Comparison_of_commercial_battery_types

Comparison of commercial battery types

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This is a list of commercially-available battery types summarizing some of their characteristics for ready comparison.

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Cell chemistry	Also known as	Electrode			Rechargeable	Commercialized	Voltage			Energy density		Specific power	Cost^†	Discharge efficiency	Self-discharge rate	Shelf life
		Anode	Electrolyte	Cathode		Commercialized	Cutoff	Nominal	100% SOC	by mass	by volume	Specific power	Cost^†	Discharge efficiency	Self-discharge rate	Shelf life
		Anode	Electrolyte	Cathode		year	V	V	V	MJ/kg (Wh/kg)	MJ/L (Wh/L)	W/kg	Wh/$ ($/kWh)	%	%/month	years
Lead–acid	SLA VRLA PbAc	Lead	H₂SO₄	Lead dioxide	Yes	1881^[1]	1.75^[2]	2.1^[2]	2.23–2.32^[2]	0.11–0.14 (30–40)^[2]	0.22–0.27 (60–75)^[2]	180^[2]	5.44–13.99 (72–184)^[2]	50–92^[2]	3–20^[2]
Zinc–carbon	Carbon–zinc	Zinc	NH₄Cl	Manganese (IV) oxide	No	1898^[3]	0.75–0.9^[3]	1.5^[3]		0.13 (36)^[3]	0.33 (92)^[3]	10–27^[3]	2.49 (402)^[3]	50–60^[3]	0.32^[3]	3–5^[4]
Zinc–air	PR		KOH	Oxygen	No	1932^[5]	0.9^[5]	1.45–1.65^[5]		1.59 (442)^[5]	6.02 (1,673)^[5]	100^[5]	2.18 (460)^[5]	60–70^[5]	0.17^[5]	3^[5]
Mercury oxide–zinc	Mercuric oxide Mercury cell		NaOH/KOH	Mercuric oxide	No	1942–^[6] 1996^[7]	0.9^[8]	1.35^[8]		0.36–0.44 (99–123)^[8]	1.1–1.8 (300–500)^[8]					2^[6]
Alkaline	Zn/MnO ₂ LR		KOH	Manganese (IV) oxide	No	1949^[9]	0.9^[10]	1.5^[11]	1.6^[10]	0.31–0.68 (85–190)^[12]	0.90–1.56 (250–434)^[12]	50^[12]	0.39 (2574)^[12]	45–85^[12]	0.17^[12]	5–10^[4]
Rechargeable alkaline	RAM		KOH	Manganese (IV) oxide	Yes	1992^[13]	0.9^[14]	1.57^[14]	1.6^[14]						<1^[13]
Silver-oxide	SR		NaOH/KOH	Silver oxide	No	1960^[15]	1.2^[16]	1.55^[16]	1.6^[17]	0.47 (130)^[17]	1.8 (500)^[17]
Nickel–zinc	NiZn		KOH	Nickel oxide hydroxide	Yes	2009^[13]	0.9^[13]	1.65^[13]	1.85^[13]						13^[13]
Nickel–iron	NiFe	Iron	KOH		Yes	1901^[18]	0.75^[19]	1.2^[19]	1.65^[19]	0.07–0.09 (19–25)^[20]	0.45 (125)^[21]	100	3.31–4.41 (227–302)^[1]		20–30	30–^[22] 50^[23]^[24]
Nickel–cadmium	NiCd NiCad	Cadmium	KOH		Yes	c. 1960^[25]	0.9–1.05^[26]	1.2^[27]	1.3^[26]	0.11 (30)^[27]	0.36 (100)^[27]	150–200^[28]			10^[13]
Nickel–hydrogen	NiH ₂ Ni-H ₂	Hydrogen	KOH		Yes	1975^[29]	1.0^[30]	1.55^[28]		0.16–0.23 (45–65)^[28]	0.22 (60)^[31]	150–200^[28]				5^[31]
Nickel–metal hydride	NiMH Ni-MH	Metal hydride	KOH\|		Yes	1990^[1]	0.9–1.05^[26]	1.2^[11]	1.3^[26]	0.36 (100)^[11]	1.44 (401)^[32]	250–1,000	2.65 (378)^[1]		30^[33]
Low self-discharge nickel–metal hydride	LSD NiMH	Metal hydride	KOH\|		Yes	2005^[34]	0.9–1.05^[26]	1.2	1.3^[26]	0.34 (95)^[35]	1.27 (353)^[36]	250–1,000			0.42^[33]
Lithium–manganese dioxide	Lithium Li-MnO ₂ CR Li-Mn	Lithium		Manganese dioxide	No	1976^[37]	2^[38]	3^[11]		0.54–1.19 (150–330)^[39]	1.1–2.6 (300–710)^[39]	250–400^[39]			1	5–10^[39]
Lithium–carbon monofluoride	Li-(CF) _x BR			Carbon monofluoride	No	1976^[37]	2^[40]	3^[40]		0.94–2.81 (260–780)^[39]	1.58–5.32 (440–1,478)^[39]	50–80^[39]			0.2–0.3^[41]	15^[39]
Lithium–iron disulfide	Li-FeS ₂ FR			Iron disulfide	No	1989^[42]	0.9^[42]	1.5^[42]	1.8^[42]	1.07 (297)^[42]	2.1 (580)^[43]					10-20^[43]
Lithium–titanate	Li ₄Ti ₅O ₁₂ LTO			Lithium manganese oxide or Lithium nickel manganese cobalt oxide	Yes	2008^[44]	1.6–1.8^[45]	2.3–2.4^[45]	2.8^[45]	0.22–0.40 (60–110)	0.64 (177)	3,000–5,100^[46]	0.39 (2539)^[46]	85^[46]	2–5^[46]	10–20^[46]
Lithium cobalt oxide	LiCoO ₂ ICR LCO Li‑cobalt^[47]	Graphite^‡	LiPF₆/LiBF₄/ LiClO₄	Lithium cobalt oxide	Yes	1991^[48]	2.5^[49]	3.7^[50]	4.2^[49]	0.70 (195)^[50]	2.0 (560)^[50]		2.21 (453)^[1]
Lithium iron phosphate	LiFePO ₄ IFR LFP Li‑phosphate^[47]			Lithium iron phosphate	Yes	1996^[51]	2^[49]	3.2^[50]	3.65^[49]	0.32–0.58 (90–160)^[50]^[52]^[53]	1.20 (333)^[50]^[52]	200^[54]–1,200^[55]			4.5	20 years^[56]
Lithium manganese oxide	LiMn ₂O ₄ IMR LMO Li‑manganese^[47]			Lithium manganese oxide	Yes	1999^[1]	2.5^[57]	3.9^[50]	4.2^[57]	0.54 (150)^[50]	1.5 (420)^[50]		2.21 (453)^[1]
Lithium nickel cobalt aluminium oxides	LiNiCoAlO ₂ NCA NCR Li‑aluminium^[47]			Lithium nickel cobalt aluminium oxide	Yes	1999	3.0^[58]	3.6^[50]	4.3^[58]	0.79 (220)^[50]	2.2 (600)^[50]
Lithium nickel manganese cobalt oxide	LiNi _xMn _yCo _1-x-yO ₂ INR NMC^[47] NCM^[50]			Lithium nickel manganese cobalt oxide	Yes	2008^[59]	2.5^[49]	3.6^[50]	4.2^[49]	0.74 (205)^[50]	2.1 (580)^[50]

