3 New Job Postings in Electrochemistry

Find openings in your area via the ECS job board.

Find openings in your area via the ECS job board.

ECS’s job board keeps you up-to-date with the latest career opportunities in electrochemical and solid-state science. Check out the latest openings that have been added to the board:

Battery Scientist
Imprint Energy – Alameda, California
Imprint Energy is seeking an exceptionally talented, innovative, and versatile Battery Scientist to join our technical team and “make it work!” This person will join a small but growing team with momentum behind them. The successful candidate will have the opportunity to shape the development of Imprint Energy’s novel battery technology from early prototypes through to application development and mass deployment. The successful candidate will have a strong background in electrochemistry and battery research and development.

Director of Research
ZincNyx Energy Solutions, Inc. – Vancouver, BC, Canada
We are looking for the right candidate to fill our Director of Research position based out of our beautiful Vancouver, BC office. The position is permanent, full time and will skyrocket the right candidate’s career!

Postdoctoral Fellow in Electrocatalysis
Miami University – Oxford, Ohio
Postdoctoral Fellow to conduct laboratory research on electrocatalysis of facet-controlled Pt-group metal nanocrystals, interpret and analyze obtained results, draft manuscripts reporting experimental results, assist supervising graduate and undergraduate researchers in the group.

New Sensor Can Improve the Taste of Your Wine

PhD student Joana Guerreiro has taken part in developing a sensor, which has been dubbed the 'mini-mouth'.Credit: Lars Kruse, Aarhus University

PhD student Joana Guerreiro has taken part in developing a sensor, which has been dubbed the ‘mini-mouth’.
Credit: Lars Kruse, Aarhus University

The ‘mini-mouth’ – that’s what scientists have dubbed the new nanosensor that can mimic the sensation that wine creates in a person’s mouth, which then determines how a specific alcohol tastes.

This technology was created by PhD student Joana Guerreiro from Aarhus University in Denmark, and sets out to detect the level of astringency associated with a particular wine. A wine’s astringency is characterized by the dry sensation drinkers get in their mouth when they drink wine.

This from Aarhus University:

Quite specifically, the sensor is a small plate coated with nanoscale gold particles. On this plate, the researchers simulate what happens in your mouth by first adding some of the proteins contained in your saliva. After this they add the wine. The gold particles on the plate act as nano-optics and make it possible to focus a beam of light below the diffraction limit so as to precisely measure something that is very small – right down to 20 nanometres. This makes it possible to study and follow the proteins, and to see what effect the wine has. It is thereby possible to see the extent to which the small molecules have to bind together for the clumping effect on the protein to be set off.

Read the full article here.

While the technique itself is not new, the ingenuity lies in using it to create a sensor that can measure an effect rather than just the number of molecules.

This technology seems as though it would threaten the livelihood of sommeliers, but researchers say that is not what the sensor is intended for. Instead, the team at Aarhus University hopes that this will produce a tool that is useful in wine production.

Want to see what else sensors can do? Head over to our Digital Library to see the newest cutting-edge sensor research.

Member Spotlight – Donald R. Sadoway

Donald R. Sadoway

Sadoway’s research seeks to establish the scientific underpinnings for technologies that make efficient use of energy and natural resources in an environmentally sound matter.
Credit: MIT

Donald R. Sadoway – a prominent member of The Electrochemical Society and electrochemist at the Massachusetts Institute of Technology in Cambridge – has led a team of researchers at MIT to improve a proposed liquid battery system that could help make sources of renewable energy more viable and prove to be a competitor for conventional power plants.

This from MIT News:

Sadoway, the John F. Elliott Professor of Materials Chemistry, says the new formula allows the battery to work at a temperature more than 200 degrees Celsius lower than the previous formulation. In addition to the lower operating temperature, which should simplify the battery’s design and extend its working life, the new formulation will be less expensive to make, he says.

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The battle to produce the most efficient and environmentally friendly car rages on, and now a new company is rising in the ranks by proposing we power our cars with salt water.

The Quant e-Sportlimousine made its debut at the 2014 Geneva Motor Show and showcased its innovative NanoFlowcell technology. This new technology sets itself apart from other systems in its ability to store and release electrical energy at very high densities – all with the help of salt water.

This from Intelligent Living:

The flow cell system powering the Quant e-Sportlimousine’s four electric motors develops electricity from the electrochemical reaction created by two electrolyte solutions. This electricity is forwarded to super capacitors where it’s stored and distributed.

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Did You Get Our Postcard?

ECS Cancun e-postcard front ECS Cancun e-postcard backDidn’t get our postcard? (Click to see it big.) Don’t be hurt. We do want to see you in Cancun. Find out more about our fall meeting!

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A Revolution in Renewable Energy

Towering like a beacon of hope in Germany’s North Sea stand wind turbines. Stretching as high as 60-story buildings and standing as far as 60 miles from the mainland, the turbines are part of Germany’s push to find a solution to global warming.

Some call it change. Some call it transformation. We call it a revolution.

According to an article in the The New York Times, it is expected that by the end of the year, scores of new turbines will be set in place – thus allowing low-emission electricity to be sent to German cities hundreds of miles south.

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23 Reasons You Should be in Cancun

Watch the video and hear at least 23 reasons for coming to the meeting! (Yes, I counted.)

Register now for the 2014 ECS and SMEQ (Sociedad Mexicana de Electroquímica) Joint International Meeting to be held October 5-9, 2014.

