of cyclable Ah charge and as a "voltage fade".
  5. Other material degradations. Negative copper current collector is particularly prone to corrosion/dissolution at low cell voltages. PVDF binder also degrades, causing the detachment of the electroactive materials, and the loss of cyclable Ah charge.
Overview of the correlation between operational stress factors (the causes for degradation), the corresponding aging mechanisms, aging mode, and their effect on Lithium-ion batteries aging.

These are shown in the figure on the right. A change from one main degradation mechanism to another appears as a knee (slope change) in the capacity vs. cycle number plot.[168]

Most studies of lithium-ion battery aging have been done at elevated (50–60 °C) temperatures in order to complete the experiments sooner. Under these storage conditions, fully charged nickel-cobalt-aluminum and lithium-iron phosphate cells lose ca. 20% of their cyclable charge in 1–2 years. It is believed that the aforementioned anode aging is the most important degradation pathway in these cases. On the other hand, manganese-based cathodes show a (ca. 20–50%) faster degradation under these conditions, probably due to the additional mechanism of Mn ion dissolution.[163] At 25 °C the degradation of lithium-ion batteries seems to follow the same pathway(s) as the degradation at 50 °C, but with half the speed.[163] In other words, based on the limited extrapolated experimental data, lithium-ion batteries are expected to lose irreversibly ca. 20% of their cyclable charge in 3–5 years or 1000–2000 cycles at 25 °C.[168] Lithium-ion batteries with titanate anodes do not suffer from SEI growth, and last longer (>5000 cycles) than graphite anodes. However, in complete cells other degradation mechanisms (i.e. the dissolution of Mn3+ and the Ni2+/Li+ place exchange, decomposition of PVDF binder and particle detachment) show up after 1000–2000 days, and the use titanate anode does not improve full cell durability in practice.

Detailed degradation description

[edit]

A more detailed description of some of these mechanisms is provided below:

  1. The negative (anode) SEI layer, a passivation coating formed by electrolyte (such as ethylene carbonate, dimethyl carbonate but not propylene carbonate) reduction products, is essential for providing Li+ ion conduction, while preventing electron transfer (and, thus, further solvent reduction). Under typical operating conditions, the negative SEI layer reaches a fixed thickness after the first few charges (formation cycles), allowing the device to operate for years. However, at elevated temperatures or due to mechanical detachment of the negative SEI, this exothermic electrolyte reduction can proceed violently and lead to an explosion via several reactions.[162] Lithium-ion batteries are prone to capacity fading over hundreds[169] to thousands of cycles. Formation of the SEI consumes lithium ions, reducing the overall charge and discharge efficiency of the electrode material.[170] as a decomposition product, various SEI-forming additives can be added to the electrolyte to promote the formation of a more stable SEI that remains selective for lithium ions to pass through while blocking electrons.[171] Cycling cells at high temperature or at fast rates can promote the degradation of Li-ion batteries due in part to the degradation of the SEI or lithium plating.[172] Charging Li-ion batteries beyond 80% can drastically accelerate battery degradation.[173][174][175][176]

    Depending on the electrolyte and additives,[177] common components of the SEI layer that forms on the anode include a mixture of lithium oxide, lithium fluoride and semicarbonates (e.g., lithium alkyl carbonates). At elevated temperatures, alkyl carbonates in the electrolyte decompose into insoluble species such as Li
    2
    CO
    3
     that increases the film thickness. This increases cell impedance and reduces cycling capacity.[164] Gases formed by electrolyte decomposition can increase the cell's internal pressure and are a potential safety issue in demanding environments such as mobile devices.[162] Below 25 °C, plating of metallic Lithium on the anodes and subsequent reaction with the electrolyte is leading to loss of cyclable Lithium.[164] Extended storage can trigger an incremental increase in film thickness and capacity loss.[162] Charging at greater than 4.2 V can initiate Li+ plating on the anode, producing irreversible capacity loss.

    Electrolyte degradation mechanisms include hydrolysis and thermal decomposition.[162] At concentrations as low as 10 ppm, water begins catalyzing a number of degradation products that can affect the electrolyte, anode and cathode.[162] LiPF
    6
    participates in an equilibrium reaction with LiF and PF
    5
    . Under typical conditions, the equilibrium lies far to the left. However the presence of water generates substantial LiF, an insoluble, electrically insulating product. LiF binds to the anode surface, increasing film thickness.[162] LiPF
    6
    hydrolysis yields PF
    5
    , a strong Lewis acid that reacts with electron-rich species, such as water. PF
    5
    reacts with water to form hydrofluoric acid (HF) and phosphorus oxyfluoride. Phosphorus oxyfluoride in turn reacts to form additional HF and difluorohydroxy phosphoric acid. HF converts the rigid SEI film into a fragile one. On the cathode, the carbonate solvent can then diffuse onto the cathode oxide over time, releasing heat and potentially causing thermal runaway.[162] Decomposition of electrolyte salts and interactions between the salts and solvent start at as low as 70 °C. Significant decomposition occurs at higher temperatures. At 85 °C transesterification products, such as dimethyl-2,5-dioxahexane carboxylate (DMDOHC) are formed from EC reacting with DMC.[162]

    Batteries generate heat when being charged or discharged, especially at high currents. Large battery packs, such as those used in electric vehicles, are generally equipped with thermal management systems that maintain a temperature between 15 °C (59 °F) and 35 °C (95 °F).[178] Pouch and cylindrical cell temperatures depend linearly on the discharge current.[179] Poor internal ventilation may increase temperatures. For large batteries consisting of multiple cells, non-uniform temperatures can lead to non-uniform and accelerated degradation.[180] In contrast, the calendar life of LiFePO
    4
    cells is not affected by high charge states.[181][182]

    Positive SEI layer in lithium-ion batteries is much less understood than the negative SEI. It is believed to have a low-ionic conductivity and shows up as an increased interfacial resistance of the cathode during cycling and calendar aging.[162][163][161]
  2. Lithium plating is a phenomenon in which certain conditions lead to metallic lithium forming and depositing onto the surface of the battery’s anode rather than intercalating within the anode material’s structure. Low temperatures, overcharging and high charging rates can exacerbate this occurrence.[183][184] During these conditions, lithium ions may not intercalate uniformly into the anode material and form layers of lithium ion on the surface in the form of dendrites. Dendrites are tiny needle-like structures that can accumulate and pierce the separator, causing a short circuit can initiate thermal runaway.[162] This cascade of rapid and uncontrolled energy can lead to battery swelling, increased heat, fires and or explosions.[185] Additionally, this dendritic growth can lead to side reactions with the electrolyte and convert the fresh plated lithium into electrochemically inert dead lithium.[29] Moreover, the dendritic growth brought on by lithium plating can degrade the lithium-ion battery and lead to poor cycling efficiency and safety hazards. Some ways to mitigate lithium plating and the dendritic growth is by controlling the temperature, optimizing the charging conditions, and improving the materials used.[186] In terms of temperature, the ideal charging temperature is anywhere between 0 °C to 45 °C, but also room temperature is ideal (20 °C to 25 °C).[187] Advancements in materials innovation requires much research and development in the electrolyte selection and improving the anode resistance to plating. One such materials innovation would be to add other compounds to the electrolyte like fluoroethylene carbonate (FEC) to form a rich LiF SEI.[188] Another novel method would be to coat the separator in a protective shield that essentially “kills” the lithium ions before it can form these dendrites.[189]
  3. Certain manganese containing cathodes can degrade by the Hunter degradation mechanism resulting in manganese dissolution and reduction on the anode.[162] By the Hunter mechanism for LiMn
    2
    O
    4
    , hydrofluoric acid catalyzes the loss of manganese through disproportionation of a surface trivalent manganese to form a tetravalent manganese and a soluble divalent manganese:[162]
    2Mn3+ → Mn2++ Mn4+
    Material loss of the spinel results in capacity fade. Temperatures as low as 50 °C initiate Mn2+ deposition on the anode as metallic manganese with the same effects as lithium and copper plating.[164] Cycling over the theoretical max and min voltage plateaus destroys the crystal lattice via Jahn-Teller distortion, which occurs when Mn4+ is reduced to Mn3+ during discharge.[162] Storage of a battery charged to greater than 3.6 V initiates electrolyte oxidation by the cathode and induces SEI layer formation on the cathode. As with the anode, excessive SEI formation forms an insulator resulting in capacity fade and uneven current distribution.[162] Storage at less than 2 V results in the slow degradation of LiCoO
    2
    and LiMn
    2
    O
    4
    cathodes, the release of oxygen and irreversible capacity loss.[162]
  4. Discharging below 2 V can also result in the dissolution of the copper anode current collector and, thus, in catastrophic internal short-circuiting on recharge.

Recommendations

[edit]

The IEEE standard 1188–1996 recommends replacing lithium-ion batteries in an electric vehicle, when their charge capacity drops to 80% of the nominal value.[191] In what follows, we shall use the 20% capacity loss as a comparison point between different studies. We shall note, nevertheless, that the linear model of degradation (the constant % of charge loss per cycle or per calendar time) is not always applicable, and that a “knee point”, observed as a change of the slope, and related to the change of the main degradation mechanism, is often observed.[192]

Safety

[edit]

The problem of lithium-ion battery safety has been recognized even before these batteries were first commercially released in 1991. The two main reasons for lithium-ion battery fires and explosions are related to processes on the negative electrode (cathode). During a normal battery charge lithium ions intercalate into graphite. However, if the charge is forced to go too fast (or at a too low temperature) lithium metal starts plating on the anode, and the resulting dendrites can penetrate the battery separator, internally short-circuit the cell, resulting in high electric current, heating and ignition. In other mechanism, an explosive reaction between the charge anode material (LiC6) and the solvent (liquid organic carbonate) occurs even at open circuit, provided that the anode temperature exceeds a certain threshold above 70 °C.[193]

Nowadays, all reputable manufacturers employ at least two safety devices in all their lithium-ion batteries of an 18650 format or larger: a current interrupt (CID) device and a positive temperature coefficient (PTC) device. The CID comprises two metal disks, that make an electric contact with each other. When pressure inside the cell increases, the distance between the two disks increases too and they lose the electric contact with each other, thus terminating the flow of electric current through the battery. The PTC device is made of an electrically conducting polymer. When the current going through the PTC device increases, the polymer gets hot, and its electric resistance rises sharply, thus reducing the current through the battery.[194]

Fire hazard

[edit]

Lithium-ion batteries can be a safety hazard since they contain a flammable electrolyte and may become pressurized if they become damaged. A battery cell charged too quickly could cause a short circuit, leading to overheating, explosions, and fires.[195] A Li-ion battery fire can be started due to (1) thermal abuse, e.g. poor cooling or external fire, (2) electrical abuse, e.g. overcharge or external short circuit, (3) mechanical abuse, e.g. penetration or crash, or (4) internal short circuit, e.g. due to manufacturing flaws or aging.[196][197] Because of these risks, testing standards are more stringent than those for acid-electrolyte batteries, requiring both a broader range of test conditions and additional battery-specific tests, and there are shipping limitations imposed by safety regulators.[65][198][199] There have been battery-related recalls by some companies, including the 2016 Samsung Galaxy Note 7 recall for battery fires.[200][201]

Lithium-ion batteries have a flammable liquid electrolyte.[202] A faulty battery can cause a serious fire.[195] Faulty chargers can affect the safety of the battery because they can destroy the battery's protection circuit. While charging at temperatures below 0 °C, the negative electrode of the cells gets plated with pure lithium, which can compromise the safety of the whole pack.

