Saturday, January 14, 2023

 U$ MILITARY FUNDING AT WORK

Economic impact: Sandia Labs tops $4.2B in spending for first time, added 480 jobs in FY22

Labs’ purchasing power benefits regional, national economies

Business Announcement

DOE/SANDIA NATIONAL LABORATORIES

Economic Impact Graphic 

IMAGE: SANDIA NATIONAL LABORATORIES’ SPENDING FOR FISCAL YEAR 2022 HIT AN ALL-TIME HIGH. view more 

CREDIT: LLOYD WILSON, SANDIA NATIONAL LABORATORIES

ALBUQUERQUE, N.M. — For the first time, Sandia National Laboratories’ contributions to the economy have topped $4.2 billion in a fiscal year, supporting individuals, families and businesses at an unprecedented level. Total spending in fiscal year 2022, which ended Sept. 30, was $312 million more than the previous fiscal year. The spending includes labor, subcontracts, purchases and other expenditures.

Sandia also reported today it created 480 new jobs in fiscal year 2022.

“Sandia has seen steady and significant growth over the last several years, and the numbers show how our communities are growing with us,” said Associate Labs Director Scott Aeilts, in reference to the new 2022 Sandia Economic Impact brochure. “Partnering with businesses, particularly small businesses, helps us accomplish our national security mission and helps communities thrive.”

Of all subcontract-related payments, totaling more than $1.5 billion, nearly $943 million — or about 63% — went to small businesses. Total subcontract-related payments increased $132 million more than the previous fiscal year, with 79% of the increase going to small businesses.

More than 32% of all subcontract-related payments in fiscal year 2022 benefited New Mexico companies. Sandia also paid the state of New Mexico nearly $112 million in gross receipts tax, up more than $4.8 million from the previous fiscal year.

Sandia spent about $491 million with New Mexico businesses in fiscal year 2022. That includes nearly $8.9 million in procurement purchases and more than $482 million in subcontracts within the state. Of the New Mexico subcontracts, nearly $420 million — or 87% — benefited small businesses.

“Strong partnerships with diverse suppliers have been a key to our mission success,” said Labs Director James Peery. “Small businesses promote innovation and help us bring to the marketplace technologies that improve peoples’ lives. Sandia is committed to partnering with and building relationships with highly qualified small businesses to spur economic growth in New Mexico and across the country.”

In addition to spending, labs employment increased by 610 over fiscal year 2021, including 480 new non-student jobs and 130 more student interns, and more than $2.5 billion was spent on labor and non-subcontract related payments. Sandia’s total employment across all sites is 15,500, with the largest labs site, located in Albuquerque, employing nearly 12,600.

Sandia National Laboratories spent more than $1.5 billion on subcontracts in fiscal year 2022 with nearly $943 million going to small businesses. Total subcontract-related payments increased $132 million over fiscal year 2021.

Lloyd Wilson, Sandia National Laboratories

Technology commercialization initiative extended for five more years

In 2022, New Mexico Governor Michelle Lujan Grisham signed into law legislation extending the Technology Readiness Gross Receipts Initiative for five more years. Sandia is a key player in the technology maturation initiative that helps address a critical stage between technology development and commercialization when many companies need additional funding to ready products and services for the marketplace.

The program enabled Sandia to work with 10 companies on 12 projects in 2022, including one that helped IR Dynamics mature a nanoparticle film that could make windows more energy-efficient, using technology invented at Sandia.

Companies acquired 10 licenses for Sandia technologies in fiscal year 2022, and two companies engaged in Cooperative Research and Development Agreements.

Sandia manages several economic development programs that leverage the people, innovations and facilities of the labs to deploy technology in support of Sandia’s mission and job creation.

During calendar year 2022, Sandia provided $2.4 million in technical assistance to 130 small companies through the New Mexico Small Businesses Assistance program.

In the last fiscal year, 104 new patents were issued for Sandia technologies. Sandia additionally filed 223 patent applications and maintained 567 active commercial licenses.

Mentor-Protégé Program expands with addition of two more companies

Sandia grew its small business Mentor-Protégé Program this month from three participating companies to five. Dynamic Structure and Materials, LLC, based in Tennessee, and Pennsylvania-based Compunetics, Inc., joined the program designed to help small businesses develop their ability to compete for federal and industry opportunities.

