:quality(80)/p7i.vogel.de/wcms/59/77/59779f67ac5adaa9c2dd25f329a7e157/0110487266.jpeg "The collaboration has resulted in a secure and reliable combination of Trakcel’s cell orchestration platform Ocellos and Lonza’s manufacturing Moda-Es(R) platform. (Source: Lonza)")
:quality(80)/p7i.vogel.de/wcms/78/7e/787e895c1825e5333b0d923190dec6c8/0110351133.jpeg "Crab shells, like the one pictured here, could be “upcycled” to help make new battery materials. (Source: Adapted from ACS Omega, 2023)")
:quality(80)/p7i.vogel.de/wcms/da/86/da868751e2180706cdaf0d0c235159af/0110312814.jpeg "The crystal structure of the compound K₉N₅₆. (Source: Dominique Laniel)")
:quality(80)/p7i.vogel.de/wcms/c1/1b/c11b62e20d7a419337b0c6bfb602939c/0110259145.jpeg "Official launch of Evonik's new GMP facility in Hanau, Germany. (Source: Evonik)")
:quality(80)/p7i.vogel.de/wcms/2f/47/2f47f02d74dae065924498246dd68bda/0110427140.jpeg "Proteins that glow bright blue or green, as pictured here, could make disease diagnosis quicker and easier. (Source: Maarten Merkx)")
:quality(80)/p7i.vogel.de/wcms/d2/49/d249c220d9205ca75ee52e6d5c602f04/0109710663.jpeg "Illustration of the high-efficiency metal-free battery developed by Kaust researchers. Unlike conventional batteries, this battery combines an ammonium-cation-containing electrolyte with carbon-based electrodes. (Source: © 2023 Kaust; Heno Hwang)")
:quality(80)/p7i.vogel.de/wcms/d0/9e/d09efd9323e1f45fe0afa9ef0b085802/0109627099.jpeg "Researchers developed a Raman microscope that can acquire information hundreds of times faster than a conventional Raman microscope. This extra speed makes it possible to acquire large-area hyperspectral images of living cells, such as the ones seen here. (Source: Katsumasa Fujita, Osaka University)")
:quality(80)/p7i.vogel.de/wcms/df/68/df68ceabd951f8e4a41a9fa15abd95ba/0109568661.jpeg "This small, voice-activated device extracts and pretreats bacterial DNA and could make the laboratory safer for scientists and technicians. (Source: ACS Sensors )")
:quality(80)/p7i.vogel.de/wcms/d3/9a/d39a854c60e490eed32f7cc49a60d104/0110554565.jpeg "Researchers at Chalmers University of Technology, Sweden, have developed a new biobased material, a form of powder based on cellulose nanocrystals to purify water from pollutants, including textile dyes. (Source: Chalmers University of Technology/ David Ljungberg)")
:quality(80)/p7i.vogel.de/wcms/48/b8/48b84830af709f9808bff5df582976cf/0110520503.jpeg "Cinereous and Griffon Vultures feeding in the wild. (Source: Hristo Peshev, Fund for Wild Flora and Fauna)")
:quality(80)/p7i.vogel.de/wcms/7d/1c/7d1c904ad56eb9ce02999cf46de539ac/0110439227.jpeg "Coral reefs at a study site off Taiping Island, South China Sea. (Source: Yi Bei Liang)")
:quality(80)/p7i.vogel.de/wcms/03/1f/031ff4a30e1d2a453d379d07280d775e/0110390706.jpeg "This study marks the first time that next-generation gene sequencing technology has been used to analyze soil from such a high elevation on Mount Everest, enabling researchers to gain new insight into almost everything and anything that’s in them. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/8d/1f/8d1f31b5f75917ec3c939e3a3592afd3/0110552719.jpeg "Purine metabolite xanthine is found at high levels in caffeinated foods such as coffee, tea and chocolate. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/e7/3e/e73ee43f3e961c697311f77ba4afef9f/0110520476.jpeg "Coffee is one of the most frequently consumed beverages worldwide and its potential health effects trigger significant scientific research. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/dd/5f/dd5ffaf01b6c60c177399e2c9b227130/0110390203.jpeg "The analysis of almost 130,000 product additions by nearly 80 brands over eleven years in the U.S. soda category shows that, on average, sugar content reductions perform comparable to similar, (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/7d/91/7d91cac97b08ee822785f77214df59c3/0110320597.jpeg "Scientists quantified the reactive polysulfide content of 22 different types of vegetables. They revealed that reactive polysulfides are not only found in the leek genus (Allium), such as onions and garlic but also in the cruciferous family of vegetables (Brassicaceae), such as broccoli and cabbage. (Source: Osaka Metropolitan University)")
:quality(80)/p7i.vogel.de/wcms/68/6e/686e2ec5f2714e20db4c556c8ce7e1fc/0110426963.jpeg "This cross-sectional study aimed to determine if there is an association between dog and cat ownership and sleep quality and sleep disorders. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/9d/7c/9d7ca684f91e921100ec585f1243b67c/0110285938.jpeg "Nuclear magnetic resonance shows the structure of a natural protein called lanmodulin, which binds rare earth elements with high selectivity and was discovered five years ago by Penn State researchers. Researchers recently genetically reprogramed the protein to favor manganese over other common transition metals like iron and copper. (Source: Cotruvo Lab / Penn State)")
:quality(80)/p7i.vogel.de/wcms/31/b1/31b147dc8bd97c582662914f19614925/0110107896.jpeg "Thismia kobensis at the new locality: As the moniker fairy lantern denotes, it looks like a tiny lantern that illuminates the dark forest floor. (Source: Kenji Suetsugu)")
:quality(80)/images.vogel.de/vogelonline/bdb/1710600/1710675/original.jpg "Discover how to set yourself up for success when performing balance-based density determination of solids such as jewelry and precious metals. (Mettler Toledo)")
