Liquid Ammonia Chemical Lithiation: An Approach for High-Energy and High-Voltage Si–Graphite|Li1+xNi0.5Mn1.5O4 Li-Ion Batteries

Dose, Wesley M.; Blauwkamp, James; Muñoz, María José Piernas; Bloom, Ira; Xue, Rui; Klie, Robert F.; Senguttuvan, Premkumar; Johnson, Christopher

doi:10.1021/acsaem.9b00695

Cited by 36 publications

(34 citation statements)

References 66 publications

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“…[ 87 ] In addition, the liquid ammonia is introduced to dissolve the lithium metal during the prelithiation process. [ 88 ] This method is viable and even scalable to overlithiate cathode materials. In this case, a lithiated 5 V spinel Li 1+ x Ni 0.5 Mn 1.5 O 4 cathode materials have been successfully prepared, showing relatively high first delithiation capacities.…”

Section: Classification Of Prelithiation/presodiation Technologiesmentioning

confidence: 99%

“…Considering the highly reactive nature of Li/Na metal, the detailed experiments must be operated in inert environments with H 2 O <0.1 ppm and O 2 <0.1 ppm. Interestingly, a polymer layer (e.g., poly(methyl methacrylate)) can be selected to protect the lithium against Regeneration of battery [171] Thermal lithiation Sn Compensation of irreversible capacity loss [86] Thermal lithiation Si Preparation of prelithiated surface oxide layer [159] High-energy ball-milling with Li Si Compensation of irreversible capacity loss [87] Chemical lithiation with liquid NH 3 LiNi 0.5 Mn 1.5 O 4 Compensation of irreversible capacity loss [88] Chemical lithiation…”

Section: Operation With Li/na Metalmentioning

confidence: 99%

“…[87] In addition, the liquid ammonia is introduced to dissolve the lithium metal during the prelithiation process. [88] This method is viable and even scalable to overlithiate cathode materials. In this case, a lithi- In conclusion, the concept of operation of Li/Na metal based on various approaches could enable the accomplishment of prelithiation/presodiation.…”

Section: (6 Of 23)mentioning

confidence: 99%

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Prelithiation/Presodiation Techniques for Advanced Electrochemical Energy Storage Systems: Concepts, Applications, and Perspectives

Zou

Deng

Cai

et al. 2020

Adv Funct Materials

178

122

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Prelithiation/presodiation techniques are regarded as indispensable procedures in electrochemical energy storage (EES) systems, which can effectively compensate irreversible capacity loss, raise working voltage, and increase Li+/Na+ concentration in the electrolyte. Various prelithiation/presodiation methods have been successfully exploited and a revolutionary impact has been achieved through the utilization of prelithiation/presodiation techniques. It is well acknowledged that different prelithiation/presodiation strategies possess their own specific mechanisms, which play vital roles in the advancement of EES systems. However, there has rarely been systematical reviews about the concept and progress of prelithiation/presodiation techniques. Hence, in this review various prelithiation/presodiation approaches are comprehensively analyzed and summarized, and in‐depth prelithiation/presodiation behaviors and other innovative applications (including optimization of separators, amelioration of binders, regeneration of spent batteries) are discussed in detail. Finally, suggested future directions of prelithiation/presodiation techniques are proposed and it is expected that these prelithiation/presodiation techniques could provide guidance for construction of advanced EES systems and propel the commercialization process with a focus on safety considerations.

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Section: Classification Of Prelithiation/presodiation Technologiesmentioning

confidence: 99%

Section: Operation With Li/na Metalmentioning

confidence: 99%

“…[87] In addition, the liquid ammonia is introduced to dissolve the lithium metal during the prelithiation process. [88] This method is viable and even scalable to overlithiate cathode materials. In this case, a lithi- In conclusion, the concept of operation of Li/Na metal based on various approaches could enable the accomplishment of prelithiation/presodiation.…”

Section: (6 Of 23)mentioning

confidence: 99%

See 1 more Smart Citation

Prelithiation/Presodiation Techniques for Advanced Electrochemical Energy Storage Systems: Concepts, Applications, and Perspectives

