World’s Largest International Dark Sky Reserve Created by McDonald Observatory

The Milky Way soars over the domes of McDonald Observatory's Mount Locke showcasing the region's dark skies.
Credit: Stephen Hummel/McDonald Observatory

The world’s largest International Dark Sky Reserve is coming to Texas and Mexico, thanks to a partnership between The University of Texas at Austin’s McDonald Observatory, The Nature Conservancy, the International Dark-Sky Association (IDA) and many others. The designation, granted by the IDA, recognizes the commitment of organizations, governments, businesses and residents in the region to maintaining dark skies. The move will benefit not only astronomical research, but also wildlife, ecology and tourism.

The new Greater Big Bend International Dark Sky Reserve will encompass more than 15,000 square miles in portions of western Texas and northern Mexico. It is the only such reserve to cross an international border.

“This reserve protects both the scientific research and public education missions of McDonald Observatory,” said Taft Armandroff, director of UT Austin’s McDonald Observatory. “Since 1939, the observatory has enabled the study of the cosmos by faculty, students and researchers at UT Austin and other Texas institutions of higher learning, with topics ranging from planets orbiting nearby stars to the accelerating expansion of the universe.”

Mini-Livers on a Chip

Researchers at Gladstone Institutes designed a new platform for studying how the human immune system responds to hepatitis C infection by combining microfluidic technology with liver organoids. Credit: Gladstone Institutes

A vaccine for hepatitis C has eluded scientists for more than 30 years, for several reasons. For one, the virus that causes the disease comes in many genetic forms, complicating the creation of a widely effective vaccine. For another, studying hepatitis C has been difficult because options in animals are limited and lab methods using infected cells have not adequately reflected the real-life dynamics of infection.

Now, researchers at Gladstone Institutes have developed a new platform for studying how the human immune system responds to hepatitis C infection. The method, presented in the scientific journal Open Biology, marries microfluidic technology (which allows scientists to precisely manipulate fluid at a microscopic scale) with liver organoids (three-dimensional cell clusters that mimic the biology of real human livers).

“The 3D structure and cellular composition of liver organoids allows us to study viral entry and replication in a highly relevant physiological manner,” says Gladstone Senior Investigator Todd McDevitt, PhD, a senior author of the new study.

“Our approach enables a more controlled and accurate investigation into the immune response to hepatitis C infection,” says Melanie Ott, MD, PhD, director of the Gladstone Institute of Virology and another senior author of the study. “We hope our method will accelerate the discovery of a much-needed vaccine.”

Lung surfactants that could lead to better treatments for respiratory illnesses

The above video shows fluorescent microscopy footage of the finger-like crystalline structures of lung surfactant monolayers, which the researchers showed elongate with an increase in pressure.
Credit: Zasadzinski Research Lab, University of Minnesota

A team led by University of Minnesota Twin Cities engineering researchers analyzed the fundamental properties and structures of lung surfactant—a naturally occurring substance that helps human and animal lungs expand and contract—providing insight that could eventually help scientists develop better treatments for respiratory illnesses.

The paper is published in Science Advances, a peer-reviewed, multidisciplinary scientific journal published by the American Association for the Advancement of Science.

Both human and animal lungs naturally produce a surfactant, a substance consisting of lipids and proteins that coats the lungs and decreases the surface tension as we inhale and exhale, making it easier to breathe.

Respiratory illnesses like pneumonia or COVID-19 can impede the lung surfactant from working properly, leading to complications in breathing. A similar issue occurs in pre-term babies, who sometimes haven’t yet developed the ability to produce the substance and suffer from Neonatal Respiratory Distress Syndrome. Right now, treatments consist of giving humans replacement surfactant taken from animal lungs, but researchers have been working to create synthetic surfactants to treat these conditions for years.

Discovery of Matter-Wave Polaritons Sheds New Light on Photonic Quantum Technologies

An artistic rendering of the research findings in the polariton study shows the atoms in an optical lattice forming an insulating phase (left); atoms turning into matter-wave polaritons via vacuum coupling mediated by microwave radiation represented by the green color (center); polaritons becoming mobile and forming a superfluid phase for strong vacuum coupling (right).
Photo Credit: Alfonso Lanuza/Schneble Lab/Stony Brook University.

