Upcycling has become a huge trend in recent years. People are reusing and repurposing items that most wouldn’t give a second glance, transforming them into completely new, high-quality products. So what if we could take that same concept and apply it to the greenhouse gas emissions in the environment that are accelerating climate change?

An interdisciplinary team from UCLA is taking a shot at upcycling carbon dioxide by converting it into a new building material named CO2NCRETE, which could be fabricated by 3D printers.

“What this technology does is take something that we have viewed as a nuisance – carbon dioxide that’s emitted from smokestacks – and turn it into something valuable,” says J.R. DeShazo, senior member of the research team.

The fact that the team is attempting to produce a concrete-like material is also important. Currently, the extraction and preparation of building materials like concrete is responsible for 5 percent of the world’s greenhouse gas emissions. The upcycling of carbon could cut that number drastically all while reducing the enormous emissions being released from power plants (30 percent of the world’s emissions).

“We can demonstrate a process where we take lime and combine it with carbon dioxide to produce a cement-like material,” says Gaurav Sant, lead scientific contributor. “The big challenge we foresee with this is we’re not just trying to develop a building material. We’re trying to develop a process solution, an integrated technology which goes right from CO2 to a finished product.”

When the loaves in your breadbox begin to develop a moldy exterior caused by fungi, they tend to find a new home at the bottom of a trash can. However, researchers have recently developed some pretty interesting results that suggest bread mold could be the key to producing more sustainable electrochemical materials for use in rechargeable batteries.

For the first time, researchers were able to show that the fungus Neurospora crassa (better known as the enemy to bread) can transform manganese into mineral composites with promising electrochemical properties.

(MORE: Read the full paper.)

“We have made electrochemically active materials using a fungal manganese biomineralization process,” says Geoffrey Gadd of the University of Dundee in Scotland. “The electrochemical properties of the carbonized fungal biomass-mineral composite were tested in a supercapacitor and a lithium-ion battery, and it [the composite] was found to have excellent electrochemical properties. This system therefore suggests a novel biotechnological method for the preparation of sustainable electrochemical materials.”

This from University of Dundee:

In the new study, Gadd and his colleagues incubated N. crassa in media amended with urea and manganese chloride (MnCl2) and watched what happened. The researchers found that the long branching fungal filaments (or hyphae) became biomineralized and/or enveloped by minerals in various formations. After heat treatment, they were left with a mixture of carbonized biomass and manganese oxides. Further study of those structures show that they have ideal electrochemical properties for use in supercapacitors or lithium-ion batteries.

Read the full article here.

The manganese oxides in the lithium-ion batteries are showing an excellent cycling stability and more than 90 percent capacity after 200 cycles.

Graphene is at it again, outperforming all known materials (including superconductors) in a recent study testing the transmission of high frequency electrical signals.

The researchers found that when the electrical signals pass through graphene, none of the energy is lost – opening the door to a new realm of electrical transmission.

This from the University of Plymouth:

And since graphene lacks band-gap, which allows electrical signals to be switched on and off using silicon in digital electronics, academics say it seems most applicable for applications ranging from next generation high-speed transistors and amplifiers for mobile phones and satellite communications to ultra-sensitive biological sensors.

Read the full article.

“An accurate understanding of the electromagnetic properties of graphene over a broad range of frequencies (from direct current to over 10 GHz) has been an important quest for several groups around the world,” said Shakil Awan, leader of the study. “Initial measurements gave conflicting results with theory because graphene’s intrinsic properties are often masked by much larger interfering signals from the supporting substrate, metallic contacts and measurement probes. Our results for the first time not only confirm the theoretical properties of graphene but also open up many new applications of the material in high-speed electronics and bio-sensing.”

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An interdisciplinary team, including 32 year ECS member Stuart Licht and ECS student member Matthew Lefler, has developed a way to make electric vehicles that are not only carbon neutral, but carbon negative – capable of reducing the amount of atmospheric carbon dioxide as they operate by transforming the greenhouse gas.

