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Category: chemistry – Page 226

Breakthrough in Lithium-air Batteries Could Help Put More Electric Vehicles On The Road

Year 2021 face_with_colon_three

Illinois Institute of Technology Assistant Professor of Chemical Engineering Mohammad Asadi has developed solutions to two major problems facing lithium-air batteries. Lithium-air batteries hold more energy in a smaller battery size than their more common counterpart, the lithium-ion battery, but until now, lithium-air batteries have been overlooked in commercial applications because lithium-air batteries tended to die after fewer recharges and require a lot more energy to charge than can be generated by the battery later.

After almost a decade working in the oil and gas industry, Asadi turned his focus to carbon dioxide in the atmosphere, particularly caused by the transportation industry, which consumes around 38 to 40 percent of the world’s energy. “With more widespread use of electric vehicles, you can drastically reduce transportation-based carbon emissions,” says Asadi. “But to put more electric vehicles on the road, we’ll need batteries—lots of them.”

Currently, lithium-air batteries are seen as less commercially viable than their counterpart, the lithium-ion battery. However, using lithium-air batteries in electric vehicles has some huge advantages.

Scientists Come Up With a Platform For Nanomagnet and Magnetic Nanostructure Chemical Design

A research team from the University of Valencia’s ICMool (Institute of Molecular Science) came up with a platform that is open, interactive, and capable of bringing together and offering around 20,000 different data. Such data is connected to molecular nanomagnet chemical design in the specific area of magnetic memories.

SIMDAVIS Platform

According to Nanowerk, such a device is called SIMDAVIS. The application results from manual research tracking efforts released by the scientific community for more than 16 years.

Breakthrough Material Separates Heavy Water From Normal Water at Room Temperature

A flipping action in a porous material facilitates the passage of normal water to separate it out from heavy water.

A research group led by Susumu Kitagawa of Kyoto University’s Institute for Cell-Material Sciences (iCeMS), Japan and Cheng Gu of South China University of Technology, China have made a material that can effectively separate heavy water from normal water at room temperature. Until now, this process has been very difficult and energy intensive. The findings have implications for industrial – and even biological – processes that involve using different forms of the same molecule. The scientists reported their results in the journal Nature.

Isotopologues are molecules that have the same chemical formula and whose atoms bond in similar arrangements, but at least one of their atoms has a different number of neutrons than the parent molecule. For example, a water molecule (H2O) is formed of one oxygen and two hydrogen atoms. The nucleus of each of the hydrogen atoms contains one proton and no neutrons. In heavy water (D2O), on the other hand, the deuterium (D) atoms are hydrogen isotopes with nuclei containing one proton and one neutron. Heavy water has applications in nuclear reactors, medical imaging, and in biological investigations.

US startup wants to inject sulfur into the atmosphere to cool down the Earth

In theory, it could mitigate the effects of global warming; but experts are wary.

Make Sunsets, a California-based startup, released weather balloons that carried sulfur particles into the stratosphere which possibly burst there, releasing the chemical, MIT Technology Review.

Da-kuk/iStock.

Founded by Luke Iseman, previous director of hardware at Y Combinator, the attempts by the startup fall into the controversial area of solar geoengineering where particles are released into the atmosphere with an aim to reflect sunlight back into space to ease global warming. The field has largely been a thought experiment with no real consensus if the technology can help us fight climate change.

Exploring a new glass micro-drilling method using a femtosecond laser in GHz-burst mode

The research group of laser-matter interaction at the Institute of Intense Lasers and Applications (CELIA) at the University of Bordeaux, France, has explored a new glass micro-drilling method using a femtosecond laser in GHz-burst mode.

Publishing in the journal International Journal of Extreme Manufacturing, the research team used a femtosecond laser from Amplitude operating in the GHz-burst regime to study a new glass micromachining method which allows for drilling taper-free, elongated holes with smooth inner walls without any cracks in the glass. Usually, laser drilling with standard single femtosecond pulses results in tapered holes of strongly limited length and rough inner surface.

This new laser-matter interaction regime makes it possible to directly drill holes of high aspect ratio in one single step without any chemical etching. The choice of the -burst parameters was revealed to be very important in order to achieve an outstanding micromachining quality of the machined structures. The GHz-burst mode could pave the way for new applications such as microelectronics where silicon interposers are likely to be replaced by glass interposers.