:quality(80)/images.vogel.de/vogelonline/bdb/1682500/1682579/original.jpg "The new XPR Analytical balance redesigned to meet the needs of laboratory technicians of working fast and lean. (Mettler Toledo)")
:quality(80)/images.vogel.de/vogelonline/bdb/1677000/1677080/original.jpg "Enhance your weighing accuracy, comfort and productivity with the redesigned XPR Analytical balance. (Mettler Toledo)")
Smart Building Materials Chameleon-Like Buildings Change Color to Save Energy
Researchers at the University of Chicago’s Pritzker School of Molecular Engineering (PME) have designed a chameleon-like building material that changes its infrared color — and how much heat it absorbs or emits — based on the outside temperature. On hot days, the material emits most infrared heat. On colder days, the material emits just a fraction of the infrared heat, helping keep a building warm.
According to some estimates, buildings account for 30 percent of global energy consumption and emit ten percent of all global greenhouse gas. About half of this energy footprint is attributed to the heating and cooling of interior spaces. “For a long time, most of us have taken our indoor temperature control for granted, without thinking about how much energy it requires,” said Hsu. “If we want a carbon-negative future, I think we have to consider diverse ways to control building temperature in a more energy-efficient way.”
Researchers have previously developed radiative cooling materials that help keep buildings cool by boosting their ability to emit infrared, the invisible heat that radiates from people and objects. Materials also exist that prevent the emission of infrared in cold climates. “A simple way to think about it is that if you have a completely black building facing the sun, it’s going to heat up more easily than other buildings,” said PME graduate student Chenxi Sui, the first author of the new manuscript. That kind of passive heating might be a good thing in the winter, but not in the summer.
As global warming causes increasingly frequent extreme weather events and variable weather, there is a need for buildings to be able to adapt; few climates require year-round heating or year-round air conditioning.
Hsu and colleagues designed a non-flammable “electrochromic” building material that contains a layer that can take on two conformations: solid copper that retains most infrared heat, or a watery solution that emits infrared. At any chosen trigger temperature, the device can use a tiny amount of electricity to induce the chemical shift between the states by either depositing copper into a thin film, or stripping that copper off.
In the new paper, the researchers detailed how the device can switch rapidly and reversibly between the metal and liquid states. They showed that the ability to switch between the two conformations remained efficient even after 1,800 cycles.
Then, the team created models of how their material could cut energy costs in typical buildings in 15 different U.S. cities. In an average commercial building, they reported, the electricity used to induce electrochromic changes in the material would be less than 0.2 percent of the total electricity usage of the building, but could save 8.4 percent of the building’s annual HVAC energy consumption. “Once you switch between states, you don’t need to apply any more energy to stay in either state,” said Hsu. “So for buildings where you don’t need to switch between these states very frequently, it’s really using a very negligible amount of electricity.”
So far, Hsu’s group has only created pieces of the material that measure about six centimeters across. However, they imagine that many such patches of the material could be assembled like shingles into larger sheets. They say the material could also be tweaked to use different, custom colors — the watery phase is transparent and nearly any color can be put behind it without impacting its ability to absorb infrared.
The researchers are now investigating different ways of fabricating the material. They also plan to probe how intermediate states of the material could be useful. “We demonstrated that radiative control can play a role in controlling a wide range of building temperatures throughout different seasons,” said Hsu. “We’re continuing to work with engineers and the building sector to look into how this can contribute to a more sustainable future.”
References: Dynamic electrochromism for all-season radiative thermoregulation; Nature Sustainability; DOI:10.1038/s41893-022-01023-2
(ID:49040667)
:quality(80)/images.vogel.de/vogelonline/bdb/1963000/1963087/original.jpg "By analyzing the data, the researchers were able to reveal a more complete picture of trends in Neptune’s temperatures than ever before. (©dottedyeti–stock.adobe.com)")
:quality(80)/images.vogel.de/vogelonline/bdb/1896500/1896586/original.jpg "On the left panel, the copper-oxide planes of the material YBCO are presented in the strange metal phase, where the strong interaction between electrons, the 'quantum entanglement', is illustrated as lightning. On the right panel, the same planes are presented when the charge density waves appear. The symmetry of the system is reduced by the appearance of these local modulations of the conducting electrons, which cause the suppression of the strange metal phase. (Chalmers University of Technology/ Yen Strandqvist)")