The development of experimental platforms that advance the field of quantum science and technology (QIST) comes with a unique set of advantages and challenges common to any emergent technology. Researchers at Stony Brook University, led by Dominik Schneble, PhD, report the formation of matter-wave polaritons in an optical lattice, an experimental discovery that enables studies of a central QIST paradigm through direct quantum simulation using ultracold atoms. The researchers project that their novel quasiparticles, which mimic strongly interacting photons in materials and devices but circumvent some of the inherent challenges, will benefit the further development of QIST platforms that are poised to transform computing and communication technology.

The findings are detailed in a paper published in Nature Physics.

The research sheds light on fundamental polariton properties and related many-body phenomena, and it opens up novel possibilities for studies of polaritonic quantum matter.

An important challenge in work with photon-based QIST platforms is that while photons can be ideal carriers of quantum information they do not normally interact with each other. The absence of such interactions also inhibits the controlled exchange of quantum information between them. Scientists have found a way around this by coupling the photons to heavier excitations in materials, thus forming polaritons, chimera-like hybrids between light and matter. Collisions between these heavier quasiparticles then make it possible for the photons to effectively interact. This can enable the implementation of photon-based quantum gate operations and eventually of an entire QIST infrastructure.

Under Ocean Acidification, Embryos of a Key Forage Fish Struggle to Hatch

This photo shows sand lance embryos that have and have not hatched. Sand lance have trouble hatching at future ocean CO2 levels
Credit: Emma Cross.

When carbon is emitted into the atmosphere, about a quarter of it is absorbed by the earth’s oceans. As the oceans serve as a massive ‘sink’ for carbon, there are changes to the water’s pH – a measure of how acidic or basic water is. As oceans absorb carbon, their water becomes more acidic, a process called ocean acidification (OA). For years, researchers have worked to understand what effect this could have on marine life.

While most research so far shows that fish are fairly resilient to OA, new research from UConn, the University of Washington, the National Oceanic and Atmospheric Administration (NOAA), and Southern Connecticut State University, shows that an important forage fish for the Northwest Atlantic called sand lance is very sensitive to OA, and that this could have considerable ecosystem impacts by 2100. The team’s findings have just been published in Marine Ecology Progress Series.

Sand lance spawn in the winter months in offshore environments that tend to have stable, low levels of CO2, explains UConn Department of Marine Sciences researcher and lead author Hannes Baumann.

“Marine organisms are not living in a uniform ocean,” Baumann says. “In near shore environments, large CO2 fluctuations between day and night and between seasons are the norm, and the fish and other organisms are adapted to this variability. When we stumbled upon sand lances, we suspected they're different. We thought that a fish that lives in a more open-ocean offshore environment might be more sensitive than the near-shore fish because there’s just much less variability.”

Scientists Have Spotted the Farthest Galaxy Ever

HD1, object in red, appears at the center of a zoom-in image.
Credit: Harikane et al.
Hi-Res Zoomable Image

An international team of astronomers, including researchers at the Center for Astrophysics | Harvard & Smithsonian, has spotted the most distant astronomical object ever: a galaxy.

Named HD1, the galaxy candidate is some 13.5 billion light-years away and is described today in the Astrophysical Journal. In an accompanying paper published in the Monthly Notices of the Royal Astronomical Society Letters, scientists have begun to speculate exactly what the galaxy is.

The team proposes two ideas: HD1 may be forming stars at an astounding rate and is possibly even home to Population III stars, the universe’s very first stars — which, until now, have never been observed. Alternatively, HD1 may contain a supermassive black hole about 100 million times the mass of our Sun.

“Answering questions about the nature of a source so far away can be challenging,” says Fabio Pacucci, lead author of the MNRAS study, co-author in the discovery paper on ApJ, and an astronomer at the Center for Astrophysics. “It’s like guessing the nationality of a ship from the flag it flies, while being faraway ashore, with the vessel in the middle of a gale and dense fog. One can maybe see some colors and shapes of the flag, but not in their entirety. It’s ultimately a long game of analysis and exclusion of implausible scenarios.”

Insomnia could increase people’s risk of type 2 diabetes, study finds

People who have difficulty getting to sleep or staying asleep have higher blood sugar levels than people who rarely have sleep issues, new research has found. The University of Bristol-led findings suggest insomnia could increase people’s risk of type 2 diabetes, and that lifestyle or pharmacological treatments that improve insomnia could help to prevent or treat the condition.

The study, led by the University of Bristol, supported by the universities of Manchester, Exeter, and Harvard, and funded by Diabetes UK, is published in Diabetes Care.

