World hunger is a persistent problem despite all of humanity’s progress in recent years. However, I believe that we have a real shot at defeating world hunge…
Scientists are using high-energy pulses of electricity to turn any source of carbon into turbostratic graphene in an instant. The process promises environmental benefits by turning waste into valuable graphene that can then strengthen concrete and other composite materials.
Scientists typically prefer to work with ordered systems. However, a diverse team of physicists and biophysicists from the University of Groningen found that individual light-harvesting nanotubes with disordered molecular structures still transport light energy in the same way. By combining spectroscopy, molecular dynamics simulations and theoretical physics, they discovered how disorder at the molecular level is effectively averaged out at the microscopic scale. The results were published on 28 September in the Journal of the American Chemical Society.
The double-walled light-harvesting nanotubes self-assemble from molecular building blocks. They are inspired by the multi-walled tubular antenna network of photosynthetic bacteria found in nature. The nanotubes absorb and transport light energy, although it was not entirely clear how. “The nanotubes have similar sizes but they are all different at the molecular level with the molecules arranged in a disordered way,” explains Maxim Pshenichnikov, Professor of Ultrafast Spectroscopy at the University of Groningen.
HyImpulse completed the first hot-fire test of the company’s 16,800-pounds-force hybrid rocket motor on Sept. 15. Credit: HyImpulse.
VALLETTA, Malta — Launch startup HyImpulse successfully tested its 16,800-pounds-force hybrid rocket motor this month at German space agency DLR’s Lampoldshausen facility.
Headquartered in Neuenstadt am Kocher, Germany, HyImpulse is developing its three-stage SL1 launch vehicle designed to carry payloads of up to 500 kilogram to Sun-synchronous orbit. The light-lift launch vehicle will be powered by twelve 16,800-pounds-force hybrid rocket motors — eight on its first stage, and four on its second stage — plus four smaller but otherwise identical engines powering its third stage.
The HyImpulse-developed hybrid rocket motor is powered by a paraffin-based fuel and liquid oxygen. The motor is designed to make use of simpler hardware than a liquid-fueled system while offering greater safety than strictly solid-fueled motors.
Karen Potter, Director of Sustainability Hub and ideaXme sustainability ambassador interviews Christoph Promberger, M.Sc., Executive Director Foundation Conservation Carpathia (FCC). https://www.carpathia.org
Karen Potter comments:
In 2009, the Foundation Conservation Carpathia was founded by a dozen international philanthropists and conservationists with the goal to stop illegal logging and to protect a significant surface of Carpathian forests to form a completely protected area.
The FCC was founded in response to the restitution of formerly nationalised forests to private citizens in Romania. This process triggered massive clear-cuts and thousands of hectares of forests were illegally logged, posing a severe threat to the integrity of the Carpathian ecosystem.
Wilderness is disappearing globally at an alarming rate, less than 2% of Europe’s surface is still in its original state and the Carpathian Mountains form some of the largest contiguous forests on the continent with the highest percentage of still virgin woodlands; they contain an extraordinarily high number of species.
Karen is a passionate environment and sustainability campaigner leading Government and Parliamentary efforts to promote Net Zero policy solutions as well as lead on COP26, business, community and civic action. She is a project development specialist with extensive experience in designing and delivering new initiatives to promote sustainability, social responsibility, smart energy, the Green Recovery and clean tech investment. She is highly experienced in government, NGO and public sector communications, building and managing senior stakeholder relations and media engagement.
Scientists have long theorised that there are other types of superconductor out there waiting to be discovered, and it turns out they were right: new research has identified a g-wave superconductor for the first time, a major development in this area of physics.
Superconductors are materials that offer no electrical resistance, so electricity can pass through them with close to 100 percent efficiency.
That sounds great when you think about the potential of super-efficient power grids that don’t lose energy to heat. But there’s a catch. Materials that are able to act in this way usually need to be cooled to ultra-low temperatures before the actual superconductivity starts happening.
Structural coloration techniques have improved display science due to their high durability in terms of resistance to bleaching and abrasion, and low energy consumption. Here, we propose and demonstrate an all-solid-state, large-area, lithography-free color filter that can switch structural color based on a doped semiconductor. Particularly, an indium-gallium-zinc-oxide (IGZO) thin film is used as a passive index-changing layer. The refractive index of the IGZO layer is tuned by controlling the charge carrier concentration; a hydrogen plasma treatment is used to control the conductivity of the IGZO layer. In this paper, we verify the color modulation using finite difference time domain simulations and experiments. The IGZO-based color filter technology proposed in this study will pave the way for charge-controlled tunable color filters displaying a wide gamut of colors on demand.
Long-distance cargo ships lose a significant amount of energy due to fluid friction. Looking to the drag reduction mechanisms employed by aquatic life can provide inspiration on how to improve efficiency.
Fish and seaweed secrete a layer of mucus to create a slippery surface, reducing their friction as they travel through water. A potential way to mimic this is by creating lubricant-infused surfaces covered with cavities. As the cavities are continuously filled with the lubricant, a layer is formed over the surface.
Though this method has previously been shown to work, reducing drag by up to 18%, the underlying physics is not fully understood. In the journal Physics of Fluids, researchers from the Korea Advanced Institute of Science and Technology and Pohang University of Science and Technology conducted simulations of this process to help explain the effects.