Short-circuiting a battery will cause the cell to overheat and possibly to catch fire.[203] Smoke from thermal runaway in a Li-ion battery is both flammable and toxic.[204] The fire energy content (electrical + chemical) of cobalt-oxide cells is about 100 to 150 kJ/(A·h), most of it chemical.[unreliable source?][205]

Around 2010, large lithium-ion batteries were introduced in place of other chemistries to power systems on some aircraft; as of January 2014, there had been at least four serious lithium-ion battery fires, or smoke, on the Boeing 787 passenger aircraft, introduced in 2011, which did not cause crashes but had the potential to do so.[206][207] UPS Airlines Flight 6 crashed in Dubai after its payload of batteries spontaneously ignited.

To reduce fire hazards, research projects are intended to develop non-flammable electrolytes.[citation needed]

Damaging and overloading

[edit]

If a lithium-ion battery is damaged, crushed, or is subjected to a higher electrical load without having overcharge protection, then problems may arise. External short circuit can trigger a battery explosion.[208] Such incidents can occur when lithium-ion batteries are not disposed of through the appropriate channels, but are thrown away with other waste. The way they are treated by recycling companies can damage them and cause fires, which in turn can lead to large-scale conflagrations. Twelve such fires were recorded in Swiss recycling facilities in 2023.[209]

If overheated or overcharged, Li-ion batteries may suffer thermal runaway and cell rupture.[210][211] During thermal runaway, internal degradation and oxidization processes can keep cell temperatures above 500 °C, with the possibility of igniting secondary combustibles, as well as leading to leakage, explosion or fire in extreme cases.[212] To reduce these risks, many lithium-ion cells (and battery packs) contain fail-safe circuitry that disconnects the battery when its voltage is outside the safe range of 3–4.2 V per cell,[213][74] or when overcharged or discharged. Lithium battery packs, whether constructed by a vendor or the end-user, without effective battery management circuits are susceptible to these issues. Poorly designed or implemented battery management circuits also may cause problems; it is difficult to be certain that any particular battery management circuitry is properly implemented.

Voltage limits

[edit]

Lithium-ion cells are susceptible to stress by voltage ranges outside of safe ones between 2.5 and 3.65/4.1/4.2 or 4.35 V (depending on the components of the cell). Exceeding this voltage range results in premature aging and in safety risks due to the reactive components in the cells.[214] When stored for long periods the small current draw of the protection circuitry may drain the battery below its shutoff voltage; normal chargers may then be useless since the battery management system (BMS) may retain a record of this battery (or charger) "failure". Many types of lithium-ion cells cannot be charged safely below 0 °C,[215] as this can result in plating of lithium on the anode of the cell, which may cause complications such as internal short-circuit paths.[citation needed]

Other safety features are required[by whom?] in each cell:[213]

  • Shut-down separator (for overheating)
  • Tear-away tab (for internal pressure relief)
  • Vent (pressure relief in case of severe outgassing)
  • Thermal interrupt (overcurrent/overcharging/environmental exposure)

These features are required because the negative electrode produces heat during use, while the positive electrode may produce oxygen. However, these additional devices occupy space inside the cells, add points of failure, and may irreversibly disable the cell when activated. Further, these features increase costs compared to nickel metal hydride batteries, which require only a hydrogen/oxygen recombination device and a back-up pressure valve.[74] Contaminants inside the cells can defeat these safety devices. Also, these features can not be applied to all kinds of cells, e.g., prismatic high current cells cannot be equipped with a vent or thermal interrupt. High current cells must not produce excessive heat or oxygen, lest there be a failure, possibly violent. Instead, they must be equipped with internal thermal fuses which act before the anode and cathode reach their thermal limits.[216]

Replacing the lithium cobalt oxide positive electrode material in lithium-ion batteries with a lithium metal phosphate such as lithium iron phosphate (LFP) improves cycle counts, shelf life and safety, but lowers capacity. As of 2006, these safer lithium-ion batteries were mainly used in electric cars and other large-capacity battery applications, where safety is critical.[217] In 2016, an LFP-based energy storage system was chosen to be installed in Paiyun Lodge on Mt.Jade (Yushan) (the highest lodge in Taiwan). As of June 2024, the system was still operating safely.[218]

Recalls

[edit]

In 2006, approximately 10 million Sony batteries used in Dell, Sony, Apple, Lenovo, Panasonic, Toshiba, Hitachi, Fujitsu and Sharp laptops were recalled. The batteries were found to be susceptible to internal contamination by metal particles during manufacture. Under some circumstances, these particles could pierce the separator, causing a dangerous short circuit.[219]

Japan Airlines Boeing 787 lithium cobalt oxide battery that caught fire in 2013
Transport Class 9A:Lithium batteries

IATA estimates that over a billion lithium metal and lithium-ion cells are flown each year.[205] Some kinds of lithium batteries may be prohibited aboard aircraft because of the fire hazard.[220][221] Some postal administrations restrict air shipping (including EMS) of lithium and lithium-ion batteries, either separately or installed in equipment.

Non-flammable electrolyte

[edit]

In 2023, most commercial Li-ion batteries employed alkylcarbonate solvent(s) to assure the formation solid electrolyte interface on the negative electrode. Since such solvents are readily flammable, there has been active research to replace them with non-flammable solvents or to add fire suppressants. Another source of hazard is hexafluorophosphate anion, which is needed to passitivate the negative current collector made of aluminium. Hexafluorophosphate reacts with water and releases volatile and toxic hydrogen fluoride. Efforts to replace hexafluorophosphate have been less successful.

Supply chain

[edit]
The electric vehicle supply chain comprises the mining and refining of raw materials and the manufacturing processes that produce batteries and other components for electric vehicles.

In the 1990s, the United States was the World’s largest miner of lithium minerals, contributing to 1/3 of the total production. By 2010 Chile replaced the USA the leading miner, thanks to the development of lithium brines in Salar de Atacama. By 2024, Australia and China joined Chile as the top 3 miners. Li-ion battery production is also heavily concentrated, with 60% coming from China in 2024.[222]

Environmental impact

[edit]
Geographical distribution of the global battery supply chain in 2024[223]: 58 

Extraction of lithium, nickel, and cobalt, manufacture of solvents, and mining byproducts present significant environmental and health hazards.[224][225][226] Lithium extraction can be fatal to aquatic life due to water pollution.[227] It is known to cause surface water contamination, drinking water contamination, respiratory problems, ecosystem degradation and landscape damage.[224] It also leads to unsustainable water consumption in arid regions (1.9 million liters per ton of lithium).[224] Massive byproduct generation of lithium extraction also presents unsolved problems, such as large amounts of magnesium and lime waste.[228]

Lithium mining takes place in North and South America, Asia, South Africa, Australia, and China.[229]

Cobalt for Li-ion batteries is largely mined in the Congo (see also Mining industry of the Democratic Republic of the Congo). Open-pit cobalt mining has led to deforestation and habitat destruction in the Democratic Republic of Congo.[230]

Open-pit nickel mining has led to environmental degradation and pollution in developing countries such as the Philippines and Indonesia.[231][232] In 2024, nickel mining and processing was one of the main causes of deforestation in Indonesia.[233][234]

Manufacturing a kg of Li-ion battery takes about 67 megajoule (MJ) of energy.[235][236] The global warming potential of lithium-ion batteries manufacturing strongly depends on the energy source used in mining and manufacturing operations, and is difficult to estimate, but one 2019 study estimated 73 kg CO2e/kWh.[237] Effective recycling can reduce the carbon footprint of the production significantly.[238]

Solid waste and recycling

[edit]

Li-ion battery elements including iron, copper, nickel and cobalt are considered safe for incinerators and landfills.[239][citation needed] These metals can be recycled,[240][241] usually by burning away the other materials,[242] but mining generally remains cheaper than recycling;[243] recycling may cost $3/kg,[244] and in 2019 less than 5% of lithium-ion batteries were being recycled.[245] Since 2018, the recycling yield was increased significantly, and recovering lithium, manganese, aluminum, the organic solvents of the electrolyte, and graphite is possible at industrial scales.[246] The most expensive metal involved in the construction of the cell is cobalt. Lithium is less expensive than other metals used and is rarely recycled,[242] but recycling could prevent a future shortage.[240]

Accumulation of battery waste presents technical challenges and health hazards.[247] Since the environmental impact of electric cars is heavily affected by the production of lithium-ion batteries, the development of efficient ways to repurpose waste is crucial.[245] Recycling is a multi-step process, starting with the storage of batteries before disposal, followed by manual testing, disassembling, and finally the chemical separation of battery components. Re-use of the battery is preferred over complete recycling as there is less embodied energy in the process. As these batteries are a lot more reactive than classical vehicle waste like tire rubber, there are significant risks to stockpiling used batteries.[248]

Pyrometallurgical recovery

[edit]

The pyrometallurgical method uses a high-temperature furnace to reduce the components of the metal oxides in the battery to an alloy of Co, Cu, Fe, and Ni. This is the most common and commercially established method of recycling and can be combined with other similar batteries to increase smelting efficiency and improve thermodynamics. The metal current collectors aid the smelting process, allowing whole cells or modules to be melted at once.[249] The product of this method is a collection of metallic alloy, slag, and gas. At high temperatures, the polymers used to hold the battery cells together burn off and the metal alloy can be separated through a hydrometallurgical process into its separate components. The slag can be further refined or used in the cement industry. The process is relatively risk-free and the exothermic reaction from polymer combustion reduces the required input energy. However, in the process, the plastics, electrolytes, and lithium salts will be lost.[250]