“We are excited to have our program grow and will continue to look for ways to maximize opportunities for our small business protégés to work with Sandia Labs and the Department of Energy,” said Royina Lopez, Mentor-Protégé Program Lead.

Both companies provide products and services critical to Sandia mission areas. Dynamic Structure and Materials provides precision motion systems and related electronics along with design and manufacturing services. Compunetics manufactures and assembles rigid and flexible printed circuit boards and provides advanced interconnect solutions.

“We value this new relationship as a means to develop as a Department of Energy contractor and intend to harness the resources available through the Mentor-Protégé Program to deliver innovation and an excellent customer experience to Sandia National Labs,” said Dynamic Structure and Materials president Jim Bickmore.

John Gralewski, director of sales at Compunetics, said, “We believe the partnership developed under this program will enhance our growth as a company while also providing a quality supply partner for flex, and rigid-flex printed circuit boards and assemblies to Sandia National Labs.”

Sandia philanthropy supports local families, organizations

Sandia continued to support K-12 educational success and family stability programs throughout Albuquerque and Livermore. In calendar year 2022, National Technology and Engineering Solutions of Sandia contributed $1.4 million on behalf of Sandia to the local communities, including $175,000 in the Livermore area.

Sandia employees generously committed $4.6 million through the United Way of Central New Mexico to nonprofits throughout Albuquerque, Livermore and the nation during the labs’ annual Sandia Gives campaign. Employees donated an additional $103,000, with NTESS providing a $25,000 match donation, to help victims of the historic 2022 New Mexico wildfires, and more than 4,200 retired Sandia computers were donated to New Mexico schools.

Sandia provided STEM programs, including Family Math NightDepartment of Energy Regional Science BowlsSummer Physics Camp for Young Women, and the NM Electric Car ChallengeSTEM in the Sun provided outdoor STEM activities for children attending Albuquerque community center programs.

Sandia exceeds small-business goals

Sandia has met and exceeded small business goals for six consecutive years. The labs focus on working with small businesses that fit the federal categories of small disadvantaged, women-owned, veteran-owned, service-disabled veteran owned and historically underutilized business zone, also called HUBZone.

“Sandia is motivated to partner with small businesses with a variety of skills and expertise to promote innovation in support of our mission. We have teams dedicated to helping interested suppliers navigate the rewarding but sometimes unfamiliar path of working with a national laboratory,” said Laura Lovato, Sandia’s manager of supplier diversity and supply chain risk management.

Through various efforts, Sandia worked with 500 small businesses during fiscal year 2022 that hadn’t supported the labs before.

For more information on doing business with Sandia, visit the procurement website or email supplier@sandia.gov with questions.


Sandia National Laboratories is a multimission laboratory operated by National Technology and Engineering Solutions of Sandia LLC, a wholly owned subsidiary of Honeywell International Inc., for the U.S. Department of Energy’s National Nuclear Security Administration. Sandia Labs has major research and development responsibilities in nuclear deterrence, global security, defense, energy technologies and economic competitiveness, with main facilities in Albuquerque, New Mexico, and Livermore, California.

VIMS research helps clarify role of water clarity in coastal management

Choice of water-clarity metrics impacts management of seagrasses and other light-loving organisms

Peer-Reviewed Publication

VIRGINIA INSTITUTE OF MARINE SCIENCE

Secchi disc 

IMAGE: DR. JESSIE TURNER DEPLOYS A SECCHI DISC INTO THE YORK RIVER FROM THE SEAWATER RESEARCH LAB PIER AT THE VIRGINIA INSTITUTE OF MARINE SCIENCE. © DAVID MALMQUIST/VIMS. view more 

CREDIT: DAVID MALMQUIST

Secchi disks & light sensorsWater clarity is key to the health and restoration of marine plants and animals worldwide, particularly in shallow coastal systems such as the Chesapeake Bay. But it turns out that measuring water clarity isn’t as clear-cut as it might appear.

