“Stella” is the name on every climate-cautious, pollution-loathing environmentalist’s lips.

Who is Stella? Well, she’s a car.

She may not be “pretty” by conventional standards, but Stella is the first family car powered by solar energy. The car – driven by a team of students from Eindhoven University of Technology – has just finished its road trip from Los Angeles to San Francisco, fueled solely by the California sunshine.

While the car is capable of traveling 500 miles (800km) on a single charge and can clock up to 80 miles per hour, there is still one pressing question on everyone’s mind – who will drive it?

“Do you want it in your daily life? Would you want to take it to get groceries?” asked one of Stella’s drivers, Jordy de Renet, in an interview with Popular Science.

The car’s strange shape stems from a compromise for aerodynamics and allowing comfort for at least two people. Also, the wedge-shaped vehicle’s flat surface allows for more solar cell coverage.

This from Popular Science:

Stella is CO2-neutral and the first energy-positive car in the world. The solar array charges while the car is in motion as well as when it is parked. “We get more energy out of the car than is needed to drive it,” said de Renet. That power, as much as twice what the car uses, can be returned to the grid.

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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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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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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 researchers at Virginia Tech have successfully demonstrated the concept of a sugar biobattery that can completely convert the chemical energy in sugar substrates into electricity. Credit: Virginia Tech University

The researchers at Virginia Tech have successfully demonstrated the concept of a sugar biobattery that can completely convert the chemical energy in sugar substrates into electricity.
Credit: Virginia Tech University

According to new studies, the future of energy storage and conversion may be something that’s sitting in your kitchen cupboard.

A new breakthrough out of Virginia Tech demonstrates that a sugar-powered biobattery has the potential to outperform the current lithium-ion batteries on many fronts.

Not only is the energy density of the sugar-powered battery significantly higher than that of the lithium-ion battery, but the sugar battery is also less costly than the li-ion, refillable, environmentally friendly, and nonflammable.

This from LiveScience:

This nature-inspired biobattery is a type of enzymatic fuel cell (EFC) — an electrobiochemical device that converts chemical energy from fuels such as starch and glycogen into electricity. While EFCs operate under the same general principles as traditional fuel cells, they use enzymes instead of noble-metal catalysts to oxidize their fuel. Enzymes allow for the use of more-complex fuels (such as glucose), and these more-complex fuels are what give EFCs their superior energy density.

Read the full article here.

The scientists hope to increase the power density, extend the lifetime, and reduce the cost of electrode materials in order for this energy-dense sugar biobattery to become the technology of the future.

Find the full findings in this issue of Nature Communications.

Learn more about this topic by reading a recently published open access article via ECS’s Digital Library.

Microgrid

Microgrids are small power systems that are able to function independently when storms or other emergencies knock out electricity.
Credit: Center for Sustainable Energy

New York state will be holding a $40 million energy technology competition this fall in order to aid research that will allow local communities to retain power during outages.

This from Associated Press:

Gov. Andrew Cuomo announced the New York Prize competition, which would award funding to companies or utilities that suggest the best ways to create so-called “microgrids.” Microgrids are small power systems that are able to function independently when storms or other emergencies knock out electricity.

The microgrids will allow for hospitals, schools, water plants, and even homes to hold energy when the main electrical grid is not working.

Cuomo is to launch the competition this fall.

If you find this concept interesting and would like to partake in solving some of the most challenging issues in the world today, check out the details on ECS’s 2014 Electrochemical Energy and Water Summit.

Lithium or Magnesium?

LinkedIn chat bubbles

Join the ECS LinkedIn group.

This from our LinkedIn group:

Recently some researchers move to Mg batteries. Pellion Tech in its white paper claims double energy density both in volumetric and gravimetric for Mg batteries.

I am confused since it seems that the discharge voltage should be at least 3V and no cell have been reported working experimentally at such potential yet (Maybe I did not find).

Moreover, the safety issues will not come for Mg batteries with magnesium anodes? and for Mg-ion batteries, the energy density would be competitive with current Li-ion batteries?

Does the main opportunity for Mg batteries lie in their cathodes same as Lithium batteries?

Leave comments here.

Request to join the LinkedIn group today!

Grant opportunity in Cancun

Gates Foundation logo

The goal: to enable universal access to sustainable sanitation services by supporting the development of radically new sanitation technologies as well as markets for new sanitation products and services.

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 ECS and SMEQ Joint International meeting in Cancun, Mexico being held Oct. 5-9, 2014. 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.

40% of the world’s population–2.5 billion people–practice open defecation or lack adequate sanitation facilities, and the consequences can be devastating for human health as well as the environment.

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Pressure Retarded Osmosis (PRO)

Pressure retarded osmosis (PRO) is a method of producing renewable energy from two streams of a different salinity.
Credit: Jose-Luis Olivares/MIT

When the River Meets the Sea” may very well be a John Denver song circa 1979, but it is also an intersection with the potential to generate a significant amount of power. According to a team of mechanical engineers at MIT, when river water collides with sea water, there exists the potential to harness a significant amount of renewable energy.

This from Phys.org:

The researchers evaluated an emerging method of power generation called pressure retarded osmosis (PRO), in which two streams of different salinity are mixed to produce energy. In principle, a PRO system would take in river water and seawater on either side of a semi-permeable membrane. Through osmosis, water from the less-salty stream would cross the membrane to a pre-pressurized saltier side, creating a flow that can be sent through a turbine to recover power.

Read the full article here.

According to calculations by Leonardo Banchik, a graduate student in MIT’s Department of Mechanical Engineering, a PRO system could potentially power a coastal wastewater-treatment plant by taking in seawater and combining it with treated wastewater to produce renewable energy.

Although more research needs to be done to see in what applications the PRO system is economically viable, Banchik sees the huge potential of this method.

“Say we’re in a place that could really use desalinated water, like California, which is going through a terrible drought,” Banchik says. “They’re building a desalination plant that would sit right at the sea, which would take in seawater and give Californians water to drink. It would also produce a saltier brine, which you could mix with wastewater to produce power.”

Learn more about new devlopments in osmosis via ECS’s Digital Library.

Solar Energy Without Blocking the View

Solar Concentrator

The solar harvesting system uses small organic molecules developed by Lunt and his team to absorb specific nonvisible wavelengths of sunlight.
Credit: Yimu Zhao

A team of researchers at Michigan State University has developed a new type of solar concentrator that can harvest energy when placed over a window without blocking the view.

The new development is called the transparent luminescent solar concentrator and it has the potential to be used on buildings, cell phones, and any other device that has a flat, clear surface.

This from Science Daily:

Research in the production of energy from solar cells placed around luminescent plastic-like materials is not new. These past efforts, however, have yielded poor results – the energy production was inefficient and the materials were highly colored.

Read the full article here.

The transparent luminescent solar concentrator is still in the beginning of its development – yielding a solar conversion efficiency just close to one percent. However, Richard Lunt of MSU’s College of Engineering believes the concentrator will reach efficiencies beyond five percent when fully optimized.

“It opens a lot of area to deploy solar energy in a non-intrusive way,” Lunt said. “It can be used on tall buildings with lots of windows or any kind of mobile device that demands high aesthetic quality like a phone or e-reader. Ultimately we want to make solar harvesting surfaces that you do not even know are there.”

ECS will have a symposium at the upcoming meeting in Cancun dealing with solar fuels and the utilization of solar energy. Find out more about the meeting and sign-up for early bird registration today!