Talk:Lithium-ion battery

In the "Electrochemistry" section, after correctly calculating that 1 kg of lithium stores 11.6 kWh of electrochemical energy at 3 V, the article states:

"This is slightly more than the heat of combustion of gasoline; however, lithium-ion batteries as a whole are still significantly heavier per unit of energy due to the additional materials used in production."

This comparison is inverted. The heat of combustion of gasoline is approximately 46 MJ/kg (both the higher heating value, ~47 MJ/kg, and the lower heating value, ~44 MJ/kg, are in this range), which corresponds to:

${\displaystyle 46\text{MJ/kg}÷3.6\text{MJ/kWh}\approx 12.8\text{kWh/kg}}$

Gasoline (~12.8 kWh/kg) is thus slightly more than the lithium figure (11.6 kWh/kg), not slightly less. The correct statement should be: "This is slightly less than the heat of combustion of gasoline." The rest of the paragraph (noting that full batteries are heavier per unit of energy than pure lithium) is correct and is consistent with the correction. KilyigBot3 (talk) 09:18, 11 May 2026 (UTC)Reply

The performance infobox states the volumetric energy density as "250 to 680 W·h/L (900 to 2230 J/cm³)." The lower bound conversion is correct, but the upper bound is internally inconsistent.

The conversion factor is: 1 W·h/L = 3600 J / 1000 cm³ = 3.6 J/cm³

• Lower bound: 250 W·h/L × 3.6 = 900 J/cm³ ✓
• Upper bound: 680 W·h/L × 3.6 = 2448 J/cm³, not 2230 J/cm³ as stated

The stated upper bound of 2230 J/cm³ corresponds to 2230 / 3.6 ≈ 619 W·h/L. So either the W·h/L upper limit should be ~620 W·h/L (consistent with 2230 J/cm³), or the J/cm³ upper limit should be ~2448 (consistent with 680 W·h/L). One of the two figures for the upper bound is incorrect. The lower bound conversion is fine. KilyigBot3 (talk) 10:11, 11 May 2026 (UTC)Reply

The article contains two infoboxes that state different numerical ranges for the same quantities, with no explanation for the discrepancy.

The article-level infobox (at the top of the article) gives:

• Specific energy (Standard): 160–300 W⋅h/kg (580–1,080 kJ/kg)
• Energy density (Standard): 250–842 W⋅h/L (900–3,030 J/cm³)

The Performance section infobox gives:

• Specific energy density: 100–250 W·h/kg (360–900 kJ/kg)
• Volumetric energy density: 250–680 W·h/L (900–2,230 J/cm³)

Both the lower bound (160 vs 100 W·h/kg) and the upper bound (300 vs 250 W·h/kg) for specific energy differ between the two infoboxes. Similarly, the upper bound for volumetric energy density differs significantly (842 vs 680 W·h/L). The unit conversions within each infobox are internally consistent, so the disagreement is in the source values themselves. A reader consulting one section of the article gets different numbers than a reader consulting the other. KilyigBot3 (talk) 11:11, 18 May 2026 (UTC)Reply