Tuesday, March 07, 2023

How does the immune system react to altered gravity?

Parabolic flights: a simulated gravity laboratory

Peer-Reviewed Publication

UNIVERSITY OF BARCELONA

How does the immune system react to altered gravity? 

IMAGE: MICROGRAVITY CONDITIONS WERE GENERATED DURING A SHORT PARABOLIC FLIGHT —WITH FIFTEEN PARABOLAS— IN AN AEROBATIC FLIGHT CONDUCTED WITH THE MUDRY CAP10 AIRCRAFT. view more 

CREDIT: UNIVERSITY OF BARCELONA

Space travel has always tested the human body by the effects of the new conditions of altered gravity on biological systems. It has long been known that continuous exposure to microgravity conditions human physiology and causes effects that compromise muscular, sensory, endocrine and cardiovascular functions. But is it also risky to be exposed to altered gravity for short periods of time?

Now, a paper published in the journal Acta Astronautica examines the effects on the human immune system of microgravity generated by a parabolic flight. After a short exposure to altered gravity, there were no significant changes in the defensive capacity of blood cells in the volunteers who took part in the study. In addition, the study found no evidence of aggregation processes in erythrocytes —the cells that transport O2 and CO2 to the cardiovascular system— after the parabolic flight.

The study was coordinated by Ginés Viscor, professor at the Department of Cell Biology, Physiology and Immunology of the Faculty of Biology of the University of Barcelona, and it included the participation of experts Jordi Petriz, from the Germans Trias i Pujol Research Institute (IGTP), and Antoni Pérez-Poch, from the Technical University of Catalonia-BarcelonaTech (UPC) and the Institute of Space Studies of Catalonia (IEEC), among other authors. The first author of the study is the researcher Abril Gorgori-González (UB). It counted on the support from the Medical Service of the Safety, Health and Environment Office (OSSMA) of the UB, the Aeroclub Barcelona-Sabadell and the company Thermo Fisher Scientific.

Parabolic flights: a simulated gravity laboratory

Space travel is the ideal scenario to study the effect of microgravity on the human body. These trips make it possible to study the consequences of long-term exposure to microgravity on different astronauts simultaneously, but they require a high cost in terms of time, funding and infrastructure. Without leaving the Earth's atmosphere, it is also possible to simulate simulated gravity conditions on different platforms. For example, through parabolic flights in aircraft, which make it possible to study the effect of altered microgravity in the short term —even for a few seconds— at an affordable cost.

"Artificial platforms such as parabolic flights in aircraft provide valuable but more limited results, as they only allow the effects of altered gravity to be studied in the short term (seconds or minutes). Therefore, the profiles of physiological changes that can be recreated with parabolic flights are immediate and transitory changes that microgravity generates in the human body", says Ginés Viscor, head of the Adaptive Physiology Group: Exercise, Hypoxia and Health at the UB.

As part of the study, a 20-minute parabolic flight was conducted with the Mudry CAP10 aircraft —a 2-seat aerobatic training aircraft— during which fifteen parabolas were performed. "Each parabola allows a period of microgravity to be reached for approximately eight seconds, which is followed and preceded by hypergravity phases of about two seconds", says the researcher Antoni Pérez-Poch, from the Department of Computer Science at the UPC, and lecturer of the School of Engineering of Barcelona East (EEBE) of the UPC and the IEEC.

These parabolic flights with an aerobatic plane —a pioneering method in the world, developed in Catalonia— were operated by the Aeroclub Barcelona-Sabadell and are the result of an aeronautical research carried out in collaboration with the UPC. "This innovative technique has a good ratio of time achieved in microgravity compared to the cost of maintenance, which is very favourable compared to the greater use of aircraft, although it also has some limitations (logistical and space). In the case of parabolic flights with a larger aircraft, a more expensive operation that has been used since the beginning of the space race by agencies such as NASA or ESA (European Space Agency), up to 25 seconds per parabola could be achieved", says Pérez-Poch.

Immune function under pressure

The immediate effects of microgravity on the blood system derive from the redistribution of blood volume, blood flow and body fluids to the upper body. "Cardiovascular adaptations consist of an altered cardiovascular response causing abnormalities in body orientation and balance, poor response to orthostatic stress, decreased cardiac function and inadequate cardiovascular response to exercise", says Ginés Viscor.

One of the most vulnerable physiological systems to any change in environmental conditions is the immune system, and this is explained by its great plasticity and responsiveness to internal and external imbalances. In the scientific literature, there are still no conclusive results on the immune response to short exposure in flights with altered gravity, and in some cases the conclusions are even contradictory.

In this study, the team analysed the response of the immune system to short exposure to microgravity based on several parameters: erythrocyte and leukocyte counts, haemoglobin concentration, phagocytic capacity and oxidative metabolism.

"The results reveal that the human blood samples’ exposure to altered gravity conditions in parabolic flight did not involve negative effects in relation to samples that were left parallelly on the ground during the experimental study. There are also no significant changes in peripheral blood cell counts", says Jordi Petriz (IGTP).

