Results 71 to 80 of about 61,419 (203)

All-solid-state lithium-sulfur battery based on a nanoconfined LiBH₄ electrolyte [PDF]

, 2016
In this work we characterize all-solid-state lithium-sulfur batteries based on nano-confined LiBH4in mesoporous silica as solid electrolytes. The nano-confined LiBH4has fast ionic lithium conductivity at room temperature, 0.1 mScm-1, negligible ...
Blanchard, Didier, Das, Supti, De Jongh, Petra E., Ngene, Peter, Norby, Poul, Vegge, Tejs   +5 more
core   +2 more sources

Performance of Li4Ti5O12-based reference electrode for the electrochemical analysis of all-solid-state lithium-ion batteries

Electrochemistry Communications, 2020
The establishment of three-electrode cells for all-solid-state lithium-ion batteries is an important issue to clarify the electrochemical behavior of the battery components and solve problems for the practical applications.
Atsunori Ikezawa, Goro Fukunishi, Takeyoshi Okajima, Fusao Kitamura, Kota Suzuki, Masaaki Hirayama, Ryoji Kanno, Hajime Arai   +7 more
doaj   +1 more source

Sintered Cathodes for All-Solid-State Structural Lithium-Ion Batteries [PDF]

All-solid-state structural lithium ion batteries serve as both structural load-bearing components and as electrical energy storage devices to achieve system level weight savings in aerospace and other transportation applications.
Dynys, Frederick, Huddleston, William, Sehirlioglu, Alp   +2 more
core   +1 more source

Suppression of Phase Separation in LiFePO4 Nanoparticles During Battery Discharge

, 2011
Using a novel electrochemical phase-field model, we question the common belief that LixFePO4 nanoparticles separate into Li-rich and Li-poor phases during battery discharge.
Allen S. M., Amine K., Armand M., Aziz M. J., Balluffi R. W., Bazant M. Z., Bockris J. O. M., Branicio P. S., Burch D., Cahn J. W., Chen G. Y., Chung S. Y., Daniel A. Cogswell, Dargaville S., Delmas C., Dreyer W., Dupre N., Granasy L., Guyer J. E., Han B. C., Huang H., Huggins R. A., Islam M. S., Kang B., Kao Y. H., Karma A., Kuwahara A., Laffont L., Leriche J. B., Malik R., Malik R., Martin Z. Bazant, Meethong N., Meethong N., Morgan D., Murau P., Nauman E. B., Newman J. S., Padhi A. K., Pasquali M., Peng Bai, Ramana C. V., Ravet N., Ravet N., Shenouda A. Y., Singh G. K., Srinivasan V., Tan H. J., Tang M., Tang M., Tarascon J. M., Van der Ven A., Wang C. S., Whittingham M. S., Wu X. L., Yamada A., Yamada A., Zhu Y. J.   +57 more
core   +1 more source

Modelling Li+ Ion Battery Electrode Properties [PDF]

, 2008
We formulated two detailed models for an electrolytic cell with particulate electrodes based on a lithium atom concentration dependent Butler-Volmer condition at the interface between electrode particles and the electrolyte.
Anderson, D. M., Arroyo, A., Bellsky, T., Bohun, C. S., Breward, C., Bui Boi, A. M., Chi, H., Cipcigan, I., Fehribach, J. D., Franklin, M., Melara, L., Nguyen, L., Please, C.P., Richardson, G., Siddique, J., Swaminathan, S., Trichtchenko, O., Vernescu, B., Wang, Y., Zhang, C.   +19 more
core  

Ceramic Composite Cathodes for All-Solid-State Lithium Batteries

ECS Meeting Abstracts, 2020
Oxide-ceramic based all-solid-state lithium batteries (ASSLB) can provide high intrinsic safety, extended operational temperature range, and high energy density. As the first two are intrinsic to the materials system, one prerequisite to obtain high energy densities with such ASSLBs is the manufacturing of composite cathodes.
Martin Ihrig, Chih Long Tsai, Martin Finsterbusch, Dina Fattakhova-Rohlfing, Olivier Guillon   +4 more
openaire   +2 more sources

Halide segregation to boost all-solid-state lithium-chalcogen batteries [PDF]

Science
Mixing electroactive materials, solid-state electrolytes, and conductive carbon to fabricate composite electrodes is the most practiced but least understood process in all-solid-state batteries, which strongly dictates interfacial stability and charge transport.
Jieun Lee, Shiyuan Zhou, Victoria C. Ferrari, Chen Zhao, Angela Sun, Sarah Nicholas, Yuzi Liu, Chengjun Sun, Dominik Wierzbicki, Dilworth Y. Parkinson, Jianming Bai, Wenqian Xu, Yonghua Du, Khalil Amine, Gui-Liang Xu   +14 more
openaire   +2 more sources

Nanoscale Imaging of Lithium Ion Distribution During In Situ Operation of Battery Electrode and Electrolyte

, 2013
A major challenge in the development of new battery materials is understanding their fundamental mechanisms of operation and degradation. Their microscopically inhomogeneous nature calls for characterization tools that provide operando and localized ...
Abruña, Héctor D., Arias, Tomás A., Gao, Jie, Gunceler, Deniz, Holtz, Megan E., Muller, David A., Schwarz, Kathleen A., Sundararaman, Ravishankar, Yu, Yingchao   +8 more
core   +1 more source

Thermal Recovery of the Electrochemically Degraded LiCoO₂/Li₇La₃Zr₂O₁₂:Al,Ta Interface in an All-Solid-State Lithium Battery. [PDF]

ACS Appl Mater Interfaces, 2023
Ihrig M, Kuo LY, Lobe S, Laptev AM, Lin CA, Tu CH, Ye R, Kaghazchi P, Cressa L, Eswara S, Lin SK, Guillon O, Fattakhova-Rohlfing D, Finsterbusch M.   +13 more
europepmc   +1 more source

High capacity all-solid-state lithium battery enabled by in situ formation of an ionic conduction path by lithiation of MgH₂. [PDF]

RSC Adv, 2022
Inoishi A, Sato H, Chen Y, Saito H, Sakamoto R, Sakaebe H, Okada S.   +6 more
europepmc   +1 more source