Hydrometallurgical metals reclamation

[edit]

This method involves the use of aqueous solutions to remove the desired metals from the cathode. The most common reagent is sulfuric acid.[251] Factors that affect the leaching rate include the concentration of the acid, time, temperature, solid-to-liquid-ratio, and reducing agent.[252] It is experimentally proven that H2O2 acts as a reducing agent to speed up the rate of leaching through the reaction:[citation needed]

2 LiCoO2 (s) + 3 H2SO4 + H2O2 → 2 CoSO4 (aq) + Li2SO4 + 4 H2O + O2

Once leached, the metals can be extracted through precipitation reactions controlled by changing the pH level of the solution. Cobalt, the most expensive metal, can then be recovered in the form of sulfate, oxalate, hydroxide, or carbonate. [75] More recently recycling methods experiment with the direct reproduction of the cathode from the leached metals. In these procedures, concentrations of the various leached metals are premeasured to match the target cathode and then the cathodes are directly synthesized.[253]

The main issues with this method, however, is that a large volume of solvent is required and the high cost of neutralization. Although it's easy to shred up the battery, mixing the cathode and anode at the beginning complicates the process, so they will also need to be separated. Unfortunately, the current design of batteries makes the process extremely complex and it is difficult to separate the metals in a closed-loop battery system. Shredding and dissolving may occur at different locations.[254]

Direct recycling

[edit]

Direct recycling is the removal of the cathode or anode from the electrode, reconditioned, and then reused in a new battery. Mixed metal-oxides can be added to the new electrode with very little change to the crystal morphology. The process generally involves the addition of new lithium to replenish the loss of lithium in the cathode due to degradation from cycling. Cathode strips are obtained from the dismantled batteries, then soaked in NMP, and undergo sonication to remove excess deposits. It is treated hydrothermally with a solution containing LiOH/Li2SO4 before annealing.[255]

This method is extremely cost-effective for noncobalt-based batteries as the raw materials do not make up the bulk of the cost. Direct recycling avoids the time-consuming and expensive purification steps, which is great for low-cost cathodes such as LiMn2O4 and LiFePO4. For these cheaper cathodes, most of the cost, embedded energy, and carbon footprint is associated with the manufacturing rather than the raw material.[256] It is experimentally shown that direct recycling can reproduce similar properties to pristine graphite.

The drawback of the method lies in the condition of the retired battery. In the case where the battery is relatively healthy, direct recycling can cheaply restore its properties. However, for batteries where the state of charge is low, direct recycling may not be worth the investment. The process must also be tailored to the specific cathode composition, and therefore the process must be configured to one type of battery at a time.[257] Lastly, in a time with rapidly developing battery technology, the design of a battery today may no longer be desirable a decade from now, rendering direct recycling ineffective.

Physical materials separation

[edit]

Physical materials separation recovered materials by mechanical crushing and exploiting physical properties of different components such as particle size, density, ferromagnetism and hydrophobicity. Copper, aluminum and steel casing can be recovered by sorting. The remaining materials, called "black mass", which is composed of nickel, cobalt, lithium and manganese, need a secondary treatment to recover.[258]

Biological metals reclamation

[edit]

For the biological metals reclamation or bio-leaching, the process uses microorganisms to digest metal oxides selectively. Then, recyclers can reduce these oxides to produce metal nanoparticles. Although bio-leaching has been used successfully in the mining industry, this process is still nascent to the recycling industry and plenty of opportunities exists for further investigation.[258]

Electrolyte recycling

[edit]

Electrolyte recycling consists of two phases. The collection phase extracts the electrolyte from the spent Li-ion battery. This can be achieved through mechanical processes, distillation, freezing, solvent extraction, and supercritical fluid extraction. Due to the volatility, flammability, and sensitivity of the electrolyte, the collection process poses a greater difficulty than the collection process for other components of a Li-ion battery. The next phase consists of separation/electrolyte regeneration. Separation consists of isolating the individual components of the electrolyte. This approach is often used for the direct recovery of the Li salts from the organic solvents. In contrast, regeneration of the electrolyte aims to preserve the electrolyte composition by removing impurities which can be achieved through filtration methods.[259][260]

The recycling of the electrolytes, which consists 10-15 wt.% of the Li-ion battery, provides both an economic and environmental benefits. These benefits include the recovery of the valuable Li-based salts and the prevention of hazardous compounds, such as volatile organic compounds (VOCs) and carcinogens, being released into the environment.

Compared to electrode recycling, less focus is placed on recycling the electrolyte of Li-ion batteries which can be attributed to lower economic benefits and greater process challenges. Such challenges can include the difficulty associated with recycling different electrolyte compositions,[261] removing side products accumulated from electrolyte decomposition during its runtime,[262] and removal of electrolyte adsorbed onto the electrodes.[263] Due to these challenges, current pyrometallurgical methods of Li-ion battery recycling forgo electrolyte recovery, releasing hazardous gases upon heating. However, due to high energy consumption and environmental impact, future recycling methods are being directed away from this approach.[264]

Human rights impact

[edit]

Extraction of raw materials for lithium-ion batteries may present dangers to local people, especially land-based indigenous populations.[265]

Cobalt sourced from the Democratic Republic of the Congo is often mined by workers using hand tools with few safety precautions, resulting in frequent injuries and deaths.[266] Pollution from these mines has exposed people to toxic chemicals that health officials believe to cause birth defects and breathing difficulties.[267] Human rights activists have alleged, and investigative journalism reported confirmation,[268][269] that child labor is used in these mines.[270]

A study of relationships between lithium extraction companies and indigenous peoples in Argentina indicated that the state may not have protected indigenous peoples' right to free prior and informed consent, and that extraction companies generally controlled community access to information and set the terms for discussion of the projects and benefit sharing.[271]

Development of the Thacker Pass lithium mine in Nevada, USA has met with protests and lawsuits from several indigenous tribes who have said they were not provided free prior and informed consent and that the project threatens cultural and sacred sites.[272] Links between resource extraction and missing and murdered indigenous women have also prompted local communities to express concerns that the project will create risks to indigenous women.[273] Protestors have been occupying the site of the proposed mine since January, 2021.[274][275]

Research

[edit]

Researchers are actively working to improve the power density, safety, cycle durability (battery life), recharge time, cost, flexibility, and other characteristics, as well as research methods and uses, of these batteries. All-solid-state batteries are being researched as a breakthrough in technological barriers. Currently, all-solid-state batteries are expected to be the most promising next-generation battery, and various companies are working to popularize them.

See also

[edit]