Research at the Virginia Institute of Marine Science led by Dr. Jessie Turner reveals that the “clarity” of a water parcel depends on the method used to measure it, and that different research questions and management decisions merit different clarity-measuring tools and techniques. Turner and her co-authors, Drs. Kelsey Fall and Carl Friedrichs, lay out their recommendations in a recent article in Limnology and Oceanography Letters

“In coastal and inland waters,” says Turner, “the methods we use to gauge water clarity can misrepresent the underwater light climate used to determine restoration goals, such as the potential habitat available for underwater grasses. It’s thus really important to choose the most appropriate measurement method, and to clearly communicate the method used. Not all water-clarity metrics are created equal.”

Underwater grasses serve many key ecological functions and are among the most closely monitored habitats in the Bay. They provide food and shelter for numerous marine species, help oxygenate the water, and can mitigate global warming by removing carbon dioxide from the air. To do so, they need clear water for photosynthesis and growth. Their dependence on clear water makes them a “canary in the coal mine” for water clarity in shallow coastal systems.

Turner (VIMS Ph.D. ’21) is currently a postdoctoral research associate at the University of Connecticut. Fall (VIMS Ph.D. ’20) is now at the U.S. Army Engineer Research and Development Center in Vicksburg, Mississippi. Friedrichs is Glucksman Professor in William & Mary’s School of Marine Science at VIMS and Associate Director of the Chesapeake Bay National Estuarine Research Reserve in Virginia.

Water and beer

To explain the complexities of water clarity and its measurement, Turner turns to an analogy with beer—another liquid whose “clarity” is of widespread interest. Ironically, the scientific principle used to define the clarity of beer and other liquids is known as Beer’s Law (ironic as the principle was first applied to wine, not beer, and doubly so as the law is named after German chemist August Beer, not the hoppy beverage).

“Beer's Law tells us that how much light gets through a liquid depends on the concentration of stuff in the liquid and the distance over which you're measuring,” says Turner. 

What’s the “stuff?” “In beer,” she says, “it’s either particles like yeast and hops, or dissolved things like sugar or tannins from the brewing process. In Chesapeake Bay, the “stuff” can be particles such as tiny pieces of dirt and microscopic plants, or dissolved organic matter and other solutes.” Dissolved organic matter is an earthy tea steeped from leaf litter, crop residue, soil, and other carbon-based materials from the Bay and its watershed.

Crucially, particulate matter and dissolved substances impede light in different ways. “When light hits water or beer it can either get scattered, or it can get absorbed,” says Turner. “Particles scatter light, dissolved substances absorb light.”

The relative abundances of particulate and dissolved materials combine to produce different light environments. In areas of Chesapeake Bay with high levels of both light-scattering particles and light-absorbing solutes, the water is dark like a stout. In areas with lots of light-scattering particles but few light-absorbing solutes, the water is cloudy yet bright, like a hazy ale. Areas with few particles or solutes are clearest, like a cider.

Secchi disks & light sensors

These differences have important ramifications when considered in light of the multiple tools and techniques scientists use to measure water clarity. Two common optical tools are Secchi disks and light sensors. Scientists also directly measure the concentration of suspended particles, dissolved materials, and chlorophyll (the pigment that plants and plankton use to capture sunlight for photosynthesis).

“A Secchi disc is a simple black-and-white disc that you lower horizontally through the water,” explains Turner. “The depth at which it disappears from view is known as the Secchi depth.” This cheap, easy-to-deploy, and long-used tool measures water transparency and the depth of object visibility. 

Light sensors measure the loss or attenuation of sunlight as it penetrates deeper into the water, with a focus on the wavelengths plants use for photosynthesis. Recorded values are compared to those collected by a surface sensor to account for differences in incoming light due to clouds and time of day. 

Though advances in electronics and materials have reduced the cost and increased the use of light sensors, Secchi discs remain the everyday workhorse of many water-clarity studies, both by professional researchers and a growing cadre of community scientists.

Problems arise, according to Turner and her co-authors, when practitioners apply a traditional one-size-fits-all equation to estimate light attenuation from Secchi depth values. That’s because the relationship between these two metrics can vary greatly depending on the local light climate—whether an underwater study site is dark like a stout, bright yet cloudy like an ale, or clear like a cider.

“The relationship between these two metrics can vary widely between and within estuaries and other aquatic environments based on latitude, hydrology, and climate,” says Turner. “Using a single conversion factor to estimate light attenuation based on Secchi depth can thus either under- or overestimate the underwater light climate.”