This major international conference offers a unique blend of electrochemical and solid-state science and technology; and serves as a major forum for the discussion of interdisciplinary research from around the world through a variety of formats, such as oral presentations (51 symposia and 2,299 papers being presented), poster sessions, exhibits, and tutorial sessions.

ECS is partnering with the Bill & Melinda Gates Foundation to host a multi-day workshop at the 2014 International Electrochemical Energy Summit (E2S) which takes place during the meeting. The workshop will culminate in the distribution of over $200,000 in seed funding from ECS, addressing critical technology gaps in water, sanitation, and hygiene challenges being faced around the world.

Find out more and register online now.

It’s at the beautiful, all-inclusive Moon Palace Resort Hotel, located on the best beach in Cancun and just minutes from the Cancun Airport.

Daily room rates include all of the following:

  • Unlimited meals, snacks, and beverages (including all alcoholic beverages), in twelve onsite restaurants featuring varied cuisine, including Italian, Asian, Mexican, Brazilian, and Continental;
  • Mini bar in room;
  • All gratuities (restaurants, lounges, poolside, bellmen, and housekeeping) and hospitality tax;
  • Water-sport facilities with non-motorized equipment such as sailboats, kayaks, and paddle boats at Moon Palace Marina;
  • Complimentary tennis, bicycling, miniature golf, and use of the health club;
  • Jacuzzi in every room; and
  • Wireless Internet access from your laptop!

Sign up now!

Posted in Uncategorized

A Light Show on Four Wheels

Because it does not require heat to produce light, EL is safe, efficient, and long lasting.Credit: Darkside Scientific

Because it does not require heat to produce light, EL is safe, efficient, and long lasting.
Credit: Darkside Scientific

Imagine being able to paint light on an object. With Darkside Scientific’s patented technology known as LumiLor, the company is now able to turn light into paint.

Recently, the company released a video of a car treated with LumiLor, which showcases the patented technology in all its luminescent glory.

The process is made possible through electroluminescent (EL) coating technologies, which is a characteristic of material that enables it to emit light in response to an electrical field.

The from Darkside Scientific:

At the sub-atomic level, the process behind electroluminescence is radiative recombination, also known as spontaneous emission. In radiative recombination, phosphorescent substances emit photons (light particles) in response to alternating electrical current.

Read the full article here.

For more information on electroluminescent technologies, check out the wealth of information on the topic in ECS’s Digital Library.

Climate Case for Open Access

This weekend I watched the recently released short film, Disruption, which is available online for free viewing. In less than one-hour, the scientists, authors and activists featured in the film highlight some truly frightening data and trends. As those who believe in the vast majority of the science already understand, we must do more to limit greenhouse gas emissions if we want any chance of keeping global temperature change below 2°C relative to pre-industrial levels.

Thankfully, the conversion to a clean energy economy is already feasible, both economically and technologically. Countries like Germany have been demonstrating the possibilities of renewable energy, despite having sunshine similar to that of Alaska. We also know the scientists of ECS are currently working on even more exciting research to improve our understanding and technological capabilities in photovoltaics, nanotechnology and fuel cells, among other cutting-edge fields.

In my view, the bold pledge to move toward open access at ECS has serious implications for action on climate change. If we can make the scientific research results and latest findings more widely accessible, we may speed up the scientific discovery process. Perhaps a young scientist in the developing world will unlock the key to some perplexing scientific dilemma, once we’ve made the latest findings more freely available in an ECS journal. Many of us believe we can accelerate the pace of innovation, and help solve critical challenges by opening access to scientific research. You can support those efforts by donating to the ECS Publications Endowment.

PeoplesClimate.orgIn the meantime, I plan to attend the Peoples Climate March on Sunday, September 21. There is an entire staging area for scientists, among the various  1,500 other groups, including students, environmentalists, labor unions, and community activists. Together, we’ll be demanding action on climate change, just two days before President Obama and other world leaders are set to attend a Climate Summit at the United Nations hosted by Secretary General Ban Ki-moon.

The National Institutes of Health is challenging science innovators to compete for prizes totaling up to $500,000, by developing new ways to track the health status of a single cell in complex tissue over time.

The National Institutes of Health is challenging science innovators to compete for prizes totaling up to $500,000, by developing new ways to track the health status of a single cell in complex tissue over time.

The National Institutes of Health (NIH) recently announced an exciting new challenge through the InnoCentive Platform that will award a total of $500,000 to creative minds that are interested in solving some of the world’s most important problems.

The Single Cell Analysis Program (SCAP) Challenge is aimed to spur the development of innovative solutions in single cell analysis. Through advances in cellular analysis, NIH hopes to develop tools that would monitor a cell in the process of becoming cancerous, detect changes due to disease-causing virus, or track how a cell responds to treatment.

The challenge’s goal is to generate creative ideas and methods for following and predicting a single cell’s behavior – in essence, allowing one to “Follow that Cell.”

This from the National Institutes of Health:

Many biological experiments are performed under the assumption that all cells of a particular “type” are identical. However, recent data suggest that individual cells within a single population may differ quite significantly and these differences can drive the health and function of the entire cell population. Single cell analysis comprises a broad field that covers advanced optical, electrochemical, mass spectrometry instrumentation, and sensor technology, as well as separation and sequencing techniques.

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