References

[edit]
  1. ^ a b c "Specific power vs. specific energy of Li-Ion batteries distinguished by cell chemistry". Retrieved 3 November 2024.
  2. ^ "NCR18650B" (PDF). Panasonic. Archived from the original (PDF) on 17 August 2018. Retrieved 7 October 2016.
  3. ^ "NCR18650GA" (PDF). Archived (PDF) from the original on 8 March 2021. Retrieved 2 July 2017.
  4. ^ Valøen, Lars Ole; Shoesmith, Mark I. (1–2 November 2007). The effect of PHEV and HEV duty cycles on battery and battery pack performance (PDF). Proceedings of the Plug-in Highway Electric Vehicle Conference. Archived from the original (PDF) on 26 March 2009.
  5. ^ "Battery Pack Prices Fall to an Average of $132/kWh, But Rising Commodity Prices Start to Bite". Bloomberg New Energy Finance. 30 November 2021. Archived from the original on 6 January 2022. Retrieved 6 January 2022.
  6. ^ a b Redondo-Iglesias, Eduardo; Venet, Pascal; Pelissier, Serge (2016). "Measuring Reversible and Irreversible Capacity Losses on Lithium-Ion Batteries". 2016 IEEE Vehicle Power and Propulsion Conference (VPPC). p. 7. doi:10.1109/VPPC.2016.7791723. ISBN 978-1-5090-3528-1. S2CID 22822329. Archived from the original on 28 April 2021. Retrieved 20 October 2017.
  7. ^ Battery Types and Characteristics for HEV Archived 20 May 2015 at the Wayback Machine ThermoAnalytics, Inc., 2007. Retrieved 11 June 2010.
  8. ^ Ionic Liquid-Based Electrolytes for Sodium-Ion Batteries: Tuning Properties to Enhance the Electrochemical Performance of Manganese-Based Layered Oxide Cathode. 2019. ACS Applied Materials and Interfaces. L.G. Chagas, S. Jeong, I. Hasa, S. Passerini. doi: 10.1021/acsami.9b03813.
  9. ^ The lithium-ion battery: State of the art and future perspectives. 2018. Renew Sust Energ Rev. 89/292-308. G. Zubi, R. Dufo-Lopez, M. Carvalho, G. Pasaoglu. doi: 10.1016/j.rser.2018.03.002.
  10. ^ "E-Mobility Revolution : Lithium-Ion Batteries Powering the Transportation Industry – Evolute". 29 September 2023. Archived from the original on 27 October 2023. Retrieved 27 October 2023.
  11. ^ Lain, Michael J.; Brandon, James; Kendrick, Emma (December 2019). "Design Strategies for High Power vs. High Energy Lithium Ion Cells". Batteries. 5 (4): 64. doi:10.3390/batteries5040064. Commercial lithium ion cells are now optimized for either high energy density or high power density. There is a trade-off in cell design between power and energy requirements.
  12. ^ Mauger, A; Julien, C.M. (28 June 2017). "Critical review on lithium-ion batteries: are they safe? Sustainable?" (PDF). Ionics. 23 (8): 1933–1947. doi:10.1007/s11581-017-2177-8. S2CID 103350576. Archived (PDF) from the original on 2 March 2023. Retrieved 26 July 2019.
  13. ^ a b Mark Ellis, Sandy Munro (4 June 2020). Sandy Munro on Tesla's Battery Tech Domination (video). E for Electric. Event occurs at 3:53–5:50. Archived from the original on 7 July 2022. Retrieved 29 June 2020 – via YouTube.
  14. ^ Zhang, Runsen; Fujimori, Shinichiro (19 February 2020). "The role of transport electrification in global climate change mitigation scenarios". Environmental Research Letters. 15 (3): 034019. Bibcode:2020ERL....15c4019Z. doi:10.1088/1748-9326/ab6658. hdl:2433/245921. ISSN 1748-9326. S2CID 212866886.
  15. ^ "Binghamton professor recognized for energy research". The Research Foundation for the State University of New York. Archived from the original on 30 October 2017. Retrieved 10 October 2019.
  16. ^ "The Nobel Prize in Chemistry 2019". Nobel Prize. Nobel Foundation. 2019. Archived from the original on 21 May 2020. Retrieved 1 January 2020.
  17. ^ "Yoshio Nishi". National Academy of Engineering. Archived from the original on 11 April 2019. Retrieved 12 October 2019.
  18. ^ Chen, Yuqing; Kang, Yuqiong; Zhao, Yun; Wang, Li; Liu, Jilei; Li, Yanxi; Liang, Zheng; He, Xiangming; Li, Xing; Tavajohi, Naser; Li, Baohua (2021). "A review of lithium-ion battery safety concerns: The issues, strategies, and testing standards". Journal of Energy Chemistry. 59: 83–99. Bibcode:2021JEnCh..59...83C. doi:10.1016/j.jechem.2020.10.017. S2CID 228845089.
  19. ^ Eftekhari, Ali (2017). "Lithium-Ion Batteries with High Rate Capabilities". ACS Sustainable Chemistry & Engineering. 5 (3): 2799–2816. doi:10.1021/acssuschemeng.7b00046.
  20. ^ "Rising Lithium Costs Threaten Grid-Scale Energy Storage – News". eepower.com. Archived from the original on 9 June 2022. Retrieved 2 November 2022.
  21. ^ Hopkins, Gina (16 November 2017). "Watch: Cuts and dunks don't stop new lithium-ion battery – Futurity". Futurity. Archived from the original on 10 July 2018. Retrieved 10 July 2018.
  22. ^ Chawla, N.; Bharti, N.; Singh, S. (2019). "Recent Advances in Non-Flammable Electrolytes for Safer Lithium-Ion Batteries". Batteries. 5: 19. doi:10.3390/batteries5010019.
  23. ^ Yao, X.L.; Xie, S.; Chen, C.; Wang, Q.S.; Sun, J.; Wang, Q.S.; Sun, J. (2004). "Comparative study of trimethyl phosphite and trimethyl phosphate as electrolyte additives in lithium ion batteries". Journal of Power Sources. 144: 170–175. doi:10.1016/j.jpowsour.2004.11.042.
  24. ^ Fergus, J.W. (2010). "Ceramic and polymeric solid electrolytes for lithium-ion batteries". Journal of Power Sources. 195 (15): 4554–4569. Bibcode:2010JPS...195.4554F. doi:10.1016/j.jpowsour.2010.01.076.
  25. ^ a b c Li, Matthew; Lu, Jun; Chen, Zhongwei; Amine, Khalil (14 June 2018). "30 Years of Lithium-Ion Batteries". Advanced Materials. 30 (33): 1800561. Bibcode:2018AdM....3000561L. doi:10.1002/adma.201800561. ISSN 0935-9648. OSTI 1468617. PMID 29904941. S2CID 205286653.
  26. ^ Godshall, N.A.; Raistrick, I.D.; Huggins, R.A. (1980). "Thermodynamic investigations of ternary lithium-transition metal-oxygen cathode materials". Materials Research Bulletin. 15 (5): 561. doi:10.1016/0025-5408(80)90135-X.
  27. ^ Godshall, Ned A. (17 October 1979) "Electrochemical and Thermodynamic Investigation of Ternary Lithium-Transition Metal-Oxide Cathode Materials for Lithium Batteries: Li2MnO4 spinel, LiCoO2, and LiFeO2", Presentation at 156th Meeting of the Electrochemical Society, Los Angeles, CA.
  28. ^ Godshall, Ned A. (18 May 1980) Electrochemical and Thermodynamic Investigation of Ternary Lithium-Transition Metal-Oxygen Cathode Materials for Lithium Batteries. Ph.D. Dissertation, Stanford University
  29. ^ a b Besenhard, J. O.; Fritz, H. P. (25 June 1974). "Cathodic reduction of graphite in organic solutions of alkali and NR4+ salts". Journal of Electroanalytical Chemistry and Interfacial Electrochemistry. 53 (2): 329–333. doi:10.1016/S0022-0728(74)80146-4. ISSN 0022-0728.
  30. ^ Li, Matthew; Lu, Jun; Chen, Zhongwei; Amine, Khalil (14 June 2018). "30 Years of Lithium-Ion Batteries". Advanced Materials. 30 (33): 1800561. Bibcode:2018AdM....3000561L. doi:10.1002/adma.201800561. ISSN 0935-9648. OSTI 1468617. PMID 29904941. S2CID 205286653.
  31. ^ International Meeting on Lithium Batteries, Rome, 27–29 April 1982, C.L.U.P. Ed. Milan, Abstract #23
  32. ^ Yazami, R.; Touzain, P. (1983). "A reversible graphite-lithium negative electrode for electrochemical generators". Journal of Power Sources. 9 (3): 365–371. Bibcode:1983JPS.....9..365Y. doi:10.1016/0378-7753(83)87040-2.
  33. ^ Yoshino, A., Sanechika, K. & Nakajima, T. Secondary battery. JP patent 1989293 (1985)
  34. ^ Fong, R.; von Sacken, U.; Dahn, Jeff (1990). "Studies of lithium intercalation into carbons using nonaqueous electrochemical cells". J. Electrochem. Soc. 137 (7): 2009–2013. Bibcode:1990JElS..137.2009F. doi:10.1149/1.2086855.
  35. ^ "Lithium-ion batteries for mobility and stationary storage applications". European Commission. Archived (PDF) from the original on 14 July 2019. global lithium-ion battery production from about 20GWh (~6.5bn€) in 2010
  36. ^ "Switching From Lithium-Ion Could Be Harder Than You Think". 19 October 2017. Archived from the original on 19 October 2017. Retrieved 20 October 2017.
  37. ^ Murray, Cameron (8 March 2022). "Europe and US will shave c.10% off China's Li-ion production capacity market share by 2030". Energy Storage News. Archived from the original on 8 March 2022. Retrieved 8 March 2022.
  38. ^ National Blueprint for Lithium Batteries (PDF) (Report). U.S. Department of Energy. October 2020. p. 12. Archived (PDF) from the original on 28 July 2021. Retrieved 1 August 2021.
  39. ^ "The Nobel Prize in Chemistry 2019". Nobel Foundation. Archived from the original on 8 December 2019. Retrieved 4 June 2023.
  40. ^ Hanley, Steve (21 April 2023). "Condensed Matter Battery From CATL Targets Electric Airplanes". CleanTechnica. Archived from the original on 30 April 2023. Retrieved 30 April 2023.
  41. ^ "China's CATL unveils condensed matter battery to power civil aircraft". Reuters. 19 April 2023. Archived from the original on 30 April 2023. Retrieved 30 April 2023.