For example, in the turbid waters of the York River, a major Chesapeake Bay tributary, use of the traditional conversion factor would underestimate the light available for seagrasses, and thus short-sell potential restorations targets.

Recommendations

To counter this and related difficulties, Turner and colleagues recommend several changes in how water clarity is measured and reported. Most important is to clearly communicate the method used—whether a Secchi depth from a Secchi disk, light attenuation, or another method.

For studies related to underwater grasses and other light-loving organisms, the authors advise colleagues to collect light-attenuation values directly.

“Measures of light attenuation with depth are most relevant for most research in aquatic ecosystems,” says Turner. “They are well-suited to research involving underwater grasses, kelp, and corals, as these and other similar organisms are adapted to harvest downwelling light.” The authors recommend use of a separate, “scalar” measure of light attenuation when studying phytoplankton, which as floating organisms can harvest light from all directions, both downwelling and scattered from the side and below.

If cost concerns or other factors encourage use of Secchi discs, the authors advise researchers to forgo use of the traditional one-size-fits-all equation, recommending instead they calibrate the Secchi-depth to light-attenuation formula using localized measures. “The equation needs to be locally calibrated because the characteristics of the water’s dissolved and particulate matter vary greatly, sometimes over very short distances,” says Turner. “These characteristics can also vary seasonally.”

Because Secchi depth values measure visibility and transparency, the authors say their direct application is most appropriate for studies of fish and other visual predators. They note they are also of value in a human context, in areas such as in-water recreation and the value of coastal property and viewscapes.

Whatever methods a research team might use, the authors urge them to select the most useful metric or metrics according to the specific research question or management goal.

“When relevant to the goal,” says Turner, “even the simplest water clarity measurements are valuable for environmental monitoring and restoration, whether collected by scientific sampling programs, non-profit organizations, or community scientists.”

Smaller fishes in the deep ocean to be expected with ocean warming

This is the main conclusion of a new study involving the ICM-CSIC based on the analysis of fish otoliths found in geological formations dating back 700-800 thousand years

Peer-Reviewed Publication

INSTITUT DE CIÈNCIES DEL MAR (ICM-CSIC)

A new study led by the University of Vienna in which the Institut de Ciències del Mar (ICM-CSIC) has participated reveals that fishes living in the dark part of the oceans (essentially below 200 m depth in the water column) would likely decrease in size with climate warming, which may have important ecological effects.

The details of this research are reported in an article published today in Proceedings of the Royal Society B. For its preparation, the authors retrieved fish otoliths — small stones in the inner ear of bony fishes that facilitate the fishes’ sound and balance perception — from sedimentary formations dated 800–700 thousand years ago from the island of Rhodes in the Aegean Sea and measured them to track changes in fishes’ body size through glacial and interglacial periods.

The morphology of these structures is particular to each fish species and their size directly reflects the size of the fish individual they come from, which allows researchers to identify them in order to reconstruct past fish faunas.

“Thanks to the otolith analysis we have found that fishes during the interglacial period were smaller in size by 35%, when the global temperature had increased by 4 °C, which could happen again nowadays due to the ocean warming”, explains the leading author of the study, Konstantina Agiadi, from the University of Vienna.

Small fishes, big impacts

The study, that is one of the few works that have so far addressed the consequences of climate warming on the deeper part of the oceans, the mesopelagic zone (200–1000 m depth), focused on the changes in “lanternfishes”, a group of small mesopelagic fishes that are named for their capacity to produce their own light.

“Knowing the response of these organisms to ocean warming is key, since they contribute to ecosystem stability, reduce atmospheric carbon dioxide, and are a huge food resource for other organisms in the marine food web”, explains the ICM-CSIC researcher and co-author of the study Marta Coll, who adds that “these fish make up more than half the fish biomass in the deep sea, and about 100 times more than the total global annual fishery catches”.

Lately, lanternfishes are important contributors to the biological carbon pump, a natural mechanism for reducing atmospheric carbon dioxide (CO2). Initially, phytoplanktonic organisms absorb CO2 from the atmosphere through photosynthesis. Then, every night, lanternfishes travel hundreds of meters upward to the surface of the oceans and return to the mesopelagic zone, thus bringing huge amounts of carbon from the surface to the deep ocean.