Zou

Deng

Cai

et al. 2020

Adv Funct Materials

178

122

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“…All gravimetric capacities were extracted from the related literatures. [8,24,27,[37][38][39]56,[58][59][60][63][64][65][66]69,71,98] www.advancedsciencenews.com of Si-carbon nanotubes electrodes was successfully realized by directly dropping 3% SLMPs/toluene solution onto the electrode followed by thermal evaporation to remove the residual toluene (Figure 3a). [52] However, such operation process is not compatible with slurry fabrication process in current battery industry, since SLMPs possess high reactivity with solvents such as water and NMP for slurry, and the powder state of SLMPs poses serious safety concern during their application.…”

Section: Chemical and Ambient Stability Of The Prelithiation Materials/reagentsmentioning

confidence: 99%

“…All gravimetric capacities were extracted from the related literatures. [ 8,24,27,37–39,56,58–60,63–66,69,71,98 ]…”

Section: Donable Lithium‐ion Capacity/prelithiation Efficiencymentioning

confidence: 99%

Promises and Challenges of the Practical Implementation of Prelithiation in Lithium‐Ion Batteries

Zhan

Wang

Chen

et al. 2021

Advanced Energy Materials

158

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graphite-based anodes, active lithium from the lithium-containing oxide or phosphate cathode is consumed due to the side reactions during the formation of solid electrolyte interface (SEI) on the anode surface, accompanied by the decomposition of liquid electrolyte. This leads to Coulombic efficiency values lower than 100% in the very initial charge/discharge cycles (e.g., 90%-95% for the first cycle), which appreciably reduces the energy density of LIBs. [10][11][12][13] For the next-generation highenergy-density LIBs, high-capacity anodes (e.g., Si, Sn, and P with alloy reaction mechanism) undergo much more serious side reactions and show much more initial lithium loss (e.g., >15%) than the graphitebased anodes. Moreover, the side reactions of these high-capacity anodes continue to take place for several cycles, sometimes even tens of cycles, before the stabilization of Coulombic efficiency to over 99.9%, due to the large volume change of these materials (e.g., ≈420% for Si, ≈260% for Sn, and ≈300% for P) from lithium-free state to full lithiation state, which leads to large amount of accumulated lithium loss. [14,15] Consequently, the usable lithium-ion capacity and overall energy density of LIBs using these high-capacity anode materials would be significantly decreased.Prelithiation has been widely investigated as a promising strategy to resolve this lithium loss issue and increase the energy density of LIBs. With the specific purpose of compensating for the initial lithium loss in LIBs, prelithiation is conceptually independent from the pretreatment of battery materials or electrodes, and it can be simply regarded as providing additional active lithium using specific prelithiation reagents/ materials or processing to LIBs prior to battery cell cycling. To increase active lithium inside the entire LIBs, prelithiation can be performed on different battery components, cathodes, or anodes, and also at different levels, materials, or electrodes, depending on the prelithiation approaches. Till now, various prelithiation methods have been developed, including electrochemical prelithiation at the electrode level, [16][17][18][19] chemical prelithiation at the materials or electrode level, [20][21][22] prelithiation additives for cathodes and anodes, [8,[23][24][25][26][27] and direct contact/short circuit between a negative electrode and a lithium metal foil. [28][29][30][31] These prelithiation methods with various mechanisms show different prelithiation efficiency or capability in increasing the energy density of LIBs and other effects, and Lithium-ion batteries (LIBs) have changed lives since their invention in the early 1990s. Further improvement of their energy density is highly desirable to meet the increasing demands of energy storage applications. Active lithium loss in the initial charge process appreciably reduces the capacity and energy density of LIBs due to the formation of a solid electrolyte interface (SEI) on the anode surface, especially for Si based anodes in high-energy-density batteries. To solve...

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Pre‐sodiation Technologies

Song,

Liu,

2023

Sodium Ion Capacitors

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Liquid Ammonia Chemical Lithiation: An Approach for High-Energy and High-Voltage Si–Graphite|Li_1+xNi_0.5Mn_1.5O₄ Li-Ion Batteries

Cited by 36 publications

References 66 publications

Prelithiation/Presodiation Techniques for Advanced Electrochemical Energy Storage Systems: Concepts, Applications, and Perspectives

Prelithiation/Presodiation Techniques for Advanced Electrochemical Energy Storage Systems: Concepts, Applications, and Perspectives

Promises and Challenges of the Practical Implementation of Prelithiation in Lithium‐Ion Batteries

Pre‐sodiation Technologies

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