:quality(80)/p7i.vogel.de/wcms/c2/16/c216af7cc2b04b4db50b56e09bdf9cef/0114195027.jpeg "The excavation team uncovering the wooden structure (Source: Professor Larry Barham, University of Liverpool)")
:quality(80)/p7i.vogel.de/wcms/a7/00/a700addca48d218d6b578e95412bda51/0114182146.jpeg "For the first time, researchers augmented a neural network’s inner layers with a process involving random noise to improve its resilience. (Source: ©iuriimotov; aleksander1 - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/7a/2a/7a2a611e9287a36370b4c6d34ffc885d/0114089151.jpeg "Predicted Hall Scattering Factor for Maxin (Source: Korea Institute of Science and Technology)")
:quality(80)/p7i.vogel.de/wcms/73/fd/73fd032b505c8a0493d200a8b859e00b/0114026184.jpeg "At the glovebox array – a sealed container in which sensitive substances can be processed in a closed atmosphere – Master’s degree student Yanning Ding is demonstrating how the ultra-thin perovskite layer is produced. (Source: Sven Cichowicz / University of Stuttgart)")
:quality(80)/p7i.vogel.de/wcms/c3/b5/c3b50256365b0e090be6e14d6a4c9d0a/0114307390.jpeg "A prototype of the drug-producing implant, which is smaller than an adult’s finger. (Source: Brandon Martin/Rice University)")
:quality(80)/p7i.vogel.de/wcms/b6/13/b6136f786d3f781ba5750c1599ab435b/0114272550.jpeg "The new XPR106DUH (left) and XPR226DR (right) will help you focus on accuracy, savings, and ease-of-use. (Source: Mettler Toledo)")
:quality(80)/p7i.vogel.de/wcms/a1/57/a157157aab794665bd7611247c54b0f8/0114090778.jpeg "The researchers were able to pull water out of the atmosphere and make it drinkable using solar energy. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/e2/52/e252dbd54d6acdddff2f23e9d0f914e9/0114047033.jpeg "At the heart of the experiment performed by the Barz group is a two-stage interferometer in which the quantum state of an entangled photon pair is determined. (Source: Jon Heras, Cambridge Illustrators)")
:quality(80)/p7i.vogel.de/wcms/d0/7e/d07e5f0e44d16da391004791618592eb/0114340888.jpeg "The water level of Lake Victoria in central Africa has risen more than a meter since 2019 during one of the strongest periods of excessive precipitation. (Source: Nasa)")
:quality(80)/p7i.vogel.de/wcms/a6/1a/a61a0e522dc41b779d89981a5cd547d5/0114339748.jpeg "Image shows the warmest month average temperature (degrees Celsius) for Earth and the projected supercontinent (Pangea Ultima) in 250 million years, when it would be difficult for almost any mammals to survive. (Source: University of Bristol)")
:quality(80)/p7i.vogel.de/wcms/f3/42/f342ddf20648a45c3a38130ea48d6586/0114319229.jpeg "Some estimates have indicated earthworms can increase overall plant productivity by about 25 percent. (Source: Steven Fonte)")
:quality(80)/p7i.vogel.de/wcms/e7/9c/e79c1776fcc1dbc4038e7701d2451ea1/0114306638.jpeg "Causonis japonica: A magnified image clearly showing the alternating orange and pink colors of the flower petals. (Source: ©2022 H. Tsukaya CC-BY)")
:quality(80)/p7i.vogel.de/wcms/c8/b9/c8b9806004afc14a3879b9212868881d/0114046306.jpeg "Damage caused by gray mold. Botrytis cinerea is one of the most damaging fungal pathogens, affecting many different agricultural crops and plants before and after harvesting, leading to plant loss and food waste. (Source: ©Kira_Yan, Envato Elements)")
:quality(80)/p7i.vogel.de/wcms/22/7e/227e859537f21966a303604494a8b821/0113805425.jpeg "The Bayer Campus Monheim, the crop protection laboratory of the future, and the global headquarters of the Crop Science division. (Source: Bayer)")
:quality(80)/p7i.vogel.de/wcms/72/ce/72ceccded9540deedb18ee1a9f4b08ab/0113707720.jpeg "New research shows that the right combination of blending fruits can give your body a nutritional boost. (Source: free licensed)")
:quality(80)/p7i.vogel.de/wcms/97/51/97517d830ab065a6b73cde3c954f7e2c/0113704418.jpeg "Ketogenic diets have recently attracted attention as potential adjuvants that increase the efficacy of cancer therapy. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/bb/51/bb5104c0bd65dfdfc00450c792e53bf9/0114377310.jpeg "The researchers particularly focused on what interviewees said about the impact of Long Covid on schooling and education. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/28/68/286867e1ff6148007b4814b634d11b78/0114270929.jpeg "This is the third Phase I clinical trial of the Chadox1 Mers vaccine, developed by researchers at the University of Oxford’s Pandemic Sciences Institute. (Source: Pixabay)")
:quality(80)/p7i.vogel.de/wcms/a2/84/a284065034d2931d2fa0a71d98e38a6b/0114242329.jpeg "Neutralizing antibodies are critical in the fight against Covid-19 because they defend cells from infection by the virus. (Source: Siemens Healthineers )")
:quality(80)/p7i.vogel.de/wcms/97/70/9770d850e11078466e0f68c04f45f83f/0114237536.jpeg "Whole spinal cord visualization of regenerating projections from the lower thoracic spinal cord that project to walking execution centers. (Source: EPFL / .Neurorestore)")
: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
Related Vendor
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)/p7i.vogel.de/wcms/a6/1a/a61a0e522dc41b779d89981a5cd547d5/0114339748.jpeg "Image shows the warmest month average temperature (degrees Celsius) for Earth and the projected supercontinent (Pangea Ultima) in 250 million years, when it would be difficult for almost any mammals to survive. (Source: University of Bristol)")
:quality(80)/p7i.vogel.de/wcms/c4/5b/c45ba4477dc4614e87a7022b7a3ec5ef/0113039047.jpeg "Frances Camille Wu, a graduate research assistant in the Microelectronics Research Center, uses a microscope to study electronic devices in a clean room at the Pickle Research Campus in Austin, Texas. (Source: The University of Texas at Austin)")