AND WHERE TO AVOID PUTTING WINDTURBINES

New map of “stopover hotspots” provides insights for conservation of eastern US migratory landbirds

Peer-Reviewed Publication

PRINCETON SCHOOL OF PUBLIC AND INTERNATIONAL AFFAIRS

Every autumn, billions of birds migrate across the eastern U.S. en route to their wintering sites. As the birds undertake their journeys, however, they are faced with increasing threats, including habitat loss, storms, feral cats and other predators, pesticides, collisions with buildings, and climate change. Not only are individual species impacted by these threats, but so is the migratory phenomenon itself.

A new study published in the journal Proceedings of the National Academy of Sciences presents the first comprehensive map of autumn stopover hotspots of landbirds for the eastern United States. Stopover sites are locations where birds pause between migratory flights in order to rest and refuel before resuming their journeys. The new map created by the researchers can inform where conservation efforts would be most effective.

“This is the first time we’ve had a comprehensive picture of where songbirds are stopping over for the entirety of the eastern United States,” said David Wilcove, professor of Public Affairs and Ecology and Evolutionary Biology and the High Meadows Environmental Institute and a co-author on the study. “It gives us a powerful new tool for identifying the key habitats these birds are using during their epic migrations,” Wilcove said.

The researchers used data collected from a national network of weather radar stations to identify “stopover hotspots,” or sites that consistently support a high number of migratory birds year to year. Weather radar images capture not only precipitation but also migrating birds, but separating the birds from the precipitation (and other things) requires a great deal of image processing.

The study finds that landbirds migrate across a broad front through the eastern United States, with relatively more birds following the Mississippi River and, to a lesser extent, the Appalachian Mountains. By examining the migration at finer spatial scales, the researchers were able to identify hotspots that support high densities of birds from year to year on their migratory journeys.

The study also reports that at these finer scales, there are high concentrations of birds in the pockets of broadleaf forests remaining in areas that have been largely deforested to grow crops, such as the Midwest. Previously, these forest fragments were seen as having relatively little value for songbirds because they do not generally support large populations of them during the breeding season. But during the fall migration, they become important rest and refueling spots.

“Small pockets of deciduous forest are often neglected in conservation planning because birds have low breeding success in these spaces,” said Fengyi Guo, lead author of the study and a PhD candidate in the department of Ecology and Evolutionary Biology at Princeton University. “But the entire population moves across the continent twice annually. Many of them depend on food and shelter in these forest pockets to complete their migration” Guo said.

Another novel finding is that there are high concentrations of birds in the forests along the edge of the Midwest prairie region, now largely converted to farmland, suggesting that these farmlands may be an obstacle for migratory birds and that the birds are avoiding stopping over in the prairies until they reach more forested places, which provide more suitable habitat for them.

Taken together, the study suggests that a network of protected forested land distributed across the eastern US is key to maintaining healthy populations of migratory landbirds. The authors urge the protection of broadleaf forests, especially the remaining forests in the agriculturally dominated Midwest. Locally based conservation efforts across the eastern U.S. will be key to protecting bird species along their migratory journeys.

“A chain is only as strong as its weakest link. Successful conservation of migratory bird populations requires enough habitat to be protected at all stages of its annual cycle,” Guo said.

The paper, “Autumn stopover hotspots and multiscale habitat associations of migratory landbirds on the eastern U.S.,” was published January 9, 2023 in PNAS. The authors of the report are Fengyi Guo and David Wilcove (Princeton University) and Jeffrey Buler and Jaclyn Smolinsky (University of Delaware). The research was supported by the High Meadows Foundation and USDA NIFA Hatch.

Toxic toilet paper and long-lasting chemicals found in endangered killer whales

Peer-Reviewed Publication

UNIVERSITY OF BRITISH COLUMBIA

A chemical used in the production of toilet paper and 'forever chemicals' have been found in the bodies of orcas in B.C. , including the endangered southern resident killer whales.

The Institute for the Ocean and Fisheries at UBC, British Columbia Ministry of Agriculture and Food, and Fisheries and Oceans Canada scientists analyzed tissue samples from six southern resident killer whales and six Bigg’s whales stranded along the coast of B.C. from 2006 to 2018, according to a recent study. They discovered that chemical pollutants are prevalent in killer whales, with a chemical often found in toilet paper one of the most prevalent in the samples studied, accounting for 46 per cent of the total pollutants identified.

