ECS Fellow and technical editor of the Journal of The Electrochemical Society, Charles Hussey, recently added one more item to his list of career accomplishments.

The esteemed scientist and integral member of the University of Mississippi’s chemistry and biochemistry department has been named the new associate dean for research and graduate education at the university’s College of Liberal Arts.

“I am very excited about the chance to serve in this role and anxious to get started,” Hussey said in a release.

Hussey states that since the appointment of Dean Lee Cohen, the university began to shift in a new direction focused on research and graduate education. “I want to be part of helping him move the college forward in these areas,” he said.

With his extensive scientific background and experience serving as a chair of a department, Hussey will be looking to reflect those experiences in his new position. He will also be aiming to evaluate current issues students face pertaining to research engagement, scholarship, and graduate education.

“Once I have a sense of the issues, then we will work with other departments to develop long-range strategies that make use of our available resources to attack these roadblocks,” said Hussey, the 2014 winner of ECS’s Max Bredig Award in Molten Salt and Ionic Liquid Chemistry. “I also see potential for the growth of new graduate programs in the college.”

In addition to his new appointment, Hussey plans to continue his research into electrochemistry and transport properties of ionic liquids and molten salts.

Chennupati Jagadish, distinguished professor at Australian National University

Chennupati Jagadish, long-time member and ECS Fellow, has recently been selected to receive Australia’s highest civilian honor. The Australian National University distingused professor has been named a Companion of the Order of Australia (AC), for his “eminent service to physics and engineering, particularly in the field of nanotechnology, to education as a leading academic, researcher, author and mentor, and through executive roles with national and international scientific advisory institutions.”

(MORE: Read Jagadish’s published research in the ECS Digital Library.)

“I am humbled, honored, and grateful for this honor,” Jagadish, former recipient of the ECS Electronics and Photonics Divison Award, said. “This is a wonderful recognition for 25 plus years of work my research group at the Australian National University in the field of semiconductor optoelectronics and nanotechnology.”

Jagadish’s work takes the form of such novel innovations as lasers for telecommunications, increased efficiency solar cells, and artificial, trainable neurons.

Throughout his scientific career, Jagadish has published more than 620 research papers and five U.S. patents.
“They say that rest is for the weak,” Jangadish said. “I say, ‘Look, I’m having fun.’ Science is fun for me and when you’re having fun you don’t really look at how long you’re working.”

What better day than Earth Day to highlight the work of ECS member Luke Haverhals, an assistant professor at Bradley University working in novel types of energy storage and conversion through the utilization of renewable, sustainable substrates such as hemp, wood, and silk.

Haverhals is a former student of current ECS 3rd Vice-President Johna Leddy. Since departing from Leddy and the University of Iowa, Haverhals has worked in an area focused on wielding natural fibers using ionic liquids (i.e. enhanced energy conversion devices).

Ionic liquids have been gaining much notoriety lately, with potential game changing electrolytes for energy conversion devices ranging from batteries to fuel cells.

Make sure to join Haverhals and other scientists pioneering world-changing research by joining ECS today and attending our upcoming scientific meeting!

The Electrochemical Society’s Vilas Pol has developed a new process to turn simple packing peanuts into energy-storing battery components.

Pol, an associate professor at Purdue University and active member of ECS, has thoroughly succeeded in turning one person’s trash into another person’s high-tech treasure. He and his team from Purdue University have developed a system that turns the puffy packing peanuts into nanoparticles and microsheets perfect for rechargeable batteries. Pol’s new generation of battery could even outperform the ones we currently use.

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The new development provides a mechanism for engineers to design a simpler proton separation membrane.
Image: Nature Communication

We’ve all heard of graphene’s tremendous potential, which may be able to change the manufacturing process in many industries. The wonder material could make production faster, cheaper, and more efficient across the board.

Now, three ECS members have collaborated with other fellow scientists to develop a single layer graphene that could change the landscape of hydrogen fuel cell technology.

ECS members Robert Sacci, Sheng Dai, and Matthew Neurock are contributing authors on the recently published paper, “Aqueous proton transfer across single-layer graphene”.

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Edgar’s new patented process will allow for the building of better semiconductors.
Source: Kansas State University

The Electrochemical Society’s Jim Edgar has developed a new process to build better semiconductors, which will vastly improve the efficiency of electronic devices and help propel the semiconductor industry.

Edgar, a Kansas State university distinguished professor of chemical engineering and an active member of ECS since 1981, has just received a patent for his “Off-axis silicon carbide substrates” process, which is a way to build a better semiconductor. This new process could mean big things for the electronics and semiconductor manufacturing industries.

“It’s like a stacked cake separated by layers of icing,” Edgar said. “When the layers of semiconductors don’t match up very well, it introduces defects. Any time there is a defect, it degrades the efficiency of the device.”

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The development could help lead to safe, efficient artificial photosynthetic systems that replicate the natural process of photosynthesis that plants use to convert sunlight, water, and carbon dioxide into oxygen and fuel in the form of carbohydrates, or sugars.
Source: Caltech

The Electrochemical Society’s Nate Lewis is leading some pioneering research at Caltech with the vision of efficient, affordable, and effective renewable energy sources.

Dr. Lewis, an active member of ECS since 1982, has designed a novel electrically conductive film – which has the potential to result in the development of devices that can harness sunlight to change water into hydrogen fuel.

(Take a look at his plenary lecture on sustainable energy technology he gave at a past ECS meeting.)

“We’ve discovered a material which is chemically compatible with the semiconductor it’s trying to protect, impermeable to water, electrically conductive, highly transparent to incoming light, and highly catalytic for the reaction to make oxygen and fuels,” said Dr. Lewis.

He and his team have developed a process that allows the solar-driven production of fuel to be performed with record efficiency, stability, and effectiveness.

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Brightman (left) and Hinds (right) have developed a novel electrode to boost green hydrogen research.
Image: National Physical Laboratory

ECS members Edward Brightman and Gareth Hinds of the National Physical Laboratory have developed a novel reference electrode that will aid in the development of hydrogen production technologies for renewable energy storage.

Both Brightman and Hinds will present their work on reference electrodes at the 227th ECS Meeting in Chicago this May. (Get an advanced look at that presentation here.)

Brightman and Hinds’ work deals with polymer electrolyte membrane water electrolysers (PEMWEs), which convert electricity and water into hydrogen and oxygen using two electrodes separated by a solid polymer electrolyte. While scientists have been looking and PEMWEs as a promising technology for some time now, researchers have been stifled in utilizing them due to the expensive catalyst materials needed and the general poor understanding of the degradation of these catalysts.

Now, Brightman and Hinds have tackled this issue by finding a way to produce PEMWEs with a cost-effective design and extended lifetime. This development allows for in situ measurement of the electrochemical process at the anode and the cathode.

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