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In nature, scents emitted by plants attract animals such as insects. However, scents are also used in the industry, for example in the production of perfumes and aromas. In order to achieve a reliable, quick, and objective discrimination of mint scents in particular, researchers at KIT (Karlsruhe Institute of Technology) embarked on an interdisciplinary collaboration and developed an electronic nose with an artificial sense of smell. This E-nose achieves high precision in recognizing different mint species, which makes it a suitable tool for applications ranging from pharmaceutical quality control to the monitoring of mint oil as an environmentally friendly bioherbicide.

“So far, scientists were able to identify an estimated 100000 different biological compounds through which neighboring plants interact with each other or control other organisms, such as insects,” says Professor Peter Nick from the Botanical Institute of KIT. “These compounds are very similar in plants of the same genus.” A classic example from the plant world is mint, where the different varieties produce with very species-specific scents. Industrial quality control of mint oil, in particular, is subject to strict legal regulations in order to prevent adulteration, is time-consuming, and requires a great deal of expertise, the scientist explains. A new “electronic nose” equipped with sensors made from combined materials will support this process.

In new research, Texas A&M University scientists have for the first time revealed a single microscopic defect called a “twin” in a soft-block copolymer using an advanced electron microscopy technique. This defect may be exploited in the future to create materials with novel acoustic and photonic properties.

“This defect is like a black swan—something special going on that isn’t typical,” said Dr. Edwin Thomas, professor in the Department of Materials Science and Engineering. “Although we chose a certain polymer for our study, I think the twin defect will be fairly universal across a bunch of similar soft matter systems, like oils, surfactants, and natural polymers. Therefore, our findings will be valuable to diverse research across the soft matter field.”

The results of the study are detailed in the Proceedings of the National Academy of Sciences (PNAS).

Dr. Thomas Lovejoy, is an innovative conservation biologist, who is Founder and President of the non-profit Amazon Biodiversity Center, the renowned Biological Dynamics of Forest Fragments Project, and the person who coined the term “biological diversity”.

Dr. Lovejoy currently serves as Professor in the department of Environmental Science and Policy at George Mason University, and as a senior fellow at the United Nations Foundation based in Washington, DC.

Dr. Lovejoy has also served as the World Bank’s chief biodiversity advisor and the lead specialist for environment for Latin America and the Caribbean, the first Biodiversity Chair of the H. John Heinz III Center for Science, Economics and the Environment, President of the Heinz Center, and chair of the Scientific Technical Advisory Panel (STAP) for the Global Environment Facility (GEF), the multibillion-dollar funding mechanism for developing countries in support of their obligations under international environmental conventions.

Spanning the political spectrum, Dr. Lovejoy has served on science and environmental councils under the Reagan, Bush, and Clinton administrations. At the core of these many influential positions are seminal ideas, which have formed and strengthened the field of conservation biology.

In the 1980s, Dr. Lovejoy brought international attention to the world’s tropical rainforests, and in particular, the Brazilian Amazon, where he has worked since 1965.

With multiple co-edited books (including Biodiversity and Climate Change: Transforming the Biosphere; Drones for Conservation — Field Guide for Photographers, Researchers, Conservationists and Archaeologists; Costa Rican Ecosystems; Climate Change and Biodiversity; On the Edge: The State and Fate of the World’s Tropical Rainforests), Dr. Lovejoy is credited as a founder of the field of climate change biology. He also founded the series Nature, the popular long-term series on public television.

Scientists dramatically enhance the achievable resolution at free-electron lasers with a new technique.

Hard X-ray free-electron lasers (XFELs) have delivered intense, ultrashort X-ray pulses for over a decade. One of the most promising applications of XFELs is in biology, where researchers can capture images down to the atomic scale even before the radiation damage destroys the sample. In physics and chemistry, these X-rays can also shed light on the fastest processes occurring in nature with a shutter speed lasting only one femtosecond – equivalent to a millionth of a billionth of a second.

However, on these minuscule timescales, it is extremely difficult to synchronize the X-ray pulse that sparks a reaction in the sample on the one hand and the laser pulse which ‘observes’ it on the other. This problem is called timing jitter, and it is a major hurdle in ongoing efforts to perform time-resolved experiments at XFELs with ever-shorter resolution.

Nuclear Nonproliferation, Cooperative Threat Reduction and WMD Terrorism — Dr. Natasha Bajema, Director, Converging Risks Lab, The Council on Strategic Risks.


Dr. Natasha Bajema, is a subject matter expert in nuclear nonproliferation, cooperative threat reduction and WMD terrorism, and currently serves as Director of the Converging Risks Lab, at The Council on Strategic Risks, a nonprofit, non-partisan security policy institute devoted to anticipating, analyzing and addressing core systemic risks to security in the 21st century, with special examination of the ways in which these risks intersect and exacerbate one another.

The Converging Risks Lab (CRL) is a research and policy development-oriented program designed to study converging, cross-sectoral risks in a rapidly-changing world, which brings together experts from multiple sectors of the security community, to ask forward-thinking questions about these converging risks, and to develop anticipatory solutions.

Dr. Bajema is also Founder and CEO of Nuclear Spin Cycle, a publishing and production company specializing in national security, entertainment, and publishing.

Prior to this, Dr. Bajema was at the Center for the Study of Weapons of Mass Destruction at the National Defense University, serving as Director of the Program for Emerging Leaders (PEL), as well as serving long-term detail assignments serving in various capacities in the Office of the Secretary of Defense, Acquisitions, Technology and Logistics, Nuclear, Chemical and Biological Defense Programs and in Defense Nuclear Nonproliferation at Department of Energy’s National Nuclear Security Administration.