Called 4-nonylphenol or 4NP, the compound is listed as a toxic substance in Canada and can interact with the nervous system and influence cognitive function, the authors say. “This research is a wake-up call. Southern residents are an endangered population and it could be that contaminants are contributing to their population decline. We can’t wait to protect this species,” said co-author Dr. Juan José Alava, principal investigator of the ocean pollution research unit at the Institute for the Oceans and Fisheries (IOF).

4NP is often used in pulp and paper processing, as well as in soap, detergents and textile processing. It can leak into the ocean via sewage treatment plants and industrial runoffs, where it is ingested by smaller organisms and moves up the food chain to reach top predators such as killer whales. It’s known as a ‘contaminant of emerging concern’ or CEC, which are pollutants found in the environment that are not well-studied and so, regulated. “Very little is known of both the prevalence and health implications of 4NP as it has been studied in few marine mammals. This study is the first to find 4NP in killer whales,” said first author Kiah Lee, who undertook the research as an undergraduate at UBC.

“This investigation is another example of an approach that takes into account the health of people, animals and the environment, using killer whales as a case study to better understand the potential impacts of these and other compounds to animal and ecosystem health,” said co-author Dr. Stephen Raverty, IOF adjunct professor and veterinary pathologist with the B.C. Ministry of Agriculture and Food.

‘Forever chemicals’

Just over half the pollutants identified by the researchers belong to a group of compounds known as ‘forever chemicals’ because they last for a long time in the environment. They are widely used in food-packaging materials, stain and water-repellent fabrics, cookware, and fire extinguishers. Many are listed as new Persistent Organic Pollutants (POPs). These are toxic substances released into the environment through human activities that adversely affect the health of humans and animals. Many are banned in Canada.

The most common pollutant of this group the researchers found was 7:3-fluorotelomer carboxylic acid, or 7:3 FTCA. There are currently no restrictions on the production and use of 7:3 FTCA but one of its potential parent chemicals is on a list of toxic substances proposed to be recognized as new POPs by the European Chemical Agency under an international agreement, the Stockholm Convention on POPs.

“This compound has not been found in B.C. before and it was found in killer whales, which are top predators. That means the contaminants are making their way through the food system,” says Dr. Alava.

Mother-to-fetus transfer

The researchers were also the first to look at the transfer of pollutants from mother to fetus in one southern resident pair. They found that all the pollutants identified were transferred in the womb, and 95 per cent of 4NP transferred from mother to fetus.

Governments can help protect the southern residents and other marine life by halting production of the chemicals of concern, including 4NP and emerging POPs like 7:3 FTCA, as well as identifying and addressing potential sources of marine pollution in B.C. and Canada.

It's not just the killer whales that are affected, said Dr. Alava. “We are mammals, we eat Pacific salmon as well, so we need to think about how this could affect our health as well as other seafood that we consume.”

This research was supported by funding from the Department of Fisheries, the UBC Student Undergraduate Research Experience and the Nippon Foundation.

Fossils reveal dinosaurs of prehistoric Patagonia

Peer-Reviewed Publication

UNIVERSITY OF TEXAS AT AUSTIN

Prehistoric Patagonia 

IMAGE: A TIME-AVERAGED ARTIST’S INTERPRETATION OF PATAGONIA DURING THE LATE CRETACEOUS. THE ANIMALS PICTURED INCLUDE NON-AVIAN DINOSAURS, BIRDS AND OTHER VERTEBRATES THAT HAVE BEEN DISCOVERED IN THE FOSSIL RECORD OF THE REGION. THEIR SPECIFIC IDENTIFICATIONS ARE AS FOLLOWS: ORNITHURINE BIRDS (FLYING AND WALKING ON THE GROUND), STEGOUROS (ARMORED DINOSAUR), ORRETHERIUM (MAMMAL), YAMINUECHELYS (TURTLE), A MEGARAPTORID (LARGE CARNIVORE), UNENLAGIINES (PAIR OF CARNIVORES), AND ENANTIORNITHINE BIRDS (IN FOREGROUND) view more 

CREDIT: MAURICIO ALVAREZ AND GABRIEL DIAZ

A study led by The University of Texas at Austin is providing a glimpse into dinosaur and bird diversity in Patagonia during the Late Cretaceous, just before the non-avian dinosaurs went extinct.