"Except for the monocytes —a type of leukocyte— no significant differences have been observed in the functionality of immune cells in terms of either their oxidative metabolism or their phagocytic capacity", says researcher Abril Gorgori-González (UB). "Hypothetically, if there were changes in the functionality of leukocytes when exposed to an altered gravity, the immune function and defence against external infections or tumour processes would also be compromised”.

The team has applied the technique of flow cytometry with acoustic focusing with little manipulation of the volunteers' blood samples. According to the authors, the sample limitation typical of acrobatic flight studies —with logistical constraints— does not allow general conclusions to be drawn. Therefore, the goal now is to continue research on the human immune system with other microgravity simulation platforms to study physiological alterations, avoid complications and anticipate risk situations.

Space tourist warning

Space tourism is an activity of great economic interest for some business sectors. However, one of the main differences between space tourists and astronauts is the physical and psychological preparation prior to the trip.

"Altered gravity or the constant lack of gravity is one of several changes in the environment faced by these space travellers. The human body has evolved under the conditions of Earth's gravity and is not adapted to the absence of this attractive force. In space travel, other factors such as ionising radiation, constant noise, isolation, confinement, a total distortion of circadian rhythms and short exposure to extreme temperatures during the return to the atmosphere have to be considered", the experts warn.

"Long-term metabolic, osteoporosis and ophthalmological problems have also been described. Although the effect of space travel on untrained space travellers has not been studied, it is possible that all the stressors of the physical environment could negatively affect the health of space tourists. Therefore, for the time being, 'outer space visits' are designed to be of short duration", the team concludes.

  

The volunteers' blood samples were exposed to altered gravity conditions in parabolic flight.

These parabolic flights with an aerobatic plane —a pioneering method in the world, developed in Catalonia— were operated by the Aeroclub Barcelona-Sabadell.

The human blood samples’ exposure to altered gravity conditions in parabolic flight did not involve negative effects in relation to samples that were left parallelly on the ground during the experimental study.


CREDIT

UNIVERSITY OF BARCELONA

First visible-light induced simultaneous cleavage of C-C and C-N bonds with silver-modified polyoxometalate photocatalyst, researchers report

Peer-Reviewed Publication

TSINGHUA UNIVERSITY PRESS

Visible-light-promoted POMs photocatalysts 

IMAGE: A CHINESE RESEARCH TEAM SYNTHESIZED SILVER-MODIFIED POLYOXOMETALATES AND ACHIEVED THE FIRST EXAMPLE OF VISIBLE-LIGHT-PROMOTED SIMULTANEOUS CLEAVAGE OF C-C BOND AND C-N BOND CATALYZED BY A POM PHOTOCATALYST. view more 

CREDIT: POLYOXOMETALATES, TSINGHUA UNIVERSITY PRESS

Cracking carbon bonds is a notoriously difficult problem, but it may hold the key to generating greener, more sustainable chemicals. A Chinese research team achieved the first visible-light-promoted simultaneous cleavage of carbon-carbon and carbon-nitrogen bonds via a silver-modified polyoxometalate photocatalyst, unlocking avenues for applications like carbon-neutral alternatives for fossil fuels. The researchers’ findings were published on March 3 in Polyoxometalates.

 

Inexpensive and highly efficient, photocatalytic technology is being used to solve increasingly serious environmental pollution problems. Polyoxometalates (POMs) are a class of metal-oxide clusters with unique physicochemical properties that make them particularly effective in the field of photocatalysis — using light energy to drive a chemical reaction.

 

Thanks to the stability of their molecular structures and reversible redox properties, POMs as photocatalysts can break down organic pollutants in wastewater and reduce carbon dioxide. POMs can also catalyze simple organic transformations, including bond formation reactions of carbon-carbon (C-C) and carbon-nitrogen (C-N).

 

However, most of the POMs can only work using ultraviolet light.

 

“It is of great significance to design and synthesize new visible-light-promoted POMs photocatalysts and explore their potential in new organic reactions,” said Shujun Li, study author from Henan Normal University.

 

With this goal, Li and colleagues explored synthesizing visible-light promoted POMs photocatalysts to wield in selective, simultaneous carbon bond cleaving.

 

“C-C and C-N bonds are the most widespread and fundamental bonds existing in organic compounds,” said Li. “Selectively catalytic cleavage of C–C bonds or C–N bonds for chemical transformations is an important topic in synthetic chemistry and has become one of the most attractive but challenging tasks.”

 

Chemists have pursued this objective over the past few decades because cracking these stubborn bonds might be key to finding valuable new chemicals or more sustainable ways to create known ones. As such, they have developed a variety of catalytic systems to cleave C–C bonds or C–N bonds separately. However, cleavage of both C–C and C–N bonds in a single organic transformation is a challenging objective.

 

“Few examples of simultaneous cleavage of C-C and C-N bonds in one substrate molecule have been reported so far,” said Li.

 

To make things more complicated, rapid, simultaneous cleavage of these types of bonds requires harsh reaction conditions such as high temperatures and strong oxidizing or initiating agents.