Insomnia, not getting enough sleep, and having a later bedtime, have been linked in previous studies to a greater risk of type 2 diabetes. In this study, the research team assessed whether these associations are explained by causal effects of sleep traits on blood sugar levels

The researchers used a statistical technique called Mendelian Randomization to see how five sleep measures - insomnia, sleep duration, daytime sleepiness, napping and morning or evening preference (chronotype) - were related to average blood sugar levels assessed by a measure called HbA1c levels. Using Mendelian Randomization, which groups people according to a genetic code randomly assigned at birth, allowed the researchers to remove any bias from the results.

The study of over 336,999 adults living in the UK, showed that people who reported that they often had difficulty getting to sleep or staying asleep had higher blood sugar levels than people who said they never, rarely, or only sometimes had these difficulties. The research team found no clear evidence of an effect of other sleep traits on blood sugar levels.

The findings could improve researchers' understanding of how sleep disturbance influences type 2 diabetes risk. The study also suggests that lifestyle and/or pharmacological interventions that improve insomnia might help to prevent or treat diabetes.

Moving toward cleaner, more efficient hydrogen production

Hydrogen-fueled vehicles could be an important step toward a cleaner planet. They emit no chemicals other than water vapor, and would help reduce harmful carbon dioxide and air pollution levels. But although hydrogen is one of the most abundant elements on the planet, it is currently costly to produce from nonfossil sources.

Hydrogen is conventionally derived from natural gas through a process called methane steam reforming, but splitting water through an electrochemical process is cleaner and more sustainable. That process uses catalysts, which are substances that increase the rate of a chemical reaction without themselves undergoing any permanent chemical change. However, the cost of the greener technique has been a barrier in the marketplace.

Now a team of researchers led by Oregon State University (OSU) has shown that hydrogen can be cleanly produced with much greater efficiency and at a lower cost than is possible with current commercially available catalysts. The new findings, which describe ways to design catalysts that can greatly improve the efficiency of the clean hydrogen production process, were published in Science Advances and JACS Au.

The research team used the resources of the Advanced Photon Source (APS), a U.S. Department of Energy (DOE) Office of Science user facility at DOE’s Argonne National Laboratory, to test and confirm their findings.

Micro­cavities as a sensor plat­form

Nano particles trapped between mirrors might be a promising platform for quantum sensors.
Credit: IQOQI Innsbruck

Sensors are a pillar of the Internet of Things, providing the data to control all sorts of objects. Here, precision is essential, and this is where quantum technologies could make a difference. Researchers in Innsbruck and Zurich are now demonstrating how nanoparticles in tiny optical resonators can be transferred into quantum regime and used as high-precision sensors.

Advances in quantum physics offer new opportunities to significantly improve the precision of sensors and thus enable new technologies. A team led by Oriol Romero-Isart of the Institute of Quantum Optics and Quantum Information at the Austrian Academy of Sciences and the Department of Theoretical Physics at the University of Innsbruck and a team lead by Romain Quidant of ETH Zurich are now proposing a new concept for a high-precision quantum sensor. The researchers suggest that the motional fluctuations of a nanoparticle trapped in a microscopic optical resonator could be reduced significantly below the zero-point motion, by exploiting the fast unstable dynamics of the system.

New Insights into the Neuroscience Behind Conscious Awareness of Choice

Nancy Smith participates in neuroscience experiments to play a digital piano using a brain-computer interface.
Credit: T. Aflalo

When you absentmindedly reach out to pick up your cup of coffee and take a sip, what happens in your brain? Many studies have shown that brain activity begins to ramp up even before you are aware of your choice to move. But this poses a conundrum: Do we have free will to make our own choices, if our brains are already preparing for actions before we are even conscious of them?

Now, a new study from the laboratory of Richard Andersen, James G. Boswell Professor of Neuroscience, and Leadership Chair and Director of the T&C Chen Brain–Machine Interface Center, gives new insights into how the brain encodes for our choices about movement. The research indicates that brain activity of abstract high-level choices (such as the desire to consume more coffee) connects to the actual actions (such as reaching out a hand) even before the awareness of such choices to move.

"The implementation of current brain-machine interfaces that read out the intent of patients assume that they are simultaneously consciously aware of the intent that is being decoded from their brains," says Andersen. "Taking into account this early subconscious activity is critical when designing algorithms for brain-computer interfaces that could one day enable people with spinal or brain damage to regain function."