By replacing the graphite electrodes that are currently being used in the development of lithium-ion batteries for electric cars with carbon materials recovered from the atmosphere, the researchers have been able to develop a recipe for converting collected carbon dioxide into batteries.

This from Vanderbilt University:

The team adapted a solar-powered process that converts carbon dioxide into carbon so that it produces carbon nanotubes and demonstrated that the nanotubes can be incorporated into both lithium-ion batteries like those used in electric vehicles and electronic devices and low-cost sodium-ion batteries under development for large-scale applications, such as the electric grid.

Read the full article.

The research is not the first time scientists have shown progress in collecting and converting harmful greenhouse gases from the environment.

Typically, carbon dioxide conversion revolves around transforming the gas into low-value fuels such as methanol. These conversions often do not justify the costs.

(MORE: Read “Carbon Nanotubes Produced from Ambient Carbon Dioxide for Environmentally Sustainable Lithium-Ion and Sodium-Ion Battery Anodes.“)

However, the new process produces better batteries that are not only expected to be efficient, but also cost effective.

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Looking to save on electricity? Why not use bioluminescent bacteria to light the way?

Innovative start-up Glowee is looking to do just that to illuminate the streets of Paris. By using bacteria found in squid, Glowee is producing lights that consist of transparent gases filled with a gel containing the bioluminescent bacteria alongside the sugars and oxygen they need to survive.

The bio-lights will allow cities to cut back on energy and avoid light pollution. With lower electricity consumption comes considerably less carbon dioxide emissions.

Currently, the company is looking to increase lifespan and efficiency before implementing the technology.

MIT researcher have developed the first steps to creating the thinnest, lightest solar cell ever made.

Through a unique fabrication method, the researchers are moving toward the development of a solar cell so thin it could blow away. Instead of a solar cell’s typical makeup, the MIT researchers have opted for a unique fabrication of creating each layer at the same time.

This from Popular Science:

Solar cells are typically made up of layers of photovoltaic materials and a substrate, such as glass or plastic. Instead of the usual method of fabricating each layer separately, and then depositing the layers onto the substrate, the MIT researchers made all three parts of their solar cell (the cell, the supportive substrate, and the protective coating) at the same time, a method that cuts down on performance-harming contaminants. In the demonstration, the substrate and coating are made from parylene, which is a flexible polymer, and the component that absorbs light was made from dibutyl phthalate (DBP). The researchers note that the solar cell could be made from a number of material combinations, including perovskite, and it could be added to a variety of surfaces such as fabric or paper.

Read the full article.

To put the thinness of the solar cell in perspective, it is approximately 1/50th the thickness of a strand of hair. The light weight means that its power-to-weight ratio is particularly high, with an efficiency output of about 6 watts per gram (400 times higher than silicon-based solar cells).

The final trial for the researcher will be to translate the lab work to the real world, making it scalable and practical for commercial use.

Researchers have found a way to use rust to build a solar-powered battery.Image: Flickr

Researchers have found a way to use rust to build a solar-powered battery.
Image: Diego Torres Silvestre

What happens when corrosion meets energy? For researchers at Stanford University, the marriage of those two uniquely electrochemical topics could yield an answer to large-scale solar power storage.

The question of how to store solar power when the sun goes down has been on the forefront of scientific discussion. While electrochemical energy storage devices exist, they are typically either too expensive to work on a large-scale or not efficient enough.

Building a solar-powered battery

New research shows that metal oxides, such as rust, can be fashioned into solar cells capable of splitting water into hydrogen and oxygen. The research could be looked at revelatory, especially when considering large-scale storage solutions, because of its novel heat attributes.

While we knew the promising solar power potential of metal oxides before, we believed that the efficiency of cells crafted from these materials would be very low. The new study, however, disproves that theory.

