Search

Your search keyword '"Kostecki Robert"' showing total 18 results
Start Over Author "Kostecki Robert" Topic energy storage
18 results on '"Kostecki Robert"'

1. Infrared nanoimaging and nanospectroscopy of electrochemical energy storage materials and interfaces

Author

Larson, Jonathan M, Dopilka, Andrew, and Kostecki, Robert

Subjects
Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Nano-FTIR, s-SNOM, SINS, AFM-IR, Infrared nanospectroscopy, Batteries, Li-ion battery, Energy storage, Electrochemistry, Analytical chemistry, Physical chemistry, Nanotechnology
Abstract

Electrochemical interfaces are central to the function and performance of energy storage devices. Thus, the development of new methods to characterize these interfaces, in conjunction with electrochemical performance, is essential for bridging the existing knowledge gaps and accelerating the development of energy storage technologies. Of particular need is the ability to characterize surfaces or interfaces in a non-destructive way with adequate resolution to discern individual structural and chemical building blocks. To this end, sub-diffraction-limit low-energy infrared optical probes that exploit near-field interactions within atomic force microscopy platforms, such as pseudoheterodyne nanoimaging, photothermal nanoimaging and nanospectroscopy, and nanoscale Fourier transform infrared spectroscopy, are all powerful emerging techniques. These are capable of non-destructive surface probing and imaging at nanometer resolution. This review outlines recent efforts to characterize ex situ,in situ,andoperando electrode materials and electrochemical interfaces in rechargeable batteries with these advanced infrared near-field probes.

Published
2024

10. Power and capacity fade mechanism of LiNi0.8Co0.15Al0.0502 composite cathodes in high-power lithium-ion batteries

Author

Kostecki, Robert and McLarnon, Frank

Subjects
Energy storage, : Li-ion battery cathode carbon retreat conductivity micro-Raman AFM
Abstract

High-power Li-ion cells that were tested at elevated temperatures showed a significant impedance rise, which was associated primarily with the LiNi0.8Co0.15Al0.05O2 cathode. By systematically collecting thousands of Raman spectra from 50 x 80 mm areas at 0.9 mm spatial resolution, and integrating the respective bands of the cathode components for each spectrum, we were able to produce color-coded, semi-quantitative composition maps of cathode surfaces. Raman microscopy images of cathodes from tested cells revealed that cell cycling or storage at elevated temperatures led to significant changes in the LiNi0.8Co0.15Al0.05O2/elemental-carbon surface concentration ratio. The loss of conductive carbon correlated with the power and capacity fade of the tested cathodes. The cathode surface state of charge (SOC) varied between individual grains of active material, and at some locations the spectra indicated the presence of fully charged material, despite the deep cell discharge at the end of testing.

Published
2003

16. In situ infrared nanospectroscopy of the local processes at the Li/polymer electrolyte interface.

Author

He, Xin, Larson, Jonathan M., Bechtel, Hans A., and Kostecki, Robert

Subjects
ATTENUATED total reflectance, NEAR-field microscopy, POLYELECTROLYTES, SOLID electrolytes, FOURIER transform infrared spectroscopy, ENERGY density, ENERGY storage, NUCLEAR forces (Physics)
Abstract

Solid-state batteries possess the potential to significantly impact energy storage industries by enabling diverse benefits, such as increased safety and energy density. However, challenges persist with physicochemical properties and processes at electrode/electrolyte interfaces. Thus, there is great need to characterize such interfaces in situ, and unveil scientific understanding that catalyzes engineering solutions. To address this, we conduct multiscale in situ microscopies (optical, atomic force, and infrared near-field) and Fourier transform infrared spectroscopies (near-field nanospectroscopy and attenuated total reflection) of intact and electrochemically operational graphene/solid polymer electrolyte interfaces. We find nanoscale structural and chemical heterogeneities intrinsic to the solid polymer electrolyte initiate a cascade of additional interfacial nanoscale heterogeneities during Li plating and stripping; including Li-ion conductivity, electrolyte decomposition, and interphase formation. Moreover, our methodology to nondestructively characterize buried interfaces and interphases in their native environment with nanoscale resolution is readily adaptable to a number of other electrochemical systems and battery chemistries. Solid-state batteries remain promising but essential insights into electrode-electrolyte interface are required. Here, the authors report in situ infrared nanospectroscopy of the lithium-polymer-electrolyte interface to reveal its intrinsic molecular, structural, and chemical heterogeneities. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

17. Reversible Crosslinked Polymer Binder for Recyclable Lithium Sulfur Batteries with High Performance.

Author

Liu, Zhimeng, He, Xin, Fang, Chen, Camacho‐Forero, Luis E., Zhao, Yangzhi, Fu, Yanbao, Feng, Jun, Kostecki, Robert, Balbuena, Perla B., Zhang, Junhua, Lei, Jingxin, and Liu, Gao

Subjects
LITHIUM sulfur batteries, POLYSULFIDES, CROSSLINKED polymers, ENERGY storage, CONDUCTING polymers, X-ray photoelectron spectroscopy, LEAD-acid batteries
Abstract

Owing to the negative impact of the extensive utilization of batteries on the environment, sustainability of the cells needs to be included in the systemic research of batteries. Herein, a dissolvable ionic crosslinked polymer (DICP) is exploited as a binder for lithium–sulfur batteries by crosslinking the polyacrylic acid and polyethyleneimine through carboxy‐amino ionic interaction. This interaction is pH‐controlled, and therefore, the crosslinked binder network can be readily dissociated under basic conditions, providing a facile strategy enabling valuable components recycled through a convenient washing method. The sulfur cathode prepared using the recycled carbon–sulfur composite can deliver comparable capacity as that of fresh electrode. In addition, evidence from cell performance and characterizations, such as in situ X‐ray absorption spectroscopy, in situ UV–visible spectroscopy, X‐ray photoelectron spectroscopy, and density functional theory calculation, confirms that DICP is a more effective binder than its commercial counterpart on suppressing polysulfide dissolution in the electrolyte. Exploiting reversible crosslinked polymer binder for recyclable Li–S batteries with ameliorated electrochemical performance, this study illuminates sustainable development for large‐scale energy storage systems. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

18. Nonequilibrium Pathways during Electrochemical Phase Transformations in Single Crystals Revealed by Dynamic Chemical Imaging at Nanoscale Resolution.

Author

Yu, Young‐Sang, Kim, Chunjoong, Liu, Yijin, van der Ven, Anton, Meng, Ying Shirley, Kostecki, Robert, and Cabana, Jordi

Subjects
ENERGY density, ELECTRODES, SINGLE crystals, ELECTROCHEMICAL analysis, CRYSTAL whiskers
Abstract

The energy density of current batteries is limited by the practical capacity of the positive electrode, which is determined by the properties of the active material and its concentration in the composite electrode architecture. The observation in dynamic conditions of electrochemical transformations creates the opportunity of identifying design rules toward reaching the theoretical limits of battery electrodes. But these observations must occur during operation and at multiple scales. They are particularly critical at the single-particle level, where incomplete reactions and failure are prone to occur. Here, operando full-field transmission X-ray microscopy is coupled with X-ray spectroscopy to follow the chemical and microstructural evolution at the nanoscale of single crystals of Li1+ xMn2- xO4, a technologically relevant Li-ion battery electrode material. The onset and crystallographic directionality of a series of complex phase transitions are followed and correlated with particle fracture. The dynamic character of this study reveals the existence of nonequilibrium pathways where phases at substantially different potentials can coexist at short length scales. The results can be used to inform the engineering of particle morphologies and electrode architectures that bypass the issues observed here and lead to optimized battery electrode properties. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results