  42. ^ Warwick, Graham (19 April 2023). "China's CATL Targets Energy-Dense Battery At Electric Aircraft". Informa Markets. Aviation Week. Archived from the original on 30 April 2023. Retrieved 30 April 2023.
  43. ^ Flow batteries with solid energy boosters. 2022. J Electrochem Sci Eng. 12/4, 731–66. Y.V. Tolmachev, S.V. Starodubceva. doi: 10.5599/jese.1363.
  44. ^ Silberberg, M. (2006). Chemistry: The Molecular Nature of Matter and Change, 4th Ed. New York (NY): McGraw-Hill Education. p. 935, ISBN 0077216504.
  45. ^ Li, Ao; Yuen, Anthony Chun Yin; Wang, Wei; De Cachinho Cordeiro, Ivan Miguel; Wang, Cheng; Chen, Timothy Bo Yuan; Zhang, Jin; Chan, Qing Nian; Yeoh, Guan Heng (January 2021). "A Review on Lithium-Ion Battery Separators towards Enhanced Safety Performances and Modelling Approaches". Molecules. 26 (2): 478. doi:10.3390/molecules26020478. ISSN 1420-3049. PMC 7831081. PMID 33477513.
  46. ^ a b "A review of current collectors for lithium-ion batteries".
  47. ^ a b c G. Shao et al.: Polymer-Derived SiOC Integrated with a Graphene Aerogel As a Highly Stable Li-Ion Battery Anode ACS Appl. Mater. Interfaces 2020, 12, 41, 46045–46056
  48. ^ Thackeray, M. M.; Thomas, J. O.; Whittingham, M. S. (2011). "Science and Applications of Mixed Conductors for Lithium Batteries". MRS Bulletin. 25 (3): 39–46. doi:10.1557/mrs2000.17. S2CID 98644365.
  49. ^ El-Kady, Maher F.; Shao, Yuanlong; Kaner, Richard B. (July 2016). "Graphene for batteries, supercapacitors and beyond". Nature Reviews Materials. 1 (7): 16033. Bibcode:2016NatRM...116033E. doi:10.1038/natrevmats.2016.33.
  50. ^ MSDS: National Power Corp Lithium Ion Batteries Archived 26 June 2011 at the Wayback Machine (PDF). tek.com; Tektronix Inc., 7 May 2004. Retrieved 11 June 2010.
  51. ^ Revisiting the Ethylene Carbonate-Propylene Carbonate Mystery with Operando Characterization. 2022. Adv Mater Interfaces. 9/8, 7. T. Melin, R. Lundstrom, E.J. Berg. doi: 10.1002/admi.202101258.
  52. ^ Xu, Kang (1 October 2004). "Nonaqueous Liquid Electrolytes for Lithium-Based Rechargeable Batteries". Chemical Reviews. 104 (10): 4303–4418. doi:10.1021/cr030203g. PMID 15669157.
  53. ^ Joyce, C.; Trahy, L.; Bauer, S.; Dogan, F.; Vaughey, J. (2012). "Metallic Copper Binders for Lithium-Ion Battery Silicon Electrodes". Journal of the Electrochemical Society. 159 (6): 909–914. doi:10.1149/2.107206jes.
  54. ^ "Anode vs Cathode: What's the difference?". BioLogic. Archived from the original on 25 May 2023. Retrieved 25 May 2023.
  55. ^ Guyomard, Dominique; Tarascon, Jean-Marie (1994). "Rocking-chair or lithium-ion rechargeable lithium batteries". Advanced Materials. 6 (5): 408–412. Bibcode:1994AdM.....6..408G. doi:10.1002/adma.19940060516. ISSN 1521-4095.
  56. ^ Megahed, Sid; Scrosati, Bruno (1994). "Lithium-ion rechargeable batteries". Journal of Power Sources. 51 (1–2): 79–104. Bibcode:1994JPS....51...79M. doi:10.1016/0378-7753(94)01956-8.
  57. ^ Bergveld, H. J.; Kruijt, W. S.; Notten, P. H. L. (2002). Battery Management Systems: Design by Modelling. Springer. pp. 107–108, 113. ISBN 978-94-017-0843-2.
  58. ^ Dhameja, S (2001). Electric Vehicle Battery Systems. Newnes Press. p. 12. ISBN 978-075-06991-67.
  59. ^ Choi, H. C.; Jung, Y. M.; Noda, I.; Kim, S. B. (2003). "A Study of the Mechanism of the Electrochemical Reaction of Lithium with CoO by Two-Dimensional Soft X-ray Absorption Spectroscopy (2D XAS), 2D Raman, and 2D Heterospectral XAS−Raman Correlation Analysis". The Journal of Physical Chemistry B. 107 (24): 5806–5811. doi:10.1021/jp030438w.
  60. ^ Amatucci, G. G. (1996). "CoO
    2
    , the End Member of the Li
    x
    CoO
    2
    Solid Solution". Journal of the Electrochemical Society. 143 (3): 1114–1123. doi:10.1149/1.1836594.
  61. ^ Linden, David and Reddy, Thomas B. (eds.) (2002). Handbook of Batteries 3rd Edition. McGraw-Hill, New York. chapter 35. ISBN 0-07-135978-8.
  62. ^ Zhai, C; et al. (2016). "Interfacial electro-mechanical behaviour at rough surfaces" (PDF). Extreme Mechanics Letters. 9: 422–429. Bibcode:2016ExML....9..422Z. doi:10.1016/j.eml.2016.03.021. hdl:1959.4/unsworks_60452. Archived (PDF) from the original on 19 April 2021. Retrieved 31 August 2020.
  63. ^ Chung, H. C. (2021). "Charge and discharge profiles of repurposed LiFePO4 batteries based on the UL 1974 standard". Scientific Data. 8 (1): 165. Bibcode:2021NatSD...8..165C. doi:10.1038/s41597-021-00954-3. PMC 8253776. PMID 34215731.
  64. ^ Wu, Xiaogang; Hu, Chen; Du, Jiuyu; Sun, Jinlei (2015). "Multistage CC-CV Charge Method for Li-Ion Battery". Mathematical Problems in Engineering. 2015: 1–10. doi:10.1155/2015/294793. ISSN 1024-123X.
  65. ^ a b Schweber, Bill (4 August 2015). "Lithium Batteries: The Pros and Cons". GlobalSpec. Archived from the original on 16 March 2017. Retrieved 15 March 2017.
  66. ^ "Design Review For: Advanced Electric Vehicle Battery Charger, ECE 445 Senior Design Project". 090521 courses.ece.illinois.edu. Archived from the original on 4 May 2013.
  67. ^ a b "Lithium Ion Rechargeable Batteries. Technical Handbook" (PDF). Archived from the original (PDF) on 11 April 2009.
  68. ^ Sanyo: Overview of Lithium Ion Batteries. Archived 3 March 2016 at the Wayback Machine, listing self-discharge rate of 2%/mo.
  69. ^ Sanyo: Harding energy specification. Archived 27 December 2015 at the Wayback Machine, listing self-discharge rate of 0.3%/mo.
  70. ^ Zimmerman, A. H. (2004). "Self-discharge losses in lithium-ion cells". IEEE Aerospace and Electronic Systems Magazine. 19 (2): 19–24. doi:10.1109/MAES.2004.1269687. S2CID 27324676.
  71. ^ Weicker, Phil (1 November 2013). A Systems Approach to Lithium-Ion Battery Management. Artech House. p. 214. ISBN 978-1-60807-659-8.
  72. ^ Abe, H.; Murai, T.; Zaghib, K. (1999). "Vapor-grown carbon fiber anode for cylindrical lithium ion rechargeable batteries". Journal of Power Sources. 77 (2): 110–115. Bibcode:1999JPS....77..110A. doi:10.1016/S0378-7753(98)00158-X. S2CID 98171072.
  73. ^ Vetter, Matthias; Lux, Stephan (2016). "Rechargeable Batteries with Special Reference to Lithium-Ion Batteries" (PDF). Storing Energy. Fraunhofer Institute for Solar Energy Systems ISE. p. 205. doi:10.1016/B978-0-12-803440-8.00011-7. ISBN 9780128034408. Archived (PDF) from the original on 21 October 2017. Retrieved 20 October 2017.
  74. ^ a b c Winter & Brodd 2004, p. 4259
  75. ^ a b c d e Manthiram, Arumugam (25 March 2020). "A reflection on lithium-ion battery cathode chemistry". Nature Communications. 11 (1): 1550. Bibcode:2020NatCo..11.1550M. doi:10.1038/s41467-020-15355-0. ISSN 2041-1723. PMC 7096394. PMID 32214093.
  76. ^ Okada, S. and Yamaki, J.-I. (2009). Iron-Based Rare-Metal-Free Cathodes. In Lithium Ion Rechargeable Batteries, K. Ozawa (Ed.). https://onlinelibrary.wiley.com/doi/10.1002/9783527629022.ch4 Archived 5 October 2023 at the Wayback Machine
  77. ^ Electrochemical performance of CrOx cathode material for high energy density lithium batteries. 2023. Int J Electrochem Sci. 18/2, 44. D. Liu, X. Mu, R. Guo, J. Xie, G. Yin, P. Zuo. doi: 10.1016/j.ijoes.2023.01.020.
  78. ^ Industrialization of Layered Oxide Cathodes for Lithium-Ion and Sodium-Ion Batteries: A Comparative Perspective. 2020. Energy Technol. 8/12, 13. J. Darga, J. Lamb, A. Manthiram. doi: 10.1002/ente.202000723.
  79. ^ K. Kubota, S. Kumakura, Y. Yoda, K. Kuroki, S. Komaba, Adv. Energy Mater. 2018, 8, 1703415
  80. ^ a b Nitta, Naoki; Wu, Feixiang; Lee, Jung Tae; Yushin, Gleb (2015). "Li-ion battery materials: present and future". Materials Today. 18 (5): 252–264. doi:10.1016/j.mattod.2014.10.040.
  81. ^ Fergus, Jeffrey (2010). "Recent developments in cathode materials for lithium ion batteries". Journal of Power Sources. 195 (4): 939–954. Bibcode:2010JPS...195..939F. doi:10.1016/j.jpowsour.2009.08.089.
  82. ^ Ohzuku, T., Ueda, A. & Nagayama, M. Electrochemistry and structural chemistry of LiNiO2 (R3m) for 4 volt secondary lithium cells. J. Electrochem. Soc. 140, 1862–1870 (1993).
  83. ^ W. Li, E.M. Erickson, A. Manthiram, Nat. Energy 5 (2020) 26–34
  84. ^ Nickel-rich layered oxide cathodes for lithium-ion batteries: Failure mechanisms and modification strategies. 2023. J Energy Storage. 58/. X. Zheng, Z. Cai, J. Sun, J. He, W. Rao, J. Wang, et al. doi: 10.1016/j.est.2022.106405 ; W. Li, E.M. Erickson, A. Manthiram, Nat. Energy 5 (2020) 26–34
  85. ^ Xies, Ying (2022). "Li-rich layered oxides: Structure, capacity and voltage fading mechanisms and solving strategies". Particuology. 61 (4): 1–10. doi:10.1016/j.partic.2021.05.011. S2CID 237933219.
  86. ^ "Lithium-Ion Batteries". Sigma Aldrich. Archived from the original on 5 January 2016. Retrieved 5 November 2015.
  87. ^ A reflection on lithium-ion battery cathode chemistry. 2020. Nature Communications. 11/1, 9. A. Manthiram. doi: 10.1038/s41467-020-15355-0
