Energy storage

Donald Sadoway (right) of the Department of Materials Science and Engineering, David Bradwell MEng ’06, PhD ’11, and their collaborators have developed a novel molten-metal battery that is low-cost, high-capacity, efficient, long-lasting, and easy to manufacture — characteristics that make it ideal for storing electricity on power grids today and in the future.

A battery made of molten metals

New battery may offer low-cost, long-lasting storage for the grid.

January 12, 2016

The layer-by-layer solar thermal fuel polymer film comprises three distinct layers (4 to 5 microns in thickness for each). Cross-linking after each layer enables building up films of tunable thickness.

A new way to store solar heat

Material could harvest sunlight by day, release heat on demand hours or days later.

January 7, 2016

Preparing for large-scale solar deployment

Researchers are examining measures to ensure a reliable future power system.

December 30, 2015

William Braff PhD ’14, Martin Z. Bazant, and Cullen Buie are developing a low-cost, high-capacity, battery.

Novel bromine battery: Small-scale demo, large-scale promise

Low-cost, high-capacity, rechargeable battery could one day enable widespread adoption of intermittent energy sources such as solar and wind.

June 26, 2014

Panel participants (left to right): Donald Sadoway, Alexander Slocum, IHS Chairman Dan Yergin, Angela Belcher, MITEI Associate Director Lou Carranza, Robert Armstrong, Vladimir Bulovic, and CERA Co-Founder Jamey Rosenfield

MIT researchers describe 'energy game changers' at CERAWeek2014

MIT Energy Initiative Director Robert Armstrong leads panel, among other IHS CERAWeek sessions featuring MIT faculty and researchers.

March 14, 2014

A diagram of the molecular structure of double perovskite shows how atoms of barium (green) and a lanthanide (purple) are arranged within a crystalline structure of cobalt (pink) and oxygen (red).

New materials improve oxygen catalysis

Highly active catalysts could be key to improved energy storage in fuel cells and advanced batteries.

September 17, 2013

New rechargeable flow battery enables cheaper, large-scale energy storage

Design may support widespread use of solar and wind energy.

August 16, 2013

MIT graduate researchers Robert Mitchell and Betar Gallant connect a Li-air battery used to prepare the samples for in-situ Transmission Electron Microscope (TEM) characterization.

Research update: Team observes real-time charging of a lithium-air battery

Imaging reveals what happens during charging; could lead to improved batteries for electric cars.

May 13, 2013

Eric Martinot addressed the future of renewable energy at an MIT event on April 18.

The case for optimism about a renewable energy future

Researcher Eric Martinot presents findings of two-year project at campus event

May 1, 2013

Wind power — even without the wind

Innovative storage system could enable offshore wind farms to deliver power whenever it’s needed.

April 25, 2013

Joel Schindall of electrical engineering and computer science (left) and Riccardo Signorelli PhD ’09 of FastCAP Systems examine carbon-nanotube-coated samples that proved key to the development of the full-scale, high-performance ultracapacitors now being marketed by FastCAP.

A novel ultracapacitor

Energy when and where you need it.

October 9, 2012

A solid-state lithium-air battery (highlighted in orange) is positioned inside a test chamber at the Advanced Light Source (ALS) at Lawrence Berkeley National Laboratory, in preparation for its testing using X-ray photoelectron microscopy.

New technique reveals lithium in action

Fundamental reactions behind advanced battery technology, revealed in detail by advanced imaging method, could lead to improved materials.

October 8, 2012

Professor Donald Sadoway and Materials Processing Center Research Affiliate David Bradwell observe one of their small test batteries in the lab. The battery itself is inside the heavily insulated metal cylinder at center, which heats it to 700 degrees Celsius.

Liquid batteries could level the load

MIT team makes progress toward goal of inexpensive grid-scale batteries that could help make intermittent renewable energy sources viable.

February 14, 2012

Lithium-rich and lithium-poor regions tend to form bands inside particles of lithium iron phosphate.

Revealing how a battery material works

MIT team uncovers a reason why the hottest new material for rechargeable batteries works so well.

February 8, 2012

Solving energy problems, one molecule at a time

Materials scientist explores new possibilities in topics from molecules to rooftop solar panels.

January 26, 2012

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