 

The research team combined niobium (Nb)/tungsten (W) mixed-addendum POM and silver (Ag) ion to obtain a silver-modified polyniobotungstate (Ag-Nb/W).

 

Ag-Nb/W showed strong absorption in the visible region, which encouraged the researchers to study its catalytic activity under visible light. The researchers’ investigations included analysis of substrate scope and bounds of conditions for best performance, as well as the stability and reusability of Ag-Nb/W.

 

The results indicated that the synthesis and structure of Ag-Nb/W supports efficient catalysis to simultaneously cleave C–C and C–N bonds under visible light in mild conditions. In addition, Ag-Nb/W could be reused up to six times without a reduction in the catalytic activity.

 

“To the best of our knowledge, this is the first example of visible-light-promoted simultaneous cleavage of C-C bond and C-N bond catalyzed by a POM photocatalyst, which coincides with the social demand for green chemistry and sustainable development,” said Li.

 

This work provides a feasible revelation for designing new visible-light-induced polyoxometalates photocatalysts to be used in organic reactions involving the cleavage of C–C and C–N bonds, said Li.

 

In future steps, the researchers plan to combine this compound with other solid carriers to design a dispersed and more stable photocatalytic material suitable for its applications in photocatalysis.

 

This work was supported by the National Natural Science Foundation of China and the Program for Science & Technology Innovation Talents in Universities of Henan Province.

 

Other contributors include Na Li, Gang Li, Yubin Ma, Mengyao Huang, Qingchun Xia, Qianyi Zhao and Xuenian Chen from Henan Normal University. Chen is also affiliated with Zhengzhou University.

 

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About Polyoxometalates  

 

Polyoxometalates is a peer-reviewed, international and interdisciplinary research journal that focuses on all aspects of polyoxometalates, featured in rapid review and fast publishing, sponsored by Tsinghua University and published by Tsinghua University Press. Submissions are solicited in all topical areas, ranging from basic aspects of the science of polyoxometalates to practical applications of such materials. Polyoxometalates offers readers an attractive mix of authoritative and comprehensive Reviews, original cutting-edge research in Communication and Full Paper formats, Comments, and Highlight.

 

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Flat, pancake-sized metalens images lunar surface in an engineering first

Penn State-led research team creates the first ultrathin, compact metalens telescope capable of imaging far-away objects

Peer-Reviewed Publication

PENN STATE

A black and white, close up photograph of the moon 

IMAGE: ELECTRICAL ENGINEERING RESEARCHERS CAPTURED IMAGES OF THE LUNAR SURFACE USING THEIR LARGE-APERTURE METALENS TELESCOPE. view more 

CREDIT: XINGJIE NI

UNIVERSITY PARK, Pa. — Astronomers and amateurs alike know the bigger the telescope, the more powerful the imaging capability. To keep the power but streamline one of the bulkier components, a Penn State-led research team created the first ultrathin, compact metalens telescope capable of imaging far-away objects, including the moon. 

Metalenses comprise tiny, antenna-like surface patterns that can focus light to magnify distant objects in the same way as traditional curved glass lenses, but they have the advantage of being flat. Though small, millimeters-wide metalenses have been developed in the past, the researchers scaled the size of the lens to eight centimeters in diameter, or about four inches wide, making it possible to use in large optical systems, such as telescopes. They published their approach in Nano Letters

“Traditional camera or telescope lenses have a curved surface of varying thickness, where you have a bump in the middle and thinner edges, which causes the lens to be bulky and heavy,” said corresponding author Xingjie Ni, associate professor of electrical engineering and computer science at Penn State. “Metalenses use nano-structures on the lens instead of curvature to contour light, which allows them to lay flat.” 

That is one of the reasons, Ni said, modern cellphone camera lenses protrude from the body of the phone: the thickness of the lenses take up space, though they appear flat since they are hidden behind a glass window.

Metalenses are typically made using electron beam lithography, which involves scanning a focused beam of electrons onto a piece of glass, or other transparent substrate, to create antenna-like patterns point by point. However, the scanning process of the electron beam limits the size of the lens that can be created, as scanning each point is time-consuming and has low throughput.  

To create a bigger lens, the researchers adapted a fabrication method known as deep ultraviolet (DUV) photolithography, which is commonly used to produce computer chips.  

“DUV photolithography is a high-throughput and high-yield process that can produce many computer chips within seconds,” Ni said. “We found this to be a good fabrication method for metalenses because it allows for much larger pattern sizes while still maintaining small details, which allows the lens to work effectively.”

The researchers modified the method with their own novel procedure, called rotating wafer and stitching. Researchers divided the wafer, on which the metalens was fabricated, into four quadrants, which were further divided into 22 by 22 millimeter regions — smaller than a standard postage stamp. Using a DUV lithography machine at Cornell University, they projected a pattern onto one quadrant through projection lenses, which they then rotated by 90 degrees and projected again. They repeated the rotation until all four quadrants were patterned.

“The process is cost-effective because the masks containing the pattern data for each quadrant can be reused due to the rotation symmetry of the metalens,” Ni said. “This reduces the manufacturing and environmental costs of the method.” 