  88. ^ Nickel-rich layered oxide cathodes for lithium-ion batteries: Failure mechanisms and modification strategies. 2023. J Energy Storage. 58/. X. Zheng, Z. Cai, J. Sun, J. He, W. Rao, J. Wang, et al. doi: 10.1016/j.est.2022.106405.
  89. ^ de Picciotto, L. A. & Thackeray, M. M. Insertion/extraction reactions of lithium with LiV2O4. Mater. Res. Bull. 20, 1409–1420 (1985)
  90. ^ Gopalakrishnan, J. & Manthiram, A. Topochemically controlled hydrogen reduction of scheelite-related rare-earth metal molybdates. Dalton Trans. 3, 668–672 (1981) due to the inductive effect
  91. ^ Eftekhari, Ali (2017). "LiFePO4/C Nanocomposites for Lithium-Ion Batteries". Journal of Power Sources. 343: 395–411. Bibcode:2017JPS...343..395E. doi:10.1016/j.jpowsour.2017.01.080.
  92. ^ a b Olivetti, Elsa A.; Ceder, Gerbrand; Gaustad, Gabrielle G.; Fu, Xinkai (October 2017). "Lithium-Ion Battery Supply Chain Considerations: Analysis of Potential Bottlenecks in Critical Metals". Joule. 1 (2): 229–243. doi:10.1016/j.joule.2017.08.019.
  93. ^ a b Lienert, Paul (23 June 2023). "For EV batteries, lithium iron phosphate narrows the gap with nickel, cobalt". Reuters. Retrieved 10 November 2024.
  94. ^ a b c d e f Hettesheimer, Tim; Neef, Christoph; Rosellón Inclán, Inés; Link, Steffen; Schmaltz, Thomas; Schuckert, Felix; Stephan, Annegret; Stephan, Maximilian; Thielmann, Axel (2023). Lithium-Ion Battery Roadmap - Industrialization Perspectives toward 2030 (Report). Fraunhofer Institute for Systems and Innovation Research. doi:10.24406/publica-2153. Retrieved 10 November 2024.
  95. ^ Yang, Heekyong (22 November 2022). "LG Chem to invest over $3 billion to build U.S. battery cathode plant". Reuters. Archived from the original on 25 July 2023. Retrieved 25 July 2023.
  96. ^ Kim, Un-Hyuck; Kuo, Liang-Yin; Kaghazchi, Payam; Yoon, Chong S.; Sun, Yang-Kook (25 January 2019). "Quaternary Layered Ni-Rich NCMA Cathode for Lithium-Ion Batteries". ACS Energy Lett. 4 (2). American Chemical Society: 576–582. doi:10.1021/acsenergylett.8b02499. S2CID 139505460.
  97. ^ Elgendy, Mohamed (7 February 2024). "Exploring The Role of Manganese in Lithium-Ion Battery Technology". AZoM. Retrieved 10 November 2024.
  98. ^ Linsenmann, Fabian; Pritzl, Daniel; Gasteiger, Hubert A. (1 January 2021). "Comparing the Lithiation and Sodiation of a Hard Carbon Anode Using In Situ Impedance Spectroscopy". Journal of the Electrochemical Society. 168 (1): 010506. Bibcode:2021JElS..168a0506L. doi:10.1149/1945-7111/abd64e. ISSN 0013-4651. S2CID 234306808.
  99. ^ a b Hayner, CM; Zhao, X; Kung, HH (1 January 2012). "Materials for Rechargeable Lithium-Ion Batteries". Annual Review of Chemical and Biomolecular Engineering. 3 (1): 445–471. doi:10.1146/annurev-chembioeng-062011-081024. PMID 22524506.
  100. ^ Eftekhari, Ali (2017). "Low Voltage Anode Materials for Lithium-Ion Batteries". Energy Storage Materials. 7: 157–180. Bibcode:2017EneSM...7..157E. doi:10.1016/j.ensm.2017.01.009.
  101. ^ "Northwestern researchers advance Li-ion batteries with graphene-silicon sandwich | Solid State Technology". Electroiq.com. November 2011. Archived from the original on 15 March 2018. Retrieved 3 January 2019.
    Zhao, X.; Hayner, C. M.; Kung, M. C.; Kung, H. H. (2011). "In-Plane Vacancy-Enabled High-Power Si-Graphene Composite Electrode for Lithium-Ion Batteries". Advanced Energy Materials. 1 (6): 1079–1084. Bibcode:2011AdEnM...1.1079Z. doi:10.1002/aenm.201100426. S2CID 98312522.
  102. ^ "... Acceptance of the First Grid-Scale, Battery Energy Storage System" (Press release). Altair Nanotechnologies. 21 November 2008. Archived from the original on 3 August 2020. Retrieved 8 October 2009.
  103. ^ Ozols, Marty (11 November 2009). Altair Nanotechnologies Power Partner – The Military Archived 16 July 2011 at the Wayback Machine. Systemagicmotives (personal webpage)[dubiousdiscuss]. Retrieved 11 June 2010.
  104. ^ Gotcher, Alan J. (29 November 2006). "Altair EDTA Presentation" (PDF). Altairnano.com. Archived from the original (PDF) on 16 June 2007.
  105. ^ Synthetic Carbon Negative electrode Boosts Battery Capacity 30 Percent | MIT Technology Review. Technologyreview.com (2 April 2013). Retrieved 16 April 2013. Archived 4 April 2013 at the Wayback Machine
  106. ^ Blain, Loz (14 February 2022). "Amprius ships first batch of "world's highest density" batteries". New Atlas. Archived from the original on 14 February 2022. Retrieved 14 February 2022.
  107. ^ Coxworth, Ben (22 February 2017). "Silicon sawdust – coming soon to a battery near you?". newatlas.com. Archived from the original on 25 February 2017. Retrieved 26 February 2017.
  108. ^ Kasavajjula, U.; Wang, C.; Appleby, A.J. C.. (2007). "Nano- and bulk-silicon-based insertion anodes for lithium-ion secondary cells". Journal of Power Sources. 163 (2): 1003–1039. Bibcode:2007JPS...163.1003K. doi:10.1016/j.jpowsour.2006.09.084.
  109. ^ Li, H.; Huang, X.; Chenz, L. C.; Zhou, G.; Zhang, Z. (2000). "The crystal structural evolution of nano-Si anode caused by lithium insertion and extraction at room temperature". Solid State Ionics. 135 (1–4): 181–191. doi:10.1016/S0167-2738(00)00362-3.
  110. ^ Gao, B.; Sinha, S.; Fleming, L.; Zhou, O. (2001). "Alloy Formation in Nanostructured Silicon". Advanced Materials. 13 (11): 816–819. Bibcode:2001AdM....13..816G. doi:10.1002/1521-4095(200106)13:11<816::AID-ADMA816>3.0.CO;2-P.
  111. ^ Zia, Abdul Wasy; Hussain, Syed Asad; Rasul, Shahid; Bae, Dowon; Pitchaimuthu, Sudhagar (November 2023). "Progress in diamond-like carbon coatings for lithium-based batteries". Journal of Energy Storage. 72: 108803. Bibcode:2023JEnSt..7208803Z. doi:10.1016/j.est.2023.108803. S2CID 261197954.
  112. ^ a b Girishkumar, G.; McCloskey, B.; Luntz, A. C.; Swanson, S.; Wilcke, W. (2 July 2010). "Lithium−Air Battery: Promise and Challenges". The Journal of Physical Chemistry Letters. 1 (14): 2193–2203. doi:10.1021/jz1005384. ISSN 1948-7185.
  113. ^ "A Better Anode Design to Improve Lithium-Ion Batteries". Berkeley Lab: Lawrence Berkeley National Laboratory. Archived from the original on 4 March 2016.
  114. ^ O. Marques, M. Walter, E. Timofeeva, and C. Segre, Batteries, 9 115 (2023). 10.3390/batteries9020115.
  115. ^ Younesi, Reza; Veith, Gabriel M.; Johansson, Patrik; Edström, Kristina; Vegge, Tejs (2015). "Lithium salts for advanced lithium batteries: Li–metal, Li–O2, and Li–S". Energy Environ. Sci. 8 (7): 1905–1922. doi:10.1039/c5ee01215e.
  116. ^ Wenige, Niemann, et al. (30 May 1998). Liquid Electrolyte Systems for Advanced Lithium Batteries Archived 20 March 2009 at the Wayback Machine (PDF). cheric.org; Chemical Engineering Research Information Center(KR). Retrieved 11 June 2010.
  117. ^ Balbuena, P. B., Wang, Y. X. (eds) (2004). Lithium Ion Batteries: Solid Electrolyte Interphase, Imperial College Press, London. ISBN 1860943624.
  118. ^ Fong, R. A. (1990). "Studies of Lithium Intercalation into Carbons Using Nonaqueous Electrochemical Cells". Journal of the Electrochemical Society. 137 (7): 2009–2010. Bibcode:1990JElS..137.2009F. doi:10.1149/1.2086855.
  119. ^ Syzdek, J. A.; Borkowska, R.; Perzyna, K.; Tarascon, J. M.; Wieczorek, W. A. A. (2007). "Novel composite polymeric electrolytes with surface-modified inorganic fillers". Journal of Power Sources. 173 (2): 712–720. Bibcode:2007JPS...173..712S. doi:10.1016/j.jpowsour.2007.05.061.
  120. ^ Syzdek, J. A.; Armand, M.; Marcinek, M.; Zalewska, A.; Żukowska, G. Y.; Wieczorek, W. A. A. (2010). "Detailed studies on the fillers modification and their influence on composite, poly(oxyethylene)-based polymeric electrolytes". Electrochimica Acta. 55 (4): 1314–1322. doi:10.1016/j.electacta.2009.04.025.
  121. ^ Reiter, J.; Nádherná, M.; Dominko, R. (2012). "Graphite and LiCo1/3Mn1/3Ni1/3O2 electrodes with piperidinium ionic liquid and lithium bis(fluorosulfonyl)imide for Li-ion batteries". Journal of Power Sources. 205: 402–407. doi:10.1016/j.jpowsour.2012.01.003.
  122. ^ Can, Cao; Zhuo-Bin, Li; Xiao-Liang, Wang (2014). "Recent Advances in Inorganic Solid Electrolytes for Lithium Batteries". Frontiers in Energy Research. 2: 1–10. doi:10.3389/fenrg.2014.00025.
  123. ^ Zogg, Cornelia (14 June 2017). "A solid-state electrolyte that is able to compete with liquid electrolytes for rechargeable batteries". Phys.org. Archived from the original on 13 March 2018. Retrieved 24 February 2018.
  124. ^ Can, Cao; Zhuo-Bin, Li; Xiao-Liang, Wang (2014). "Recent Advances in Inorganic Solid Electrolytes for Lithium Batteries". Frontiers in Energy Research. 2: 2–4. doi:10.3389/fenrg.2014.00025.
  125. ^ Can, Cao; Zhuo-Bin, Li; Xiao-Liang, Wang (2014). "Recent Advances in Inorganic Solid Electrolytes for Lithium Batteries". Frontiers in Energy Research. 2: 6–8. doi:10.3389/fenrg.2014.00025.
  126. ^ Tatsumisago, Masahiro; Nagao, Motohiro; Hayashi, Akitoshi (2013). "Recent development of sulfide solid electrolytes and interfacial modification for all-solid-state rechargeable lithium batteries". Journal of Asian Ceramic Societies. 1 (1): 17. doi:10.1016/j.jascer.2013.03.005.