Why We are Alone in the Galaxy | Marc Defant | TEDxUSF

NOTE FROM TED: We’ve flagged this talk, which was filmed at a TEDx event, because it appears to fall outside TEDx’s curatorial guidelines. The sweeping claims and assertions made in this talk are based on the speaker’s own theory and lack legitimate scientific support. TEDx events are independently organized by volunteers. The guidelines we give TEDx organizers are described in more detail here: http://storage.ted.com/tedx/manuals/tedx_content_guidelines.pdf.

The origin of intelligent life on earth requires a host of statistically improbable events which may imply that similar intelligent life elsewhere is extremely unlikely, a fact mostly ignored in discussions about contacting extraterrestrial life.

“Marc Defant is a professor of geochemistry at USF and studies volcanoes through various funding such as the NSF and National Geographic. He has published research in Nature and other journals and has written a book on the history of the universe, earth and life. He was the keynote speaker at a conference on granitic rocks in China and was one of the first American scientists to work on volcanoes in Kamchatka when it was part of the Soviet Union. He is currently focused on emphasizing the importance of science in society.”

This talk was given at a TEDx event using the TED conference format but independently organized by a local community.

A Startup Has Begun Releasing Chemicals Into the Stratosphere

Recently, a start-up company called Make Sunsets has begun releasing chemicals into the stratosphere as a form of geoengineering that is intended to help climate change. However, many are very hesitant about the startup and the result of what they are doing.

For perspective, geoengineering is when chemical particles are released into the stratosphere to manipulate the weather or climate. The theory is that when sulfur is released into the atmosphere that it mimics a natural process that occurs after volcanoes and that by doing this intentionally, we could ease global warming.

While it isn’t difficult to do this, it is very controversial. The reason for this is that it could potentially have dangerous side effects. Additionally, because some regions could endure worse side effects, it could cause issues across international lines.

In a first! Scientists use artificial DNA to kill cancer cells: Here’s what you need to know

Researchers have found a new way to kill cancer cells by using artificial DNA which could pave the way for a cure for the disease in the future. The existing methods of treating cancer have their limitations, however, scientists believe that RNA and DNA-based drugs could potentially help beat the deadly disease.

The findings published in the Journal of the American Chemical Society, last week, show that the researchers at the University of Tokyo have used the chemically synthesised, hairpin-shaped, cancer-killing DNA to target and kill human cervical cancer and breast cancer-derived cells. The DNA pairs were also used against malignant melanoma cells in mice.

The team of researchers at the University of Tokyo, led by Assistant Professor Kunihiko Morihiro and Professor Akimitsu Okamoto from the Graduate School of Engineering, indicated that they were inspired to move away from conventional anti-cancer drug treatments by using artificial DNA.

Experts Debate the Risks of Made-to-Order DNA

In November 2016, virologist David Evans traveled to Geneva for a meeting of a World Health Organization committee on smallpox research. The deadly virus had been declared eradicated 36 years earlier; the only known live samples of smallpox were in the custody of the United States and Russian governments.

Evans, though, had a striking announcement: Months before the meeting, he and a colleague had created a close relative of smallpox virus, effectively from scratch, at their laboratory in Canada. In a subsequent report, the WHO wrote that the team’s method “did not require exceptional biochemical knowledge or skills, significant funds, or significant time.”

Evans disagrees with that characterization: The process “takes a tremendous amount of technical skill,” he told Undark. But certain technologies did make the experiment easier. In particular, Evans and his colleague were able to simply order long stretches of the virus’s DNA in the mail, from GeneArt, a subsidiary of Thermo Fisher Scientific.

New Research: This Activity Can Reduce the Risk of Metastatic Cancer

Professor Carmit Levy. Credit: Tel Aviv University.

Professor Carmit Levy from the Department of Human Genetics and Biochemistry and Dr. Yftach Gepner from the School of Public Health and the Sylvan Adams Sports Institute at TAU’s Sackler Faculty of Medicine conducted the study. Prof. Levy notes that the new research has resulted in a very important discovery by merging scientific know-how from different schools at TAU, which may help avoid metastatic cancer, Israel’s top cause of death. The study was recently published on the cover of the journal of Cancer Research.

Prof. Levy and Dr. Gepner: “Studies have demonstrated that physical exercise reduces the risk for some types of cancer by up to 35%. This positive effect is similar to the impact of exercise on other conditions, such as heart disease and diabetes. In this study we added new insight, showing that high-intensity aerobic exercise, which derives its energy from sugar, can reduce the risk of metastatic cancer by as much as 72%. If so far the general message to the public has been ‘be active, be healthy’, now we can explain how aerobic activity can maximize the prevention of the most aggressive and metastatic types of cancer.”