Hysteretic order-disorder transitions of ionic liquid double layer structure on graphite

Wan Yu Tsai, Jeremy Come, Wei Zhao, Runxi Wang, Guang Feng, Bishnu Prasad Thapaliya, Sheng Dai, Liam Collins, Nina Balke

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Abstract

Understanding the electrical double layer (EDL) structure at the solid/liquid interface is critical towards realizing the full potential of electrochemical applications using ionic liquids. In this work, the out-of-plane and in-plane EDL structures of PYR 14 -TFSI on graphite (HOPG) have been studied by in-situ electrochemical atomic force microscopy (AFM) and molecular dynamics (MD) simulation. AFM results revealed that the first adsorbed ion layer on HOPG consists of both disordered and ordered lateral domains. It has been found that the neighboring molecules in the x-y plane form intricate ordered lateral structures on length scale of hundreds of nanometers, and the out-of-plane EDL structure is independent of the in-plane structure. MD simulations under zero polarization showed that in the first adsorbed layer, cations have one preferred orientation while anions have two preferred orientations in relation to the HOPG surface, which might be the origin of the complex lateral ordering. When polarizing the surface, a hysteretic order-disorder transition of the lateral ordering in the first adsorbed layer can be observed by in-situ AFM, and the ordered domains disappear for high positive or negative voltages. Comparison with bias-dependent MD reveals that the existence of a bimodal anion distribution in the first absorbed layer can be linked to the observed transitions giving new insights into the origin of the structural domains, which can help understand unusual charge and discharge kinetics observed in similar systems.

Original languageEnglish
Pages (from-to)886-893
Number of pages8
JournalNano Energy
Volume60
DOIs
StatePublished - Jun 2019

Funding

AFM measurements and ionic liquid synthesis were supported by the Fluid Interface Reactions, Structures and Transport (FIRST) Center , an Energy Frontier Research Center (EFRC) funded by the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences (W.-Y.T., J.C., N.B., B.P.T, S.D) . The experiments and sample preparation in this work were performed and supported at the Center for Nanophase Materials Sciences in Oak Ridge National Lab, which is a DOE Office of Science user facility (L.C.). W.Z., R.W. and G.F. acknowledge the support from National Natural Science Foundation of China ( 51876072 ) which funded the molecular dynamic simulations. Simulations were performed at the National Supercomputing Centers in Tianjin (Tianhe-1A) and Guangzhou (Tianhe II). The authors also thank Celine Merlet, De-en Jiang, Matt Thompson, Paul Fenter, and Brandon Wood for fruitful discussions.

FundersFunder number
Energy Frontier Research Center
Office of Basic Energy Sciences
U.S. Department of Energy
Office of Science
National Natural Science Foundation of China51876072

    Keywords

    • Atomic force microscopy
    • Electrical double layer structure
    • Electrode/electrolyte interface
    • Ionic liquids
    • Molecular dynamic simulation
    • Self-assembly

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