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The NSF-DOE Vera C. Rubin Observatory, a major new scientific facility jointly funded by the U.S. National Science Foundation and the U.S. Department of Energy’s Office of Science, released its first imagery today at an event in Washington, D.C. The imagery shows cosmic phenomena captured at an unprecedented scale. In just over 10 hours of test observations, NSF-DOE Rubin Observatory has already captured millions of galaxies and Milky Way stars and thousands of asteroids. The imagery is a small preview of Rubin Observatory’s upcoming 10-year scientific mission to explore and understand some of the universe’s biggest mysteries.

“The NSF-DOE Vera C. Rubin Observatory demonstrates that the United States remains at the forefront of international basic science and highlights the remarkable achievements we get when the many parts of the national research enterprise work together,” said Michael Kratsios, director of the White House Office of Science and Technology Policy. “The Rubin Observatory is an investment in our future, which will lay down a cornerstone of knowledge today on which our children will proudly build tomorrow.”

“NSF-DOE Rubin Observatory will capture more information about our universe than all optical telescopes throughout history combined,” said Brian Stone, performing the duties of the NSF director. “Through this remarkable scientific facility, we will explore many cosmic mysteries, including the dark matter and dark energy that permeate the universe.”

“We’re entering

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Microorganisms with extreme abilities have laid the groundwork for decades of biotechnologies from the PCR technique that enables amplification of DNA for diagnostics and drug development to the gene editing tool CRISPR, and now researchers supported by the U.S. National Science Foundation have found a trove of these microbes in a somewhat unlikely location — the Gowanus Canal in Brooklyn. The team identified more than 450 species with over 60 different biochemical pathways to deal with pollutants and 1,171 genes that can aid in processing heavy metals, offering potential for bio-based and cheaper methods of industrial clean-up, the costs of which are estimated to be more than $645 billion.

The Gowanus Canal is a contaminated waterway in Brooklyn that has high concentrations of petrochemicals and heavy metals. The researchers, including Sergios-Orestis Kolokotronis of the SUNY Downstate Health Sciences University, collected soil samples at 14 locations along the 1.8-mile-long canal and deep sediment core samples and analyzed them using genomic sequencing and bioinformatics. Understanding the genetic sequences and metabolic pathways of the organisms identified will allow researchers to develop faster methods of what the microbes can do naturally.

“We have seen the power of extremophiles used in medicine and industry, and this new analysis expands the biological adaptations we can harness for societal benefit,” said Joanna Shisler, program director in the NSF Directorate for Biological

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The U.S. National Science Foundation Zettawatt-Equivalent Ultrashort pulse laser System (NSF ZEUS) laser facility at the University of Michigan now has the most powerful laser in the U.S., with roughly double the peak power of any other laser in the country. Researchers at NSF ZEUS achieved a laser pulse of two petawatts (2 quadrillion watts) in a brief pulse that lasted 25 quintillionths of a second. In that moment, the laser exceeded the total global output of electrical power by more than 100 times.

The NSF ZEUS laser is available to scientists across the U.S. for experiments in a range of fields, including quantum physics and plasma science with potential applications in medicine, national security, materials science and more.

“The fundamental research done at the NSF ZEUS facility has many possible applications, including better imaging methods for soft tissues and advancing the technology used to treat cancer and other diseases,” said Vyacheslav Lukin, program director in the NSF Division of Physics, which oversees the ZEUS facility. “Scientists using the unique capabilities of ZEUS will expand the frontiers of human knowledge in new ways and provide new opportunities for American innovation and economic growth.”