Cell chemistry	Charge efficiency	Cycle durability
Cell chemistry	%	# 100% depth of discharge (DoD) cycles
Lead–acid	50–92^[2]	50–100^[60] (500@40%DoD^[2]^[60])
Rechargeable alkaline		5–100^[13]
Nickel–zinc		100 to 50% capacity^[13]
Nickel–iron	65–80	5,000
Nickel–cadmium	70–90	500^[25]
Nickel–hydrogen	85	20,000^[31]
Nickel–metal hydride	66	300–800^[13]
Low self-discharge nickel–metal hydride battery		500–1,500^[13]
Lithium cobalt oxide	90	500–1,000
Lithium–titanate	85–90	6,000–10,000 to 90% capacity^[46]
Lithium iron phosphate	90	2,500^[54]–12,000 to 80% capacity^[61]
Lithium manganese oxide	90	300–700

Cell chemistry	Overcharge	Overheat
	Onset	Onset	Runaway	Peak
	SOC%	°C	°C	°C/min
Lithium cobalt oxide	150^[62]	165^[62]	190^[62]	440^[62]
Lithium iron phosphate	100^[62]	220^[62]	240^[62]	21^[62]
Lithium manganese oxide	110^[62]	210^[62]	240^[62]	100+^[62]
Lithium nickel cobalt aluminium oxide	125^[62]	140^[62]	195^[62]	260^[62]
Lithium nickel manganese cobalt oxide	170^[62]	160^[62]	230^[62]	100+^[62]

Types	Cell Voltage	Self-discharge	Memory	Cycles Times	Temperature	Weight
NiCd	1.2V	20%/month	Yes	Up to 800	-20 °C to 60 °C	Heavy
NiMH	1.2V	30%/month	Mild	Up to 500	-20 °C to 70 °C	Middle
Low Self Discharge NiMH	1.2V	3%/year–1%/month	No	500–2,000	-20 °C to 70 °C	Middle
Li-ion (LCO)	3.6V	5–10%/month	No	500–1,000	-20 °C to 60 °C	Light
LiFePO₄ (LFP)	3.2V	2–5%/month	No	2,500–12,000^[61]	-20 °C to 60 °C	Light
LiPo (LCO)	3.7V	5–10%/month	No	500–1,000	-20 °C to 60 °C	Lightest
Li–Ti (LTO)	2.4V	2–5%/month^[46]	No	6,000–20,000	-40 °C to 75 °C	Light

Comparison_of_commercial_battery_types

Comparison of commercial battery types

Common characteristics

Rechargeable characteristics

Thermal runaway

NiCd vs. NiMH vs. Li-ion vs. Li–polymer vs. LTO

See also

References

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