The fossils represent the first record of theropods — a dinosaur group that includes both modern birds and their closest non-avian dinosaur relatives — from the Chilean portion of Patagonia. The researchers’ finds include giant megaraptors with large sickle-like claws and birds from the group that also includes today’s modern species.

“The fauna of Patagonia leading up to the mass extinction was really diverse,” said lead author Sarah Davis, who completed this work as part of her doctoral studies with Professor Julia Clarke at the UT Jackson School of Geosciences Department of Geological Sciences. “You’ve got your large theropod carnivores and smaller carnivores as well as these bird groups coexisting alongside other reptiles and small mammals.”

The study was published in the Journal of South American Earth Sciences.

Since 2017, members of the Clarke lab, including graduate and undergraduate students, have joined scientific collaborators from Chile in Patagonia to collect fossils and build a record of ancient life from the region. Over the years, researchers have found abundant plant and animal fossils from before the asteroid strike that killed off the dinosaurs.

The study focuses specifically on theropods, with the fossils dating from 66 to 75 million years ago.

Non-avian theropod dinosaurs were mostly carnivorous, and include the top predators in the food chain. This study shows that in prehistoric Patagonia, these predators included dinosaurs from two groups — megaraptors and unenlagiines.

Reaching over 25 feet long, megaraptors were among the larger theropod dinosaurs in South America during the Late Cretaceous. The unenlagiines — a group with members that ranged from chicken-sized to over 10 feet tall — were probably covered with feathers, just like their close relative the velociraptor. The unenlagiinae fossils described in the study are the southernmost known instance of this dinosaur group.

The bird fossils were also from two groups — enantiornithines and ornithurines. Although now extinct, enantiornithines were the most diverse and abundant birds millions of years ago. These resembled sparrows — but with beaks lined with teeth. The group ornithurae includes all modern birds living today. The ones living in ancient Patagonia may have resembled a goose or duck, though the fossils are too fragmentary to tell for sure.

The researchers identified the theropods from small fossil fragments; the dinosaurs mostly from teeth and toes, the birds from small bone pieces. Davis said that the enamel glinting on the dinosaur teeth helped with spotting them among the rocky terrain.

Some researchers have suggested that the Southern Hemisphere faced less extreme or more gradual climatic changes than the Northern Hemisphere after the asteroid strike. This may have made Patagonia, and other places in the Southern Hemisphere, a refuge for birds and mammals and other life that survived the extinction. Davis said that this study can aid in investigating this theory by building up a record of ancient life before and after the extinction event.

Study co-author Marcelo Leppe, the director of the Antarctic Institute of Chile, said that these past records are key to understanding life as it exists today.

“We still need to know how life made its way in that apocalyptic scenario and gave rise to our southern environments in South America, New Zealand and Australia,” he said. “Here theropods are still present — no longer as dinosaurs as imposing as megaraptorids — but as the diverse array of birds found in the forests, swamps and marshes of Patagonia, and in Antarctica and Australia.”

The research was funded by the National Science Foundation, the National Agency for Research and Development of Chile, and the Jackson School of Geosciences.

The study’s co-authors include Clarke and researchers at the University of Chile, Major University, the University of Concepción and the Chilean National Museum of Natural History.

A figure from the study showing teeth from a megaraptor dinosaur from various view points. The black tooth preserves most of the tooth crow. The tan tooth is missing the crown apex and base.

CREDIT

Davis et al.

The researchers in Patagonia in 2017. Lead author Sarah Davis is in the center of the front row in a blue jacket. The researchers include members from the Jackson School of Geosciences, INACH, the University of Chile, and the University of Concepción.

CREDIT

Sarah Davis

Offshore and coastal risk analyses may misrepresent wave storms from extreme weather like bomb cyclones

A new study shows that models used across the globe to estimate the height of coastal storm waves — critical information when building ports, reinforcing infrastructure and estimating flooding — can differ by several feet

Peer-Reviewed Publication

UNIVERSITY OF CENTRAL FLORIDA

A new study shows that models used across the globe to estimate the height of coastal storm waves — critical information when building ports, reinforcing infrastructure and estimating flooding — can differ by several feet.

