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- | Name = Lithium selenide | ImageCaption = Crystal structure of lithium selenide<br /><span style="color:#99CC00;background-color:#99CC00;">__</spa ...7 KB (849 words) - 00:06, 12 May 2024
- ...n phosphate battery]], PTMA/LiFePO<sub>4</sub>. Together, they improve the lithium ion intercalation capacity, cycle life, electrochemical performances, and c ...oxides, in particular the V<sub>2</sub>O<sub>5</sub> [[xerogel]], allows [[lithium ion]]s to [[Diffusion|diffuse]] faster and thus have a better cyclability. ...9 KB (1,341 words) - 00:23, 14 December 2024
- | Name = Lithium Aluminium Germanium Phosphate | ImageCaption = Lithium aluminium germanium phosphate (LAGP) sputtering target ...45 KB (6,291 words) - 20:26, 21 January 2025
Page text matches
- | Name = Lithium selenide | ImageCaption = Crystal structure of lithium selenide<br /><span style="color:#99CC00;background-color:#99CC00;">__</spa ...7 KB (849 words) - 00:06, 12 May 2024
- ...st=Reona|date=2020|title=High-Capacity Anode Materials for All-Solid-State Lithium Batteries|journal=Frontiers in Energy Research|volume=8|pages=171|doi=10.33 ...liquid electrolytes. Developments in 2021 showed that solid-state silicon lithium-ion batteries are possible, and offer many of the hypothesized benefits.<re ...8 KB (1,100 words) - 00:35, 12 January 2025
- ...sparingly soluble in water. It reacts with metallic [[lithium]] to yield [[lithium fluoride]] and metallic promethium:<ref>{{cite journal|doi=10.1002/ange.196 ...2 KB (228 words) - 15:38, 23 September 2023
- | ''Z''=3: || Li<sup>+</sup> || [[lithium]] ion ...egative [[Hydrogen]] [[ion]] (H<sup>−</sup>, ''Z'' = 1), or the positive [[Lithium]] ion (Li<sup>+</sup>, ''Z'' = 3) is:<ref name="Bransden">Physics of Atoms ...4 KB (606 words) - 15:19, 14 April 2022
- ...n phosphate battery]], PTMA/LiFePO<sub>4</sub>. Together, they improve the lithium ion intercalation capacity, cycle life, electrochemical performances, and c ...oxides, in particular the V<sub>2</sub>O<sub>5</sub> [[xerogel]], allows [[lithium ion]]s to [[Diffusion|diffuse]] faster and thus have a better cyclability. ...9 KB (1,341 words) - 00:23, 14 December 2024
- | OtherCations = [[Lithium sulfide]]<br>[[Sodium sulfide]]<br>[[Potassium sulfide]]<br>[[Caesium sulfi Rubidium sulfide has a cubic crystal similar to [[lithium sulfide]], [[sodium sulfide]] and [[potassium sulfide]], known as the [[Ant ...4 KB (437 words) - 13:47, 25 January 2022
- ...ke|first2=G. W. F.|date=2003-09-11|title=Bethe Logarithm and QED Shift for Lithium|journal=Physical Review Letters|volume=91|issue=11|pages=113004|doi=10.1103 ...3 KB (459 words) - 22:16, 20 March 2024
- ...96964746/depth-of-discharge-dod-all-battery|access-date=2022-02-20|website=lithium & solar power LiFePO4}}</ref><ref>{{Cite web|title=Blog - LiFePO4 {{!}} sho ...rces|series=Selected papers presented at the 11th International Meeting on Lithium Batteries|language=en|volume=119-121|pages=955–958|doi=10.1016/S0378-7753(0 ...8 KB (1,167 words) - 14:00, 8 November 2024
- ...sugar battery's [[Voltage|output voltage]](0.5V) is lower than that of the lithium-ion battery (3.6 V), which causes its [[electric power]] (the rate of Compared to the currently widely used [[lithium-ion battery]], the sugar battery has potential benefits in many aspects. ...15 KB (2,223 words) - 14:15, 8 January 2025
- ...ooks?id=sKx0IBC22p4C&pg=PA135|isbn=9782884491631}}</ref> Bergmann observed lithium at 5347 cm<sup>−1</sup>, sodium at 5416 cm<sup>−1</sup> potassiu ==Lithium== ...10 KB (1,352 words) - 12:43, 5 January 2025
- ...ion of Tin Oxalate-Reduced Graphene Oxide Composite Anode for Rechargeable Lithium Batteries |journal=[[ACS Applied Materials & Interfaces]] |date=9 August 20 ...4 KB (551 words) - 02:58, 1 December 2023
- |OtherCations=[[Lithium peroxide]]<br />[[Sodium peroxide]]<br />[[Potassium peroxide]]<br />[[Caes ...2 KB (300 words) - 17:59, 10 January 2024
- | OtherCations = [[lithium selenide]]<br/>[[sodium selenide]]<br/>[[potassium selenide]]<br/>[[rubidiu ...3 KB (317 words) - 04:32, 18 June 2023
- ...experiencing ever-increasing demand despite the limited availability of [[lithium]]. Developing high-performance sodium-ion batteries is a challenge because ...exhibit satisfactory high energy densities that are comparable to those of lithium-ion batteries as they operate through multi-electron redox reactions (V3+/V ...25 KB (3,510 words) - 05:03, 19 February 2025
- | supply = 2×"CR-2032" Lithium + 1×"CR-2032" Lithium ...6 KB (809 words) - 01:24, 4 October 2023
- | 84–120 [[kilowatt hour|kWh]] [[lithium-ion battery|lithium ion]] ...6 KB (792 words) - 09:43, 22 December 2024
- ...m amide (LiNR<sub>2</sub>) base (e.g., [[Lithium diisopropylamide|LDA]], [[Lithium bis(trimethylsilyl)amide|LHMDS]]). Subsequently, the enolate is reacted wi ...8 KB (1,071 words) - 08:05, 13 April 2024
- ...B.C. Smith, J.W. Rosenthal, W.L. Jolly|editor-surname1=H.F. Holtzlow|title=Lithium Bis(trimethylsilyl)amide and Tris(trimethylsilyl)amine, in Inorganic Synthe The reaction of lithium nitride with trimethylchlorosilane can be carried out as a one-pot reaction ...13 KB (1,771 words) - 01:25, 18 March 2023
- ...ng a [[Alkoxy group|lithium alkoxide]]. [[Acetic acid]] is added to remove lithium and liberate the free alcohol.<ref name="Midland"/> ...ter|Scheme 1. Reaction of ethyl propiolate with n-butyllithium to form the lithium acetylide.]] ...12 KB (1,584 words) - 08:49, 9 May 2024
- ...r and J. Newman, "The importance of the lithium ion transference number in lithium/polymer cells." Electrochim Acta, 39, 2073 (1994) 10.1016/0013-4686(94)850 ...11 KB (1,619 words) - 13:54, 14 February 2025