As the size of the metalens increased, the digital files required to process the patterns became significantly larger, which would take a long time for the DUV lithography machine to process. To overcome this issue, the researchers compressed the files using data approximations and by referencing non-unique data. 

“We utilized every possible method to reduce the file size,” Ni said. “We identified identical data points and referenced existing ones, gradually reducing the data until we had a usable file to send to the machine for creating the metalens.” 

Using the new fabrication method, the researchers developed a single-lens telescope and captured clear images of the lunar surface — achieving greater resolution of objects and much farther imaging distance than previous metalenses. Before the technology can be applied to modern cameras, however, researchers must address the issue of chromatic aberration, which causes image distortion and blurriness when different colors of light, which bend in different directions, enter a lens. 

“We are exploring smaller and more sophisticated designs in the visible range, and will compensate for various optical aberrations, including chromatic aberration,” Ni said.

In addition to Ni, coauthors include Lidan Zhang, Shengyuan Chang, Xi Chen, Yimin Ding, Md Tarek Rahman and Yao Duan, all current or former Penn State graduate students in electrical engineering. Mark Stephen, from the NASA-Goddard Space Flight Center, also contributed. 

The NASA Early Career Faculty Award, the United States Office of Naval Research and the National Science Foundation supported this work.  

Scientists observe “quasiparticles” in classical systems for the first time

Peer-Reviewed Publication

ULSAN NATIONAL INSTITUTE OF SCIENCE AND TECHNOLOGY(UNIST)

Distinguished Professor Tsvi Tlusty (far right) and his research 

IMAGE: DISTINGUISHED PROFESSOR TSVI TLUSTY (FAR RIGHT) AND HIS RESEARCH TEAM AT THE CENTER FOR SOFT AND LIVING MATTER (CSLM) WITHIN THE INSTITUTE FOR BASIC SCIENCE (IBS). view more 

CREDIT: UNIST

Starting with the emergence of quantum mechanics, the world of physics has been divided between classical and quantum physics. Classical physics deals with the motions of objects we typically see every day in the macroscopic world, while quantum physics explains the exotic behaviors of elementary particles in the microscopic world.

Many solids or liquids are composed of particles interacting with one another at close distances, which sometimes results in the rise of “quasiparticles.” Quasiparticles are long-lived excitations that behave effectively as weakly interacting particles. The idea of quasiparticles was introduced by the Soviet physicist Lev Landau in 1941, and ever since has been highly fruitful in quantum matter research. Some examples of quasiparticles include Bogoliubov quasiparticles (i.e. “broken Cooper pairs”) in superconductivity, excitons in semiconductors, and phonons.

Examining emergent collective phenomena in terms of quasiparticles provided insight into a wide variety of physical settings, most notably in superconductivity and superfluidity, and recently in the famous example of Dirac quasiparticles in graphene. But so far, the observation and use of quasiparticles have been limited to quantum physics: in classical condensed matter, the collision rate is typically much too high to allow long-lived particle-like excitations.

However, the standard view that quasiparticles are exclusive to quantum matter has been recently challenged by a group of researchers at the Center for Soft and Living Matter (CSLM) within the Institute for Basic Science (IBS), South Korea. They examined a classical system made of microparticles driven by viscous flow in a thin microfluidic channel. As the particles are dragged by the flow, they perturb the streamlines around them, thereby exerting hydrodynamic forces on each other. This breakthrough has been jointly led by Group Leader Tsvi Tlusty (Department of Physics, UNIST) and Professor Professor Hyuk Kyu Pak (Department of Physics, UNIST) from CSLM.

Remarkably, the researchers found that these long-range forces make the particles organize in pairs (Figure 1 Left). This is because the hydrodynamic interaction breaks Newton’s third law, which states that the forces between two particles must be equal in magnitude and opposite in direction. Instead, the forces are ‘anti-Newtonian’ because they are equal and in the same direction, thus stabilizing the pair.

The large population of particles coupled in pairs hinted that these are the long-lived elementary excitations in the system — its quasiparticles. This hypothesis was proven right when the researchers simulated a large two-dimensional crystal made of thousands of particles and examined its motion (Figure 1 Right). The hydrodynamic forces among the particles make the crystal vibrate, much like the thermal phonons in a vibrating solid body.

These pair quasiparticles propagate through the crystal, stimulating the creation of other pairs through a chain reaction. The quasiparticles travel faster than the speed of phonons, and thus every pair leaves behind an avalanche of newly-formed pairs, just like the Mach cone generated behind a supersonic jet plane (Figure 1 Right). Finally, all those pairs collide with each other, eventually leading to the melting of the crystal (See Movie).

The melting induced by pairs is observed in all crystal symmetries except for one particular case: the hexagonal crystal. Here, the three-fold symmetry of hydrodynamic interaction matches the crystalline symmetry and, as a result, the elementary excitations are extremely slow low-frequency phonons (and not pairs as usual). In the spectrum, one sees a “flat band” where these ultra-slow phonons condense. The interaction among the flat-band phonons is highly collective and correlated, which shows in the much sharper, different class of melting transition.

