Toggle light / dark theme

Living Planet Symposium opens in Vienna

ESA’s Living Planet Symposium, one of the world’s leading Earth observation conferences, opened today in Vienna.

More than 6,500 participants from almost 120 countries signed up to attend the event. With more than 4,200 scientific presentations and posters, the symposium provides a forum and meeting point for scientists, academics and space industry representatives, as well as students and citizens.

The event takes place every three years and this year the focus is ‘from observation to climate action and sustainability for Earth’

New passivation strategy improves scalability and efficiency of perovskite solar cells

Solar cells, devices that can convert sunlight into electrical energy, are becoming increasingly widespread, with many households and industries worldwide now relying on them as a source of electricity. While crystalline silicon-based photovoltaics and other widely available solar cells perform relatively well, manufacturing them can be expensive, and they do not perform well in low-light or other unfavorable conditions.

Enzyme-based plastics recycling at an industrial scale could be cost-effective, analysis finds

A successful collaboration involving a trio of research institutions has yielded a roadmap toward an economically viable process for using enzymes to recycle plastics.

The researchers, from the National Renewable Energy Laboratory (NREL), the University of Massachusetts Lowell, and the University of Portsmouth in England, previously partnered on the of improved PETase enzymes that can break down polyethylene terephthalate (PET). With its low manufacturing cost and excellent material properties, PET is used extensively in single-use packaging, soda bottles, and textiles.

The new study, published in Nature Chemical Engineering, combines previous fundamental research with advanced chemical engineering, process development, and techno-economic analysis to lay the blueprints for enzyme-based PET recycling at an industrial scale.

Two-step system makes plastic from carbon dioxide, water and electricity

What if a machine could suck up carbon dioxide from the atmosphere, run it through a series of chemical reactions, and essentially spit out industrially useful plastic?

“I think that is something that we, as a society, would be interested in. After all, in addition to being a , carbon dioxide is an abundant and inexpensive feedstock,” says Theo Agapie, Ph.D., the John Stauffer Professor of Chemistry and the executive officer for chemistry at Caltech. “With our new work, we have taken a significant step in that direction.”

Reporting in the journal Angewandte Chemie International Edition, Agapie and a team of Caltech chemists have developed a system that uses electricity from sustainable sources to carry out the chemical conversion of carbon dioxide (CO2) into molecules, such as ethylene and , that are useful for making more complex compounds.

Modified perovskite solar cells harvest energy from indoor fluorescent lighting

When you think of solar panels, you usually picture giant cells mounted to face the sun. But what if “solar” cells could be charged using fluorescent lights?

Perovskite solar cells (PeSCs) have emerged as a lower-cost, higher-efficiency alternative to traditional silicon solar cells due to their material structure and physical flexibility. Their large power conversion efficiency rate (PCE), which is the amount of energy created from the amount of energy hitting the cell, makes PeSCs well suited to converting lower light sources into energy.

In APL Energy, researchers from National Yang Ming Chiao Tung University in Taiwan created that effectively convert indoor lighting into .

Sustainable cooling film could slash building energy use by 20% amid rising global temperatures

An international team of scientists has developed a biodegradable material that could slash global energy consumption without using any electricity, according to a new study published today.

The bioplastic metafilm—that can be applied to buildings, equipment and other surfaces—passively cools temperatures by as much as 9.2°C during peak sunlight and reflects almost 99% of the sun’s rays.

Developed by researchers from Zhengzhou University in China and the University of South Australia (UniSA), the new film is a sustainable and long-lasting material that could reduce building energy consumption by up to 20% a year in some of the world’s hottest cities.

Scientists develop stable all-perovskite tandem solar cells

A research group led by Prof. Ge Ziyi from the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences has developed an innovative strategy to alleviate NiOx corrosion, enabling more efficient and stable all-perovskite tandem solar cells (TSCs).