Publications

2022
Bar Gavriel, Bergman, Gil , Turgeman, Meital , Nimkar, Amey , Elias, Yuval , Levi, Mikhael D. , Sharon, Daniel , Shpigel, Netanel , and Aurbach, Doron . 2022. Aqueous Proton Batteries Based On Acetic Acid Solutions: Mechanistic Insights. Materials Today Energy, Pp. 101189. doi:10.1016/j.mtener.2022.101189.
Daniel Sharon, Deng, Chuting , Bennington, Peter , Webb, Michael A. , Patel, Shrayesh N. , de Pablo, Juan J. , and Nealey, Paul F. . 2022. Critical Percolation Threshold For Solvation-Site Connectivity In Polymer Electrolyte Mixtures. Macromolecules, 55, Pp. 7212-7221. doi:10.1021/acs.macromol.2c00988. Abstract
Poly(ethylene oxide) (PEO)-based polymer electrolytes are often mixed with rigid, nonconductive polymers to improve mechanical strength. The suppressed conductivity of the mixture typically arises from a reduced segmental mobility and a diminished connectivity between conductive PEO sites. To decouple these two mechanisms, we compare transport in symmetric miscible blends and disordered block copolymers (BCP) of PEO and poly(methyl methacrylate) (PMMA). Because the two systems have identical physicochemical properties, differences in their conductivity directly reflect the underlying PEO network connectivity. We find that, at short distances (<5 Å), the Li+ solvation networks are identical for the two systems; however, a distinct variation in the network connectivity arises at length scales between 5 and 10 Å. Specifically, the BCP exhibits a lower connectivity, and therefore a lower conductivity than the blend. A quantitative model is proposed that associates long-range Li+ transport with local miscibility; the concept of network connectivity discussed here could be useful for designing polymer electrolyte systems.
Ran Attias, Dlugatch, Ben , Blumen, Omer , Shwartsman, Keren , Salama, Michal , Shpigel, Netanel , and Sharon, Daniel . 2022. Determination Of Average Coulombic Efficiency For Rechargeable Magnesium Metal Anodes In Prospective Electrolyte Solutions. Acs Applied Materials & Interfaces, 14, Pp. 30952-30961. doi:10.1021/acsami.2c08008.
Gil Bergman, Nimkar, Amey , Saha, Arka , Gavriel, Bar , Hen, Meital , Malchik, Fyodor , Fan, Tianju , Tsubery, Merav Nadav , Noked, Malachi , Sharon, Daniel , and Shpigel, Netanel . 2022. Development Of Electroactive And Stable Current Collectors For Aqueous Batteries. Journal Of The Electrochemical Society, 169, Pp. 050516. doi:10.1149/1945-7111/ac6c0c. Abstract

The need for low-cost, high-safety batteries for large-scale energy storage applications has sparked a surge in research of rechargeable aqueous batteries. While most research efforts are focused on the development of electrolyte formulations and electrode materials, it appears that the current collector impact on the battery performance is frequently overlooked. Even though the current collector is traditionally thought of as an inactive battery component, it is included in the battery energy density calculations, making its activation desirable. Furthermore, poor current collector selection can cause irreversible side reactions, resulting in rapid cell efficiency decay. Herein we propose a new approach to design current collectors that makes use of anodized Ti. The redox-active anodized Ti significantly improves the overall anode capacity and provides effective inhibition of hydrogen formation on the electrified interface. The use of TiO 2 particles on an anodized Ti current collector in an aqueous electrolyte solution resulted in capacity of 130 mAh g −1 and exceptional capacity retention of 99% after 1000 cycles. Although the concept of active current collectors needs to be refined before it can be implemented in commercial cells, our findings indicate that this approach could be useful for improving overall cell performance without requiring significant changes to its configuration.

Pei Liu, Counihan, Michael J. , Zhu, Yisi , Connell, Justin G. , Sharon, Daniel , Patel, Shrayesh N. , Redfern, Paul C. , Zapol, Peter , Markovic, Nenad M. , Nealey, Paul F. , Curtiss, Larry A. , and Tepavcevic, Sanja . 2022. Increasing Ionic Conductivity Of Poly(Ethylene Oxide) By Reaction With Metallic Li. Advanced Energy And Sustainability Research, 3, 1, Pp. 2100142. doi:10.1002/aesr.202100142.
Asmita Dutta, Sathiyan, Krishnamoorthy , Sharon, Daniel , and Borenstein, Arie . 2022. Laser Induced Incorporation Of Cnts In Graphene Electrodes Improves Flexibility And Conductivity. Flatchem, 33, Pp. 100378. doi:10.1016/j.flatc.2022.100378.
Asmita Dutta, Sharon, Daniel , Shpigel, Netanel , and Borenstein, Arie . 2022. Mxenes In Aqueous Electrochemical Energy Systems. Journal Of Solid State Electrochemistry. doi:10.1007/s10008-022-05244-5.
Amey Nimkar, Chae, Munseok S. , Wee, Shianlin , Bergman, Gil , Gavriel, Bar , Turgeman, Meital , Malchik, Fyodor , Levi, Mikhael D. , Sharon, Daniel , Lukatskaya, Maria R. , Shpigel, Netanel , and Mandler, Daniel . 2022. What About Manganese? Toward Rocking Chair Aqueous Mn-Ion Batteries. Acs Energy Letters, Pp. 4161-4167. doi:10.1021/acsenergylett.2c02242.