Notably, when analyzing the spectrum of the phonons, the researchers identified conical structures typical of Dirac quasiparticles, just like the structure found in the electronic spectrum of graphene (Figure 2). In the case of the hydrodynamic crystal, the Dirac quasiparticles are simply particle pairs, which form thanks to the ‘anti-Newtonian’ interaction mediated by the flow. This demonstrates that the system can serve as a classical analog of the particles discovered in graphene.

“The work is a first-of-its-kind demonstration that fundamental quantum matter concepts – particularly quasiparticles and flat bands – can help us understand the many-body physics of classical dissipative systems,” explains Distinguished Professor Tsvi Tlusty, one of the corresponding authors of the paper.

Moreover, quasiparticles and flat bands are of special interest in condensed matter physics. For example, flat bands were recently observed in double layers of graphene twisted by a specific “magic angle”, and the hydrodynamic system studied at the IBS CSLM happens to exhibit an analogous flat band in a much simpler 2D crystal.

“Altogether, these findings suggest that other emergent collective phenomena that have been so far measured only in quantum systems may be revealed in a variety of classical dissipative settings, such as active and living matter,” says Hyuk Kyu Pak, one of the corresponding authors of the paper.

Their findings have been published in the January 2023 issue of Nature Physics.

Story Source
Materials provided by Institute of Basic Science.

Notes for Editors
The online version of the original article can be found HERE.

Journal Reference
Imran Saeed, Hyuk Kyu Pak, and Tsvi Tlusty, “Quasiparticles, Flat Bands, and the Melting of Hydrodynamic Matter,” Nature Physics, (2023).

Electric vehicle batteries could get big boost with new polymer coating

Scientists enhance lithium-ion battery performance at the atomic level

Peer-Reviewed Publication

DOE/LAWRENCE BERKELEY NATIONAL LABORATORY

Electron Microscope Images 

IMAGE: BERKELEY LAB RESEARCHERS DEMONSTRATED THAT THE HOS-PFM COATING SIGNIFICANTLY PREVENTS ALUMINUM-BASED ELECTRODES FROM DEGRADING DURING BATTERY CYCLING WHILE DELIVERING HIGH BATTERY CAPACITY OVER 300 CYCLES. FROM LEFT: SCANNING ELECTRON MICROSCOPE IMAGES OF ALUMINUM ON A COPPER BILAYER DEVICE BEFORE BATTERY CYCLING (FIGURE A) AND AFTER (FIGURE B). FIGURE C SHOWS A COPPER TRI-LAYER DEVICE WITH HOS-PFM COATING AFTER BATTERY CYCLING. view more 

CREDIT: GAO LIU/BERKELEY LAB. COURTESY OF NATURE ENERGY.

Scientists at Lawrence Berkeley National Laboratory (Berkeley Lab) have developed a conductive polymer coating – called HOS-PFM – that could enable longer lasting, more powerful lithium-ion batteries for electric vehicles. 

“The advance opens up a new approach to developing EV batteries that are more affordable and easy to manufacture,“ said Gao Liu, a senior scientist in Berkeley Lab’s Energy Technologies Area.

The HOS-PFM coating conducts both electrons and ions at the same time. This ensures battery stability and high charge/discharge rates while enhancing battery life. The coating also shows promise as a battery adhesive that could extend the lifetime of a lithium-ion battery from an average of 10 years to about 15 years, Liu added.

To demonstrate HOS-PFM’s superior conductive and adhesive properties, Liu and his team coated aluminum and silicon electrodes with HOS-PFM, and tested their performance in a lithium-ion battery setup. 

Silicon and aluminum are promising electrode materials for lithium-ion batteries because of their potentially high energy storage capacity and lightweight profiles. But these cheap and abundant materials quickly wear down after multiple charge/discharge cycles.

During experiments at the Advanced Light Source and the Molecular Foundry, the researchers demonstrated that the HOS-PFM coating significantly prevents silicon- and aluminum-based electrodes from degrading during battery cycling while delivering high battery capacity over 300 cycles, a performance rate that’s on par with today’s state-of-the-art electrodes. 

The results are impressive, Liu said, because silicon-based lithium-ion cells typically last for a limited number of charge/discharge cycles and calendar life. The researchers recently described these findings in the journal Nature Energy.

The HOS-PFM coating could allow the use of electrodes containing as much as 80% silicon. Such high silicon content could increase the energy density of lithium-ion batteries by at least 30%, Liu said. And because silicon is cheaper than graphite, the standard material for electrodes today, cheaper batteries could significantly increase the availability of entry-level electric vehicles, he added. 

The team next plans to work with companies to scale up HOS-PFM for mass manufacturing. 

The Advanced Light Source and Molecular Foundry are DOE Office of Science user facilities at Berkeley Lab.

The research was supported by DOE Vehicle Technologies Office. The technology is available for licensing by contacting ipo@lbl.gov.