The team showed that as the cells grow hotter, efficiency levels increase. This is a huge benefit when it comes to large-scale, solar energy conversion and it the polar opposite of the traditional silicon solar cell.

“We’ve shown that inexpensive, abundant, and readily processed metal oxides could become better producers of electricity than was previously supposed,” says William Chueh, an assistant professor of materials science and engineering.

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Globally, carbon dioxide is the number one contributor to harmful greenhouse gas emissions. These emissions accelerate climate change, leading to such devastating effects as rising sea levels that can dislocate families and radical local climates that hurt food production levels.

But what if we could turn those harmful emissions into useable fuels through a simple, one-step process?

Researchers have proven that through a process combining concentrated light, heat, and high pressure, carbon dioxide and water could be directly converted into usable liquid hydrocarbon fuels.

Not only would this effort offer some relief in the energy infrastructure, it would also aid efforts against climate change by removing carbon dioxide from the atmosphere.

“Our process also has an important advantage over battery or gaseous-hydrogen powered vehicle technologies as many of the hydrocarbon products from our reaction are exactly what we use in cars, trucks and planes, so there would be no need to change the current fuel distribution system,“ said Frederick MacDonnell, co-principal investigator of the project.

The corresponding paper was published in the Proceedings of the National Academy of Sciences.

“We are the first to use both light and heat to synthesize liquid hydrocarbons in a single stage reactor from carbon dioxide and water,” said Brian Dennis, co-principal investigator of the project. “Concentrated light drives the photochemical reaction, which generates high-energy intermediates and heat to drive thermochemical carbon-chain-forming reactions, thus producing hydrocarbons in a single-step process.”

Bill & Melinda Gates FoundationThe Bill & Melinda Gates Foundation has been fighting the good fight on many fronts over the years, including poverty, women’s equality, and of course, energy.

In their 2016 annual letter, the private foundation looked at the issue of access to energy. According to Bill Gates, 1.3 billion people – or 18 percent of the world’s population – live without electricity to light their homes.

Energy crisis

Many energy trouble areas exist in sub-Saharan Africa, where 7 out of 10 people live in the dark. The same problems exist in parts of Asia and India where more than 300 million people lack access to electricity.

(MORE: Take a look at the work that ECS has done with the Gates Foundation to tackle critical issues in water and sanitation.)

There are still many parts of the world that have yet to reap the benefits of Thomas Edison’s incandescent light bulb.

But it’s not just about light. Energy allows better medical care through functioning hospitals, greater educational efforts through functioning schools, and even more food through the powering of agricultural devices.

Renewable energy revolution

Not only is the provision of energy to all people essential, but the research into finding a clean, efficient way to do so is also crucial. ECS members and scientists across the globe are currently making effort to combat climate change, which is consequentially poised to hit the world’s poor the hardest.

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Nuclear PosterThe U.S. Department of Energy recently released a new series of posters illuminating a new generation of sustainable energy and green jobs. The series is reminiscent of the famous imagery created for the Works Progress Administration, only this time, the images depict a renewable energy revolution.

The posters accompany a report on the energy accomplishments from the American Recovery and Reinvestment Act, which was signed into law seven years ago by President Obama.

(MORE: See all the the posters from the department of energy.)

The newly established law created the Section 1705 Loan Guarantee Program, which worked to spur economic growth while creating new jobs and saving existing ones.

Some of the key accomplishments of the act include the creating of 10,000 jobs in the energy industry, $16.1 billion in loans for renewable energy projects, and a newly developed infrastructure that can power an additional one million American homes annually.

The Recovery Act also launched utility-grade photovoltaic solar plants in the U.S. Prior to signing the act into law in 2009, there weren’t any plants larger than 100 megawatts in the country. Now, five major plants are producing significant amounts of energy and 28 more are scheduled for the future.

Overall, the posters remind citizens of the positive accomplishments that can be achieved when government and science work together as well as give us all a visual image of an optimistic view of a renewable future.