  127. ^ Haregewoin, Atetegeb Meazah; Wotango, Aselefech Sorsa; Hwang, Bing-Joe (8 June 2016). "Electrolyte additives for lithium ion battery electrodes: progress and perspectives". Energy & Environmental Science. 9 (6): 1955–1988. doi:10.1039/C6EE00123H. ISSN 1754-5706. Archived from the original on 20 October 2020. Retrieved 19 October 2020.
  128. ^ Summerfield, J. (2013). "Modeling the Lithium Ion Battery". Journal of Chemical Education. 90 (4): 453–455. Bibcode:2013JChEd..90..453S. doi:10.1021/ed300533f.
  129. ^ Lee, Sang-Won; Lee, Kyung-Min; Choi, Yoon-Geol; Kang, Bongkoo (November 2018). "Modularized Design of Active Charge Equalizer for Li-Ion Battery Pack". IEEE Transactions on Industrial Electronics. 65 (11): 8697–8706. doi:10.1109/TIE.2018.2813997. ISSN 0278-0046. S2CID 49536272. Archived from the original on 21 May 2023. Retrieved 5 July 2023.
  130. ^ Andrea 2010, p. 2.
  131. ^ "How is a Lithium Ion Pouch Cell Manufactured in the Lab?". KIT Zentrum für Mediales Lernen. 6 June 2018. Archived from the original on 18 February 2020. Retrieved 1 February 2020. Creative Commons Attribution license
  132. ^ Andrea 2010, p. 234.
  133. ^ "Prismatic cell winder". University of Michigan. 25 June 2015. Archived from the original on 17 May 2020. Retrieved 1 February 2020.
  134. ^ Wang, Y.; He, P.; Zhou, H. (2012). "Li-Redox Flow Batteries Based on Hybrid Electrolytes: At the Cross Road between Li-ion and Redox Flow Batteries". Advanced Energy Materials. 2 (7): 770–779. Bibcode:2012AdEnM...2..770W. doi:10.1002/aenm.201200100. S2CID 96707630.
  135. ^ Qi, Zhaoxiang; Koenig, Gary M. (15 August 2016). "A carbon-free lithium-ion solid dispersion redox couple with low viscosity for redox flow batteries". Journal of Power Sources. 323: 97–106. Bibcode:2016JPS...323...97Q. doi:10.1016/j.jpowsour.2016.05.033.
  136. ^ Panasonic unveils "smallest" pin-shaped lithium ion battery Archived 6 September 2015 at the Wayback Machine, Telecompaper, 6 October 2014
  137. ^ Erol, Salim (5 January 2015). Electrochemical Impedance Spectroscopy Analysis and Modeling of Lithium Cobalt Oxide/Carbon Batteries (PhD). Retrieved 10 September 2018.
  138. ^ "Rechargeable Li-Ion Button Battery: Serial LIR2032" (PDF). AA Portable Power Corp. Archived (PDF) from the original on 9 May 2018. Retrieved 10 September 2018.
  139. ^ Goodwins, Rupert (17 August 2006). "Inside a notebook battery pack". ZDNet. Archived from the original on 24 July 2013. Retrieved 6 June 2013.
  140. ^ OECD; Office, European Union Intellectual Property (17 March 2022). Illicit Trade Dangerous Fakes Trade in Counterfeit Goods that Pose Health, Safety and Environmental Risks: Trade in Counterfeit Goods that Pose Health, Safety and Environmental Risks. OECD Publishing. ISBN 978-92-64-59470-8. Archived from the original on 28 August 2023. Retrieved 10 July 2023.
  141. ^ Hesse, Holger; Schimpe, Michael; Kucevic, Daniel; Jossen, Andreas (11 December 2017). "Lithium-Ion Battery Storage for the Grid—A Review of Stationary Battery Storage System Design Tailored for Applications in Modern Power Grids". Energies. 10 (12): 2107. doi:10.3390/en10122107. ISSN 1996-1073.
  142. ^ Grey, Clare P.; Hall, David S. (December 2020). "Prospects for lithium-ion batteries and beyond—a 2030 vision". Nature Communications. 11 (1): 6279. Bibcode:2020NatCo..11.6279G. doi:10.1038/s41467-020-19991-4. ISSN 2041-1723. PMC 7722877. PMID 33293543.
  143. ^ "Overview of lithium ion batteries" (PDF). Panasonic. January 2007. Archived from the original (PDF) on 7 November 2011. Retrieved 13 November 2013.
  144. ^ "Panasonic Develops New Higher-Capacity 18650 Li-Ion Cells; Application of Silicon-based Alloy in Anode". greencarcongress.com. Archived from the original on 12 July 2014. Retrieved 31 January 2011.
  145. ^ a b Quinn, Jason B.; Waldmann, Thomas; Richter, Karsten; Kasper, Michael; Wohlfahrt-Mehrens, Margret (19 October 2018). "Energy Density of Cylindrical Li-Ion Cells: A Comparison of Commercial 18650 to the 21700 Cells". Journal of the Electrochemical Society. 165 (14): A3284–A3291. doi:10.1149/2.0281814jes. S2CID 105193083.
  146. ^ Winter & Brodd 2004, p. 4258
  147. ^ Andrea 2010, p. 12.
  148. ^ Stroe, Daniel-Ioan; Swierczynski, Maciej; Kar, Soren Knudsen; Teodorescu, Remus (22 September 2017). "Degradation Behavior of Lithium-Ion Batteries During Calendar Ageing—The Case of the Internal Resistance Increase". IEEE Transactions on Industry Applications. 54 (1): 517–525. doi:10.1109/TIA.2017.2756026. ISSN 0093-9994. S2CID 34944228. Archived from the original on 26 January 2022. Retrieved 10 February 2022.
  149. ^ Turpen, Aaron (16 November 2015). "New battery tech gives 10 hours of talk time after only 5 minutes on charge". www.gizmag.com. Archived from the original on 8 December 2015. Retrieved 3 December 2015.
  150. ^ Smith, Noah (16 January 2015). "Get Ready For Life Without Oil". bloombergview.com. Archived from the original on 11 July 2015. Retrieved 31 July 2015.
  151. ^ Randall, Tom; Lippert, John (24 November 2017). "Tesla's Newest Promises Break the Laws of Batteries". Bloomberg.com. Archived from the original on 12 June 2018. Retrieved 13 February 2018.
  152. ^ a b Ziegler, Micah S.; Trancik, Jessika E. (21 April 2021). "Re-examining rates of lithium-ion battery technology improvement and cost decline". Energy & Environmental Science. 14 (4): 1635–1651. arXiv:2007.13920. doi:10.1039/D0EE02681F. ISSN 1754-5706. S2CID 220830992.
  153. ^ Ziegler, Micah S.; Song, Juhyun; Trancik, Jessika E. (9 December 2021). "Determinants of lithium-ion battery technology cost decline". Energy & Environmental Science. 14 (12): 6074–6098. doi:10.1039/D1EE01313K. hdl:1721.1/145588. ISSN 1754-5706. S2CID 244514877.
  154. ^ Predtechenskiy, Mikhail R.; Khasin, Alexander A.; Smirnov, Sergei N.; Bezrodny, Alexander E.; Bobrenok, Oleg F.; Dubov, Dmitry Yu.; Kosolapov, Andrei G.; Lyamysheva, Ekaterina G.; Muradyan, Vyacheslav E.; Saik, Vladimir O.; Shinkarev, Vasiliy V.; Chebochakov, Dmitriy S.; Galkov, Mikhail S.; Karpunin, Ruslan V.; Verkhovod, Timofey D. (1 July 2022). "New Perspectives in SWCNT Applications: Tuball SWCNTs. Part 2. New Composite Materials through Augmentation with Tuball". Carbon Trends. 8: 100176. Bibcode:2022CarbT...800176P. doi:10.1016/j.cartre.2022.100176. ISSN 2667-0569.
  155. ^ Bobanac, Vedran; Basic, Hrvoje; Pandzic, Hrvoje (6 July 2021). "Determining Lithium-ion Battery One-way Energy Efficiencies: Influence of C-rate and Coulombic Losses" (PDF). IEEE EUROCON 2021 – 19th International Conference on Smart Technologies. IEEE. pp. 385–389. doi:10.1109/EUROCON52738.2021.9535542. ISBN 978-1-6654-3299-3. S2CID 237520703. Archived (PDF) from the original on 22 June 2023. Retrieved 22 June 2023.
  156. ^ Schimpe, Michael; Naumann, Maik; Truong, Nam; Hesse, Holger C.; Santhanagopalan, Shriram; Saxon, Aron; Jossen, Andreas (8 November 2017). "Energy efficiency evaluation of a stationary lithium-ion battery container storage system via electro-thermal modeling and detailed component analysis". Applied Energy. 210 (C): 211–229. doi:10.1016/j.apenergy.2017.10.129. ISSN 0306-2619.
  157. ^ "Lithium-ion Battery DATA SHEET Battery Model : LIR18650 2600 mAh" (PDF). Archived (PDF) from the original on 3 May 2019. Retrieved 3 May 2019.
  158. ^ a b Wang, J.; Liu, P.; Hicks-Garner, J.; Sherman, E.; Soukiazian, S.; Verbrugge, M.; Tataria, H.; Musser, J.; Finamore, P. (2011). "Cycle-life model for graphite-LiFePO4 cells". Journal of Power Sources. 196 (8): 3942–3948. Bibcode:2011JPS...196.3942W. doi:10.1016/j.jpowsour.2010.11.134.
  159. ^ a b Saxena, S.; Hendricks, C.; Pecht, M. (2016). "Cycle life testing and modeling of graphite/LiCoO2 cells under different state of charge ranges". Journal of Power Sources. 327: 394–400. Bibcode:2016JPS...327..394S. doi:10.1016/j.jpowsour.2016.07.057.
  160. ^ Sun, Y.; Saxena, S.; Pecht, M. (2018). "Derating Guidelines for Lithium-Ion Batteries". Energies. 11 (12): 3295. doi:10.3390/en11123295. hdl:1903/31442.
  161. ^ a b c Hendricks, C.; Williard, N.; Mathew, S.; Pecht, M. (2016). "A failure modes, mechanisms, and effects analysis (FMMEA) of lithium-ion batteries". Journal of Power Sources. 327: 113–120. doi:10.1016/j.jpowsour.2015.07.100..
  162. ^ a b c d e f g h i j k l m n o p Voelker, Paul (22 April 2014). "Trace Degradation Analysis of Lithium-Ion Battery Components". R&D. Archived from the original on 28 April 2015. Retrieved 4 April 2015.
  163. ^ a b c d Vermeer, Wiljan (2022). "A Comprehensive Review on the Characteristics and Modeling of Lithium-Ion Battery Aging". IEEE Transactions on Transportation Electrification. 8 (2): 2205. doi:10.1109/tte.2021.3138357. S2CID 245463637..