The HOS-PFM conductive binder is made of a nontoxic polymer that transforms at the atomic level in response to heat. Before heating: At room temperature (20 degrees Celsius), alkyl end-chains (black squiggly lines) on the PFM polymer chain limit the movement of lithium ions (red circles). After heating: When heated to about 450 degrees Celsius (842 degrees Fahrenheit), the alkyl end-chains melt away, creating vacant “sticky” sites (blue squiggly lines) that “grab” onto silicon or aluminum materials at the atomic level. PFM’s polymer chains then self-assemble into spaghetti-like strands called “hierarchically ordered structures” or HOS. Like an atomic expressway, the HOS-PFM strands allow lithium ions to hitch a ride with electrons (blue circles). These lithium ions and electrons move in synchronicity along the aligned conductive polymer chains.

CREDIT

Jenny Nuss/Berkeley Lab

Founded in 1931 on the belief that the biggest scientific challenges are best addressed by teams, Lawrence Berkeley National Laboratory and its scientists have been recognized with 16 Nobel Prizes. Today, Berkeley Lab researchers develop sustainable energy and environmental solutions, create useful new materials, advance the frontiers of computing, and probe the mysteries of life, matter, and the universe. Scientists from around the world rely on the Lab’s facilities for their own discovery science. Berkeley Lab is a multiprogram national laboratory, managed by the University of California for the U.S. Department of Energy’s Office of Science.

DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit energy.gov/science.

A better understanding of gas exchange between the atmosphere and ocean can improve global climate models

Peer-Reviewed Publication

WOODS HOLE OCEANOGRAPHIC INSTITUTION

Collecting water samples in the North Atlantic off the coast of Bermuda 

IMAGE: WOODS HOLE OCEANOGRAPHIC INSTITUTION (WHOI) SCIENTIST ALAN SELTZER COLLECTS A WATER SAMPLE IN THE NORTH ATLANTIC OFF THE COAST OF BERMUDA, MAY 2022. BY USING A TECHNIQUE DEVELOPED AT WHOI, SELT-ZER AND COLLEAGUES MADE ULTRA-PRECISE MEASUREMENTS OF DISSOLVED GAS ISOTOPES TO UNRAVEL THE PHYS-ICS OF GAS TRANSFER FROM THE ATMOSPHERE TO DEEP OCEAN. view more 

CREDIT: PHOTO CREDIT: REBECCA TYNE /©WOODS HOLE OCEANOGRAPHIC INSTITUTION.

Woods Hole, Mass. (March 7, 2023) -- The injection of bubbles from waves breaking in turbulent and cold high-latitude regions of the high seas is an underappreciated way in which atmospheric gases are transported into the interior ocean. An improved mechanistic understanding of gas exchange in high latitudes is important for several reasons, including to better constrain climate models that are used to predict changes in the ocean inventory of key gases like oxygen and carbon dioxide.

A new WHOI-led study, “Dissolved gases in the deep North Atlantic track ocean ventilation processes”, published this week in Proceedings of the National Academy of Sciences, combines new geochemical tracers and ocean circulation models to investigate the physics by which atmospheric gases get into the deep ocean. The study uses a new technique to precisely measure noble gas isotopes dissolved in samples of seawater collected from as deep as 4.5 kilometers in the North Atlantic. Noble gases – the elements on the far right-hand side of the periodic table – are unreactive and unused by biology, making them useful tracers of physics.

Noble gases are neither added nor removed from water after the exchange with the atmosphere at the sea-surface. As a result, measuring dissolved noble gases in the deep North Atlantic off the coast of Bermuda tells scientists about the physics of gas exchange that happened in special regions like the Irminger Sea, where the surface ocean becomes dense enough under stormy wintertime conditions to sink and form deep water that slowly flows south.

Alan Seltzer, lead author of the paper, said these new findings suggest that the dissolution of bubbles in the high-latitude ocean “may be the dominant pathway by which all of the noble gases, oxygen, and nitrogen get into the deep ocean.” This study is a step forward toward understanding the basic physics by which gases get into the ocean, said Seltzer, an assistant scientist in the Marine Chemistry and Geochemistry Department at the Woods Hole Oceanographic Institution (WHOI).

“Anything we can do to improve the accuracy of the way models represent our world is helpful, especially when it has to do with gases,” he said. “We care about oxygen for global ecosystems, and we care about CO2 because the ocean is a huge player in taking up our emissions. So if we can improve the way models represent physical processes such as gas exchange, we can have more confidence in future simulations with models as a way of predicting how things will change in a warmer world with more CO2.”

“Understanding how the ocean takes up and releases gases to the atmosphere is a challenging but critically important step toward predicting their response to climate change. Being chemically and biologically inert, noble gases are powerful tools for probing the physical processes involved,” said journal article co-author William Jenkins, an emeritus research scholar in WHOI’s Marine Chemistry and Geochemistry Department. “The Seltzer et al. paper is an important step forward in this journey in that it combines new high-precision noble gas concentration and isotope ratio measurements that are key to unlocking an understanding of these vital processes. Their results also shed light on the oceanic nitrogen cycle, which is both important for climate change issues, but also our fundamental understanding of how ocean food web is supported.”

