New type of solar cell is being tested in space

Magnus Borgström Professor, Solid State Physics Lund University
Photo Credit: Lund University

Physics researchers at Lund University in Sweden recently succeeded in constructing small solar radiation-collecting antennas – nanowires – using three different materials that are a better match for the solar spectrum compared with today’s silicon solar cells. As the nanowires are light and require little material per unit of area, they are now to be installed for tests on satellites, which are powered by solar cells and where efficiency, in combination with low weight, is the most important factor. The new solar cells were sent into space a few days ago.

A group of nanoengineering researchers at Lund University working on solar cells made a breakthrough last year when they succeeded in building photovoltaic nanowires with three different band gaps. This, in other words, means that one and the same nanowire consists of three different materials that react to different parts of solar light. The results have been published in Materials Today Energy and subsequently in more detail in Nano Research.

“The big challenge was to get the current to transfer between the materials. It took more than ten years, but it worked in the end,” says Magnus Borgström, professor of solid-state physics, who wrote the articles with the then doctoral student Lukas Hrachowina.

Earth likely to cross critical climate thresholds even if emissions decline

Already, the world is 1.1 degrees Celsius hotter on average than it was before fossil fuel combustion took off in the 1800s. More extreme rainfall and flooding are among the litany of impacts from that warming.
Photo Credit: Chris Gallagher

Artificial intelligence provides new evidence our planet will cross the global warming threshold of 1.5 degrees Celsius within 10 to 15 years. Even with low emissions, we could see 2 C of warming. But a future with less warming remains within reach.

A new study has found that emission goals designed to achieve the world’s most ambitious climate target – 1.5 degrees Celsius above pre-industrial levels – may in fact be required to avoid more extreme climate change of 2 degrees Celsius.

The study, published Jan. 30 in Proceedings of the National Academy of Sciences, provides new evidence that global warming is on track to reach 1.5 degrees Celsius (2.7 Fahrenheit) above pre-industrial averages in the early 2030s, regardless of how much greenhouse gas emissions rise or fall in the coming decade.

The new “time to threshold” estimate results from an analysis that employs artificial intelligence to predict climate change using recent temperature observations from around the world.

Marburg vaccine shows promising results in first-in-human study

Colorized scanning electron micrograph of Marburg virus particles (blue) both budding and attached to the surface of infected VERO E6 cells (orange).
Image Credit: National Institute of Allergy and Infectious Diseases

A newly published paper in The Lancet shows that an experimental vaccine against Marburg virus (MARV) was safe and induced an immune response in a small, first-in-human clinical trial. The vaccine, developed by researchers at the National Institute of Allergy and Infectious Diseases (NIAID), part of the National Institutes of Health, could someday be an important tool to respond to Marburg virus outbreaks.

This first-in-human, Phase 1 study tested an experimental MARV vaccine candidate, known as cAd3-Marburg, which was developed at NIAID’s Vaccine Research Center (VRC). This vaccine uses a modified chimpanzee adenovirus called cAd3, which can no longer replicate or infect cells, and displays a glycoprotein found on the surface of MARV to induce immune responses against the virus. The cAd3 vaccine platform demonstrated a good safety profile in prior clinical trials when used in investigational Ebola virus and Sudan virus vaccines developed by the VRC.

Mating causes ‘jet lag’ in female fruit flies, changing behavior

A seminal fluid protein transferred from male to female fruit flies during mating changes the expression of genes related to the fly’s circadian clock, Cornell research has found.
Photo Credit: Erik Karits

A seminal fluid protein transferred from male to female fruit flies during mating changes the expression of genes related to the fly’s circadian clock, an innovative technique has revealed.

The finding, published in the Proceedings of the National Academy of Sciences, could help explain how this protein, called sex peptide, alters the female’s behavior.

Post-mating, sex peptide has been shown to elicit increased egg-laying, aggression, activity and feeding, while reducing sleep and interest in mating in previously unmated females.

“Flies like to eat at certain times of day,” said Mariana Wolfner ’74, professor of molecular biology and genetics and a Stephen H. Weiss Presidential Fellow in the College of Arts and Sciences, and one of the paper’s senior authors. “They sleep at certain times, and the circadian clock machinery controls when flies are likely to do these things.

Climate Change May Cut U.S. Forest Inventory by a Fifth This Century

Mountain forests.
Photo Credit  Alek Kalinowsk

A study led by a North Carolina State University researcher found that under more severe climate warming scenarios, the inventory of trees used for timber in the continental United States could decline by as much as 23% by 2100. The largest inventory losses would occur in two of the leading timber regions in the U.S., which are both in the South.

Researchers say their findings show modest impacts on forest product prices through the end of the century, but suggest bigger impacts in terms of storing carbon in U.S. forests. Two-thirds of U.S. forests are classified as timberlands.

