The Electrochemical Energy Systems Laboratory (ECSL) was established at Drexel in 2009 by Dr. E. Caglan Kumbur to address the research and development needs of emerging alternative
Electrochemical Energy Storage for Green Grid. Click to copy article link Article link copied! Zhenguo Yang * Jianlu Zhang; Michael C. W. Kintner-Meyer Jun Liu; View Author Information View Author Information.
Electrochemical power conversion and storage including polymer electrolyte fuel cells, flow battery systems, and biological energy systems. Multi-phase transport visualization and characterization. Computational simulation of
Lithium metal is considered to be the most ideal anode because of its highest energy density, but conventional lithium metal–liquid electrolyte battery systems suffer from low Coulombic
Electrochemical energy storage -Precisely engineered nanocrystals as high-performance cathode and anode materials in rechargeable Li-ion, Na-ion and Mg-ion batteries -Novel concepts for electrochemical energy storage
Our research activities are focusing on the development and diagnostic studies of new electrochemical energy storage systems, especially for vehicle applications, and new materials for these systems. Brookhaven Science Associates
High entropy materials (HEMs) with a single-phase structure have introduced a brand-new area of research in electrochemical energy conversion and storage devices. The fusion of divergent
Cost-effective and high-performance electrochemical energy storage devices can increase the fuel efficiency of new transportation technologies, including start-stop vehicle, (plug-in) hybrid
designing materials and electrolytes for energy We study complex phenomena in solids and liquids and at their electrified interfaces. We apply the fundamental knowledge that we gained
Electrochemical energy storage and conversions, including fuel cells, electrolyzers, batteries. Alternative fuel and renewable energy, including biofuel, solar energy and wind power. Hybrid energy systems. Thermal control and
Key Laboratory of Physics and Technology for Advanced Batteries (Ministry of Education), State Key Laboratory of Superhard Materials, College of Physics, Jilin University,
Our research programs are centered on understanding the electronic structures of surfaces, with emphasis on metal oxides, searching for descriptors of catalytic activity, surface/interface reactivity and ion transport,
The team is particularly focused on science and technology underlying sustainable energy and the decarbonization of the economy, including clean electrochemical energy storage via batteries and hydrogen fuel necessary to
Supported largely by DOE''s OE Energy Storage Program, PNNL researchers are developing novel materials in not only flow batteries, but sodium, zinc, lead-acid, and flywheel storage systems that are boosting performance, safety, and
2 Electrochemical Energy Storage Technologies Electrochemical storage systems use a series of reversible chemical reactions to store electricity in the form of chemical energy. Batteries are
Electrochemical Energy Storage is the missing link for 100% renewable electricity and for making transportation carbon-free. Lithium ion batteries (LIBs) dominate these markets, and we are working on developing better anode, cathode, and
Search energy storage technologies available for licensing through our Intellectual Property Office. Through CalCharge and other partnerships, Berkeley Lab has strong collaborative ties with a broad range of energy storage companies in the Bay Area and beyond.
We design electrochemical processes by tuning local chemical environments at the solid-electrolyte interface. Our research relies on molecular engineering of the electrolytes and interfaces, aiming to achieve fast and stable electrochemical energy storage and conversion.
This public summit convened and connected national and regional thought leaders across industry, government, communities, and the research enterprise to catalyze solutions and partnerships around specific challenges to America’s energy storage future.
Our group puts a significant emphasis on mechanistic studies and the utilization of advanced characterization techniques. We use in situ X-ray scattering and spectroscopy, FTIR and Raman spectroscopy, and electrochemical quartz crystal microbalance techniques to probe electrolytes and solid-electrolyte interfaces.
Exponential energy storage deployment is both expected and needed in the coming decades, enabling our nation’s just transition to a clean, affordable, and resilient energy future.
We are deeply committed to excellence in all our endeavors.
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