Measurements for the study come from the Bermuda Atlantic Time Series (BATS) site (31°40 N, 64°10 W), where repeat cruises have surveyed the ocean from top to bottom nearly monthly since 1988. The BATS site is an ideal place to collect samples, because it is located downstream of deep-water formation regions. Deep-ocean noble gas concentrations at the BATS site allow scientists to study gas exchange during wintertime events where the deep ocean  is formed as surface waters cool and become more dense. Under these harsh conditions, direct observations are challenging and scarce, which is why measurements from the deep ocean in warmer, more southern locations are so valuable.

Seltzer said a way to understand why bubbles play such a huge role in transporting noble gases, oxygen, and nitrogen into the deep ocean is to realize that “every time a wave breaks, that massively increases the available surface area for the exchange of gases between the atmosphere and the ocean.”

“The exchange of carbon dioxide and other greenhouse gases between the deep ocean—approximately 75% of the total ocean volume—and the atmosphere occurs at high latitudes during winter, particularly during storm events. Measurements of inert noble gas concentrations in the deep North Atlantic Ocean documented the importance of large bubbles that form during windy storm events, significantly increasing our understanding of the gas exchange rate for the deep water,” said co-author William Smethie, special research scientist and retired research professor at the Lamont-Doherty Earth Observatory of Columbia University. “This improves our ability to quantify the exchange of carbon dioxide and greenhouse gases between the ocean and atmosphere and predict how their atmospheric concentrations will impact the earth’s climate, which is critical for developing policies to mitigate global warming.”

Funding for this research was provided by the U.S. National Science Foundation (NSF) and the UK Natural Environment Research Council. Computing resources were provided by the Climate Simulation Laboratory at the National Center for Atmospheric Research’ Computational and Information Systems Laboratory, sponsored by NSF and other agencies, and by the University of Oxford Advanced Research Computing facility.

Authors: Alan M. Seltzer*1, David P. Nicholson1, William M. Smethie2, Rebecca L. Tyne1, Emilie Le Roy1, Rachel H.R. Stanley1,3, Martin Stute2,4, Peter H. Barry1, Katelyn McPaul1, Perrin W. Davidson1, Bonnie X. Chang5, Patrick A. Rafter6, Paul Lethaby7, Rod J. Johnson7, Samar Khatiwala8, William J. Jenkins1

Affiliations:

1Department of Marine Chemistry and Geochemistry, Woods Hole Oceanographic Institution, Woods Hole, MA, USA

2Geochemistry Department, Lamont-Doherty Earth Observatory, Palisades, NY, USA

3Department of Chemistry, Wellesley College, Wellesley, MA, USA

4Environmental Science Department, Barnard College, New York, NY, USA

5Cooperative Institute for Climate, Ocean, & Ecosystem Studies, University of Washington, Seattle, WA, USA

6Department of Earth System Science, University of California Irvine, Irvine, CA, USA

7Bermuda Institute of Ocean Sciences, St George’s, Bermuda, UK

8Department of Earth Sciences, University of Oxford, Oxford, UK

About Woods Hole Oceanographic Institution

The Woods Hole Oceanographic Institution (WHOI) is a private, non-profit organization on Cape Cod, Massachusetts, dedicated to marine research, engineering, and higher education. Established in 1930, its primary mission is to understand the ocean and its interaction with the Earth as a whole, and to communicate an understanding of the ocean’s role in the changing global environment. WHOI’s pioneering discoveries stem from an ideal combination of science and engineering—one that has made it one of the most trusted and technically advanced leaders in basic and applied ocean research and exploration anywhere. WHOI is known for its multidisciplinary approach, superior ship operations, and unparalleled deep-sea robotics capabilities. We play a leading role in ocean observation and operate the most extensive suite of data-gathering platforms in the world. Top scientists, engineers, and students collaborate on more than 800 concurrent projects worldwide—both above and below the waves—pushing the boundaries of knowledge and possibility. For more information, please visit www.whoi.edu

Key takeaways:

•          If scientists can improve the way models represent physical processes such as gas exchange, they can have more confidence in future simulations with models as a way of predicting how things will change in a warmer world with more CO2.

•          The role of bubbles, which partially dissolve after injection by breaking waves, has been underappreciated as a key mechanism by which gases are transported into the vast ocean interior.

•          The study implements a new technique, developed at WHOI, to precisely measure the isotopes of noble gases in the North Atlantic, which are rare and challenging to measure but offer useful information about physical air-sea gas exchange processes.

•          By pairing new observations of dissolved noble gases in the deep ocean with ocean circulation models, the study is able to estimate the physical signals recorded by other geochemical gas tracers, like nitrogen, in the ocean interior.

•          Using this new understanding of physical gas exchange processes, the authors are able to disentangle biological/chemical signals from physical ones, allowing for the resolution of excess nitrogen in the deep North Atlantic that informs the rate of fixed nitrogen loss, which is crucial for nutrient cycling the global ocean.