  164. ^ a b c d Waldmann, T.; Wilka, M.; Kasper, M.; Fleischhammer, M.; Wohlfahrt-Mehrens, M. (2014). "Temperature dependent ageing mechanisms in Lithium-ion batteries – A Post-Mortem study". Journal of Power Sources. 262: 129–135. Bibcode:2014JPS...262..129W. doi:10.1016/j.jpowsour.2014.03.112.
  165. ^ Leng, Feng; Tan, Cher Ming; Pecht, Michael (6 August 2015). "Effect of Temperature on the Aging rate of Li Ion Battery Operating above Room Temperature". Scientific Reports. 5 (1): 12967. Bibcode:2015NatSR...512967L. doi:10.1038/srep12967. PMC 4526891. PMID 26245922.
  166. ^ Williams, Sarah C. P. "Researchers zoom in on battery wear and tear". University of Chicago via techxplore.com. Archived from the original on 2 February 2023. Retrieved 18 January 2023.
  167. ^ Zhang, Minghao; Chouchane, Mehdi; Shojaee, S. Ali; Winiarski, Bartlomiej; Liu, Zhao; Li, Letian; Pelapur, Rengarajan; Shodiev, Abbos; Yao, Weiliang; Doux, Jean-Marie; Wang, Shen; Li, Yixuan; Liu, Chaoyue; Lemmens, Herman; Franco, Alejandro A.; Meng, Ying Shirley (22 December 2022). "Coupling of multiscale imaging analysis and computational modeling for understanding thick cathode degradation mechanisms". Joule. 7: 201–220. doi:10.1016/j.joule.2022.12.001. ISSN 2542-4785.
  168. ^ a b c Attia PM, Bills A, Planella FB, Dechent P, dos Reis G, Dubarry M, Gasper P, Gilchrist R, Greenbank S, Howey D, Liu O, Khoo E, Preger Y, Soni A, Sripad S, Stefanopoulou AG, Sulzer V (10 June 2022). "Review-"Knees" in Lithium-Ion Battery Aging Trajectories". Journal of the Electrochemical Society. 169 (6): 28. arXiv:2201.02891. Bibcode:2022JElS..169f0517A. doi:10.1149/1945-7111/ac6d13. S2CID 245836782..
  169. ^ "How to prolong your cell phone battery's life span". phonedog.com. 7 August 2011. Retrieved 25 July 2020.
  170. ^ Alexander K Suttman.(2011).Lithium Ion Battery Aging Experiments and Algorithm Development for Life Estimation. Published by The Ohio State University and OhioLINK
  171. ^ Matthew B. Pinson1 and Martin Z. Bazant. Theory of SEI Formation in Rechargeable Batteries: Capacity Fade, Accelerated Aging and Lifetime Prediction. Massachusetts Institute of Technology, Cambridge, MA 02139
  172. ^ "New Data Shows Heat & Fast-Charging Responsible For More Battery Degradation Than Age Or Mileage". CleanTechnica. 16 December 2019. Archived from the original on 27 April 2021. Retrieved 20 December 2019.
  173. ^ "How iOS 13 Will Save Your iPhone's Battery (by Not Fully Charging It)". www.howtogeek.com. 4 June 2019. Archived from the original on 7 April 2020. Retrieved 12 January 2020.
  174. ^ Jary, Simon. "Battery charging tips and tricks for prolonged life". Tech Advisor. Archived from the original on 12 January 2020. Retrieved 12 January 2020.
  175. ^ Reynolds, Matt (4 August 2018). "Here's the truth behind the biggest (and dumbest) battery myths". Wired UK. Archived from the original on 12 January 2020. Retrieved 12 January 2020 – via www.wired.co.uk.
  176. ^ "Why You Should Stop Fully Charging Your Smartphone Now". Electrical Engineering News and Products. 9 November 2015. Archived from the original on 12 January 2020. Retrieved 12 January 2020.
  177. ^ Song, Wentao; Harlow, J.; Logan, E.; Hebecker, H.; Coon, M; Molino, L.; Johnson, M.; Dahn, J.; Metzger, M. (2021). "A Systematic Study of Electrolyte Additives in Single Crystal and Bimodal LiNi0.8Mn0.1 Co0.1O2/Graphite Pouch Cells". Journal of the Electrochemical Society. 168 (9): 090503. Bibcode:2021JElS..168i0503S. doi:10.1149/1945-7111/ac1e55..
  178. ^ Jaguemont, Joris; Van Mierlo, Joeri (October 2020). "A comprehensive review of future thermal management systems for battery-electrified vehicles". Journal of Energy Storage. 31: 101551. Bibcode:2020JEnSt..3101551J. doi:10.1016/j.est.2020.101551. S2CID 219934100. Archived from the original on 24 February 2022. Retrieved 28 November 2021.
  179. ^ Waldmann, T.; Bisle, G.; Hogg, B.-I.; Stumpp, S.; Danzer, M. A.; Kasper, M.; Axmann, P.; Wohlfahrt-Mehrens, M. (2015). "Influence of Cell Design on Temperatures and Temperature Gradients in Lithium-Ion Cells: An in Operando Study". Journal of the Electrochemical Society. 162 (6): A921. doi:10.1149/2.0561506jes..
  180. ^ Malabet, Hernando (2021). "Electrochemical and Post-Mortem Degradation Analysis of Parallel-Connected Lithium-Ion Cells with Non-Uniform Temperature Distribution". Journal of the Electrochemical Society. 168 (10): 100507. Bibcode:2021JElS..168j0507G. doi:10.1149/1945-7111/ac2a7c. S2CID 244186025.
  181. ^ Andrea 2010, p. 9.
  182. ^ Liaw, B. Y.; Jungst, R. G.; Nagasubramanian, G.; Case, H. L.; Doughty, D. H. (2005). "Modeling capacity fade in lithium-ion cells". Journal of Power Sources. 140 (1): 157–161. Bibcode:2005JPS...140..157L. doi:10.1016/j.jpowsour.2004.08.017.
  183. ^ Cheng, Xin-Bing; Zhang, Rui; Zhao, Chen-Zi; Zhang, Qiang (9 August 2017). "Toward Safe Lithium Metal Anode in Rechargeable Batteries: A Review". Chemical Reviews. 117 (15): 10403–10473. doi:10.1021/acs.chemrev.7b00115. ISSN 0009-2665. PMID 28753298. Archived from the original on 5 November 2023. Retrieved 5 November 2023.
  184. ^ Xu, Wu; Wang, Jiulin; Ding, Fei; Chen, Xilin; Nasybulin, Eduard; Zhang, Yaohui; Zhang, Ji-Guang (23 January 2014). "Lithium metal anodes for rechargeable batteries". Energy & Environmental Science. 7 (2): 513–537. doi:10.1039/C3EE40795K. ISSN 1754-5706. Archived from the original on 5 November 2023. Retrieved 5 November 2023.
  185. ^ Lyu, Peizhao; Liu, Xinjian; Qu, Jie; Zhao, Jiateng; Huo, Yutao; Qu, Zhiguo; Rao, Zhonghao (1 October 2020). "Recent advances of thermal safety of lithium ion battery for energy storage". Energy Storage Materials. 31: 195–220. Bibcode:2020EneSM..31..195L. doi:10.1016/j.ensm.2020.06.042. ISSN 2405-8297. S2CID 225545635.
  186. ^ Lei, Yanxiang; Zhang, Caiping; Gao, Yang; Li, Tong (1 October 2018). "Charging Optimization of Lithium-ion Batteries Based on Capacity Degradation Speed and Energy Loss". Energy Procedia. Cleaner Energy for Cleaner Cities. 152: 544–549. Bibcode:2018EnPro.152..544L. doi:10.1016/j.egypro.2018.09.208. ISSN 1876-6102. S2CID 115875535.
  187. ^ Bandhauer, Todd M.; Garimella, Srinivas; Fuller, Thomas F. (25 January 2011). "A Critical Review of Thermal Issues in Lithium-Ion Batteries". Journal of the Electrochemical Society. 158 (3): R1. doi:10.1149/1.3515880. ISSN 1945-7111. S2CID 97367770.
  188. ^ Zhang, Xue-Qiang; Cheng, Xin-Bing; Chen, Xiang; Yan, Chong; Zhang, Qiang (March 2017). "Fluoroethylene Carbonate Additives to Render Uniform Li Deposits in Lithium Metal Batteries". Advanced Functional Materials. 27 (10). doi:10.1002/adfm.201605989. ISSN 1616-301X. S2CID 99575315. Archived from the original on 5 November 2023. Retrieved 5 November 2023.
  189. ^ Zhang, Sheng S.; Fan, Xiulin; Wang, Chunsheng (12 June 2018). "Preventing lithium dendrite-related electrical shorting in rechargeable batteries by coating separator with a Li-killing additive". Journal of Materials Chemistry A. 6 (23): 10755–10760. doi:10.1039/C8TA02804D. ISSN 2050-7496. Archived from the original on 5 November 2023. Retrieved 5 November 2023.
  190. ^ Geldasa FT, Kebede MA, Shura MW, Hone FG (2022). "Identifying surface degradation, mechanical failure, and thermal instability phenomena of high energy density Ni-rich NCM cathode materials for lithium-ion batteries: a review". RSC Advances. 12 (10): 5891–5909. Bibcode:2022RSCAd..12.5891G. doi:10.1039/d1ra08401a. PMC 8982025. PMID 35424548.
  191. ^ Pang XX, Zhong S, Wang YL, Yang W, Zheng WZ, Sun GZ (2022). "A Review on the Prediction of Health State and Serving Life of Lithium-Ion Batteries". Chemical Record. 22 (10): e202200131. doi:10.1002/tcr.202200131. PMID 35785467. S2CID 250282891.
  192. ^ Li AG, West AC, Preindl M (2022). "Towards unified machine learning characterization of lithium-ion battery degradation across multiple levels: A critical review". Applied Energy. 316: 9. Bibcode:2022ApEn..31619030L. doi:10.1016/j.apenergy.2022.119030. S2CID 246554618.
  193. ^ On the Decomposition of Carbonate-Based Lithium-Ion Battery Electrolytes Studied Using Operando Infrared Spectroscopy. 2018. J Electrochem Soc. 165/16, A4051-A7. N. Saqib, C.M. Ganim, A.E. Shelton, J.M. Porter. doi: 10.1149/2.1051816jes.
  194. ^ Safety and Quality Issues of Counterfeit Lithium-Ion Cells. 2023. ACS Energy Lett. 8/6, 2831–9. T. Joshi, S. Azam, D. Juarez-Robles, J.A. Jeevarajan. doi: 10.1021/acsenergylett.3c00724.
  195. ^ a b Hislop, Martin (1 March 2017). "Solid-state EV battery breakthrough from Li-ion battery inventor John Goodenough". North American Energy News. The American Energy News. Archived from the original on 12 November 2020. Retrieved 15 March 2017.
  196. ^ Bisschop, Roeland; Willstrand, Ola; Rosengren, Max (1 November 2020). "Handling Lithium-Ion Batteries in Electric Vehicles: Preventing and Recovering from Hazardous Events". Fire Technology. 56 (6): 2671–2694.