“We already see some inventory decline at baseline in our analysis, but relative to that, you could lose, additionally, as much as 23% of the U.S. forest inventory,” said the study’s lead author Justin Baker, associate professor of forestry and environmental resources at North Carolina State University. “That’s a pretty dramatic change in standing forests.”

Boeing Awarded U.S. Air Force Contract for 15 KC-46A Tankers

KC-46A Pegasus tanker
Photo Credit: Boeing

The U.S. Air Force has awarded Boeing a $2.3 billion contract for the ninth production lot of 15 KC-46A Pegasus tanker aircraft, expanding its fleet of the world’s most advanced multi-mission aerial refueler. To date, 128 KC-46A Pegasus are on contract with the U.S. Air Force, with 68 delivered and operationally deployed worldwide.

“The combat-ready KC-46A is transforming the role of the tanker for the 21st century,” said James Burgess, vice president and KC-46 program manager. “We’re proud to work side-by-side with the Air Force ensuring the Pegasus provides unmatched capabilities and continues to evolve for the U.S. and its allies’ global mission needs.”

The KC-46A Pegasus delivers crucial fuel and data for the fleet, as well as cargo, personnel and aeromedical transportation for joint force rapid mobility, global reach and agile combat employment.

Researchers can ‘see’ crystals perform their dance moves

Wenbin Li (left) and Aditya Mohite.
Photo Credit: Jeff Fitlow/Rice University

Rice University researchers already knew the atoms in perovskites react favorably to light. Now they can see precisely how those atoms move.

A breakthrough in visualization supports their efforts to squeeze every possible drop of utility out of perovskite-based materials, including solar cells, a long-standing project that only recently yielded an advance to make the devices far more durable.

A study published in Nature Physics details the first direct measurement of structural dynamics under light-induced excitation in 2D perovskites. Perovskites are layered materials that have well-ordered crystal lattices. They are highly efficient harvesters of light that are being explored for use as solar cells, photodetectors, photocatalysts, light-emitting diodes, quantum emitters and more.

“The next frontier in light-to-energy conversion devices is harvesting hot carriers,” said Rice University’s Aditya Mohite, a corresponding author of the study. “Studies have shown that hot carriers in perovskite can live up to 10-100 times longer than in classical semiconductors. However, the mechanisms and design principles for the energy transfer and how they interact with the lattice are not understood.”

RUDN University Chemists Create Substances for Supramolecules Self-assembly

Illustration Credit: RUDN University

RUDN University chemists derived molecules that can assemble into complex structures using chlorine and bromine halogen atoms. They bind to each other as “Velcro” — chlorine “sticks” to bromine, and vice versa. As a result, supramolecules are assembled from individual molecules. The obtained substances will help to create supramolecules with catalytic, luminescent, conducting properties.

Supramolecules are the structures made of several molecules. Individual molecules are combined, for example, by self-assembly or without external control. The resulting structure has properties that the molecules did not have individually. That is the way to create new materials, catalysts, molecular machines for drug delivery, conductors, and so on. To get a material with the specified properties, you need to choose the right starting molecules and auxiliary substances that will ensure their unification. One of the ways to control self-assembly is halogen-halogen interactions. These are the chemical bonds forming between two halogens (for example, chlorine, fluorine, bromine). RUDN University chemists have created a molecule with a halogen bond that can form supramolecules by itself or provide the required self-assembly with other substances. They will help to create substances for the chemical industry, medicine, and electronics.

Researchers revisit potent drug as promising treatment for acute leukemia

Photo Credit: Louis Reed

The two-pronged attack of a “forgotten drug” simultaneously targets two cancer-causing pathways of leukemia to stop the disease in its tracks

A team of researchers from the Cancer Science Institute of Singapore (CSI Singapore) at the National University of Singapore, led by Associate Professor Takaomi Sanda and Dr Lim Fang Qi, has breathed new life into an existing drug — combatting a type of blood cancer called T-cell acute lymphoblastic leukemia, or T-ALL.

The drug, called PIK-75, was initially discovered over a decade ago but was dismissed in favor of newer ones. Now, it has made a comeback that deems it unmissable — the researchers established that the drug could block not just one but two crucial cancer-causing pathways of T-ALL, enabling them to develop new treatments that could effectively stem the disease.

The increase of fungal infection

A strain of Candida auris cultured in a petri dish at a CDC laboratory.
Photo Credit: Shawn Lockhart / Centers for Disease Control / Public Domain

Late last year the WHO published a report highlighting the first-ever list of fungal "priority pathogens" – a catalogue of the 19 fungi that represent the greatest threat to public health. The premise behind the publication is both because fungi are a significant and increasing threat to public health and because there is little global R&D into fungi or their treatment.

According to Professor Ana Traven, from the Biomedicine Discovery Institute, fungi can range from the benign (skin and nail infections and vaginal thrush) to the deadly (Candida, Aspergillus), “and they have been largely ignored because deadly fungal infections predominantly target people who are immunosuppressed, they are generally not transmitted in human-to-human contact.”