ORLANDO, Jan. 12, 2023 – Extreme weather events, such as the storm waves generated by the cyclone that recently moved across California, may be underestimated in many models used to estimate coastal flooding, according to a new study led by University of Central Florida researchers.

The study, which was published this week in the journal Science Advances, shows that models used across the globe to estimate the height of coastal storm waves —critical information when building ports, reinforcing infrastructure and estimating flooding — can differ by several feet, leading to some areas being possibly under protected during extreme wave events.

The first-of-its-kind study compared wave estimates from 12 global models with historical buoy observations across different ocean areas.

It found that existing models can reliably represent historical buoy observations across many areas, but no model performs well everywhere and estimates of extreme wave heights can vary between models by up to approximately 20 feet at places.

The study shows that such discrepancies largely exceed current projected 21st changes in coastal extreme wave storm events under a high-emission scenario (9 degrees Fahrenheit in warming by 2100).

“Extreme wave events pose a major risk to offshore-coastal infrastructure and can dramatically affect global coastlines and natural ecosystems through widespread flooding and erosion,” says Joao Morim, a coastal climate researcher in UCF’s Department of Civil, Environmental, and Construction Engineering and the study’s lead author. “Understanding their magnitude and frequency for today’s climate is required for offshore and coastal designs and risk assessments, and it’s essential to assess potential future changes.”

Morim says due to a lack of observations with global coverage, wave models are typically used for many different applications, such as coastal flood risk assessments.

 “We show that depending on the product used, estimated flooding can vary by several feet,” Morim says.

The researchers found that to more accurately assess offshore and coastal risk and inform future mitigation and adaptation responses, decision and policy makers must account for differences between global wave models and take into account observation measurements based on today’s climate.

This means considering different models and using additional, modern observational data to better constrain extreme wave estimates under current climate conditions.

This should be done before considering changes due global warming and sea level rise, which is the main focus of many of the current global and regional flood risk assessments, the researchers say.

The additional data could include long-term observational records from satellite missions and more data from buoys.

“I feel that our results provide a clear message that published broad-scale offshore and coastal risk assessments for present and future climate using extreme wave data taken from specific global and regional wave model products can be misleading and need to consider multiple products to fully assess offshore-coastal impacts and make robust conclusions,” Morim says.

“The results, which are surprising given that current differences between models can differ by several feet, show that we need to consider uncertainties in extreme wave event estimates for today’s climate while also addressing projected future changes due to global climate change,” he says.

For Florida, there are considerable uncertainties concerning wave flooding estimates for the west coast of the state, stemming from the wave models analyzed and the discrepancies between them, which partly result from their different ability in resolving extremes wave storms due to tropical cyclone, the study shows.

“We feel that our research improves our current knowledge and makes a clear point that no uncertainty can be neglected when considering global and regional adaptation,” Morim says.

Study co-authors were Thomas Wahl, an associate professor in UCF’s Department of Civil, Environmental and Construction Engineering; Sean Vitousek with the Pacific Coastal Marine Science Center, U.S. Geological Survey; Sara Santamaria-Aguilar, a postdoctoral researcher in UCF’s Department of Civil, Environmental, and Construction Engineering;  Ian Young with the Department of Infrastructure Engineering, University of Melbourne, Parkville, Victoria; and Mark Hemer with the Commonwealth Scientific and Industrial Research Organisation (CSIRO) Oceans and Atmosphere, Hobart, Tasmania, Australia.

The research was funded with support by the UCF Pre-eminent Postdoctoral Program; the NASA Sea Level Change Team; the U.S. National Science Foundation; the U.S. Geological Survey; the Australian Research Council; the Australian Commonwealth National Environmental Science Program and CSIRO’s Climate Science Centre.

Morim received his doctorate in climate change and coastal risk from Griffith University on the Gold Coast, Queensland, Australia. He joined UCF in 2021.

Wahl earned his doctorate in civil engineering from the University of Siegen, Germany, and joined UCF’s Department of Civil, Environmental and Construction Engineering, part of UCF’s College of Engineering and Computer Science, in 2017. He is also a member of UCF’s National Center for Integrated Coastal Research and Sustainable Coastal Systems faculty cluster.

Study title: Understanding uncertainties in contemporary and future extreme wave events for broad-scale impact and adaptation planning

CONTACT: Robert H. Wells, Office of Research, robert.wells@ucf.edu