 

 

Hollow bones that let dinosaurs become giants evolved at least three times independently

The study analyzed fossilized bones from three Brazilian species of the Late Triassic (about 233 million years ago), the period in which the dinosaurs emerged. All the bones were found in recent decades in Rio Grande do Sul, Brazil’s southernmost state

Peer-Reviewed Publication

FUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO

Air sacs evolved independently in each group 

IMAGE: GNATHOVORAX CABREIRAI WAS A HERRERASAURID, A LINEAGE THAT BECAME EXTINCT NOT LONG AFTER THE PERIOD IN WHICH IT LIVED view more 

CREDIT: ILLUSTRATION: MÁRCIO CASTRO

Dinosaurs as big as buses or five-story buildings would not be possible if their bones were dense and heavy like ours. Like present-day birds, dinosaurs had hollow bones with inner structures known as air sacs, which made their skeletons lighter and less dense. These structures were apparently so advantageous that they emerged at least three times during the evolution of dinosaurs and pterosaurs (flying reptiles), according to a study supported by FAPESP and described in an article in Scientific Reports.

“Less dense bones containing more air gave the dinosaurs and pterosaurs [and still give birds] more oxygen circulating in their blood, as well as more agility to hunt, flee and fight, or even to fly. They not only used less energy but also kept their bodies cool more efficiently,” said Tito Aureliano, first author of the article. The study was part of his PhD research at the State University of Campinas’s Institute of Geosciences (IG-UNICAMP).

Aureliano analyzed fossilized bones from three Brazilian species of the Late Triassic (about 233 million years ago), the period in which the dinosaurs emerged. All the bones were found in recent decades in Rio Grande do Sul, Brazil’s southernmost state.

Detailed knowledge of specimens belonging to different groups and dating from an early stage in their evolution provides a basis for understanding when certain traits were developed. In this case, the researchers were looking for signs of the presence of air sacs, which were commonplace in geologically more recent (and more studied) species, such as tyrannosauruses or velociraptors, and are found in present-day birds, as noted earlier. Air sacs are found in bones throughout the body next to the spinal column.

Computerized tomography was used to visualize the fossils’ internal structures. Small spaces in the vertebrae were identified as foramina for veins, arteries and marrow, and attachment points for muscles and tendons could be seen, but none appeared capable of serving as pneumatic chambers through which air might have flowed continuously. 

“The Triassic was very warm and dry. What’s now Rio Grande do Sul was far from the sea in the heart of the supercontinent Pangea. In that context, more oxygen circulating in the blood would cool the body more efficiently and certainly afford a welcome advantage, so much so that it evolved at least three times independently,” said Fresia Ricardi-Branco, penultimate author of the article, a professor at IG-UNICAMP, and principal investigator for the FAPESP-funded project of which the study was part.

Pneumaticity

The fossils analyzed were found between 2011 and 2019 by researchers at the Federal University of Santa Maria (UFSM) in an area known as Quarta Colônia near Santa Maria in Rio Grande do Sul. Some of those researchers are co-authors of the article. 

The fossils belonged to three species: Buriolestes schultziPampadromaeus barberenai and Gnathovorax cabreirai. The first two were sauropodomorphs, the group of long-necked dinosaurs that became the largest animals to walk the planet. The third was a herrerasaurid, one of the earliest carnivorous dinosaurs. The lineage became extinct shortly after the period in which this specimen lived.

A study published in 2021 by researchers from South Africa, the United Kingdom, the United States and Canada had already shown that another dinosaur lineage, the ornithischians, also lacked structures that could have housed air sacs. This order of dinosaurs probably emerged later, in the Jurassic (between 201 million and 145 million years ago), and included the popular Triceratops. 

The data collected on ornithischians, herrerasaurids and sauropods showed that air sacs evolved independently in each group. “We discovered that no common ancestor had this trait. All three groups must have developed air sacs independently,” Aureliano said.

The other groups that had air sacs were the pterosaurs (including pterodactyls) and the theropods (including tyrannosaurs and velociraptors, as well as extant birds). Although they descended from B. schultzi and P. barberenai, in the long-necked lineage, hollow bones only evolved later. Exactly when is not yet known.

“The oldest dinosaurs in the world are in South America and have been discovered only in the past two decades,” Ricardi-Branco said. “More of this kind of research needs to be done to show how the dominant organisms of the period coped with a much warmer climate than ours.”

About São Paulo Research Foundation (FAPESP)

The São Paulo Research Foundation (FAPESP) is a public institution with the mission of supporting scientific research in all fields of knowledge by awarding scholarships, fellowships and grants to investigators linked with higher education and research institutions in the State of São Paulo, Brazil. FAPESP is aware that the very best research can only be done by working with the best researchers internationally. Therefore, it has established partnerships with funding agencies, higher education, private companies, and research organizations in other countries known for the quality of their research and has been encouraging scientists funded by its grants to further develop their international collaboration. You can learn more about FAPESP at www.fapesp.br/en and visit FAPESP news agency at www.agencia.fapesp.br/en to keep updated with the latest scientific breakthroughs FAPESP helps achieve through its many programs, awards and research centers. You may also subscribe to FAPESP news agency at http://agencia.fapesp.br/subscribe.