Prior to joining the Center, Dr. Bajema was a Research Associate at the Center on International Cooperation at New York University, where she supported research staff of the High-Level Panel on Threats, Challenges and Change established by the UN Secretary-General. She has also served as a Junior Political Officer in the Weapons of Mass Destruction Branch of the Department for Disarmament Affairs at the United Nations.

Dr. Bajema’s publications include two co-edited volumes entitled Terrorism and Counterterrorism, and Weapons of Mass Destruction and Terrorism, both of which were published by McGraw Hill. She has also published the novels Bionic Bug, Rescind Order, Genomic Data, and Project Gecko.

Dr. Bajema holds an M.A. in international policy from the Monterey Institute of International Studies and a PhD in international relations from the Fletcher School of Law and Diplomacy.

NASA’s newest Mars rover is beginning to study the floor of an ancient crater that once held a lake.

NASA’s Perseverance rover has been busy serving as a communications base station for the Ingenuity Mars Helicopter and documenting the rotorcraft’s historic flights. But the rover has also been busy focusing its science instruments on rocks that lay on the floor of Jezero Crater.

What insights they turn up will help scientists create a timeline of when an ancient lake formed there, when it dried, and when sediment began piling up in the delta that formed in the crater long ago. Understanding this timeline should help date rock samples – to be collected later in the mission – that might preserve a record of ancient microbes.

In the last decade, lab-grown meat has emerged a sustainable alternative to traditional livestock methods. Livestock strain Earth’s land resources and account for about 14.5 percent of global greenhouse gas emissions. But while scientists can grow thin sheets of cow meat and scrape it together to form a patty, people eat with their eyes as much as their mouths. For lab-grown meat to replace a fresh steak, it needs to look like a steak.

Growing lab-based meat into 3D structures is difficult because it needs constant delivery of oxygen and nutrients. In living organisms, vascular systems fill that need. Researchers at Boston College previously showed that skeletonized spinach leaves, stripped of everything but their veiny, oxygen-dispersing, vascular system, can support patches of heart muscle cells. Now, they show that lab-grown meat can grow on skeletonized spinach, an essential step to growing steak-shaped meat in the lab.

A team of researchers from Zhejiang University, Xi’an Jiaotong University and Monash University has developed a way to bind multiple strands of graphene oxide into a thick cable. In their paper published in the journal Science, the group describes their process and possible uses for it. Rodolfo Cruz-Silva and Ana Laura Elías with Shinshu University and Binghamton University have published a Perspectives piece in the same issue outlining the work by the researchers and explaining why they believe the technique could prove useful in manufacturing efforts.

In recent years, have been exploring the possibility of making products using total or partial self-assembly as a way to produce them faster or at less cost. In where two materials self-assemble into a third material, scientists describe this as a fusion process, borrowing terminology from physics. So when a single material spontaneously separates into two or more other materials, they refer to it as a fission process. In this new effort, the researchers have developed a technique for creating graphene-oxide-based yarn that exploits both processes.

The work by the team is very basic. They created multiple strands of graphene oxide and then dunked them into a solvent for 10 minutes. When the strands were pulled from the solution, they banded together forming a cord, or single strand of yarn. They also developed a means for reversing the process—dunking the strand of yarn in a different solvent solution.

Hey guys — you might like this interview I did with Brent Nally (CEO — Longevity Plan) about why humans can and should strive towards biological immortality. Very grateful for any subs to support the channel!


I interview Brent Nally, host of Lifespan News and CEO/co-founder of Longevity Plan, about the longevity movement and why he believes humans can and should strive for biological immortality. Covers scientific progress, the evolving longevity movement, why some oppose radical life extension and a brief section on Bitcoin.

Lifespan news: https://www.youtube.com/channel/UC-hyW-B6pWS8lPjZk4zLYcQ

Brent’s YouTube: https://www.youtube.com/channel/UCCwpkla04tVxHJUds2J2aqA

Unlocking The Potential Of Salt and Drought Tolerant Crops And Seawater Agriculture — Professor Dr. Mark Tester — Center for Desert Agriculture, King Abdullah University of Science and Technology; Co-founder & CSO, Red Sea Farms.


Professor Dr. Mark Tester is Professor, Plant Science, and Associate Director, Center for Desert Agriculture, Biological and Environmental Science and Engineering Division, of King Abdullah University of Science and Technology (KAUST) in Saudi Arabia.

Prior to joining King Abdullah University of Science and Technology in February 2013, Professor Tester was a professor of plant physiology at the University of Adelaide and the Australian Centre for Plant Functional Genomics from 2009 to 2013. He has a PhD from the University of Cambridge in plant sciences.

The aim of Professor Tester’s research program is to elucidate the molecular genetic mechanisms that enable certain plants to thrive in sub-optimal conditions, such as those of high salinity or high temperature, and then deliver the outputs in economically viable systems, such as barley, rice, tomatoes and quinoa.

An immediate applied aim of the program is to modify crop plants in order to increase productivity in conditions of challenging abiotic stress, with consequent improvement of yield in Saudi Arabia, the region and globally.

A larger aspiration is to unlock seawater, by developing a new economically viable agricultural system where salt-tolerant crops are irrigated with partially desalinized seawater or brackish groundwater.

A company, Red Sea Farms, has been established to facilitate this scientific translation, of which Dr. Tester is Co-founder and CSO.