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    Over the past few years, Dr. Sheppard and his team have been performing the largest and deepest survey ever attempted of our Solar System’s fringes. In December 2018, he announced the most-distant object ever observed in our Solar System. His team’s work has shown that the farthest-out-there objects—beyond the Kuiper Belt and the influence of the known major planets—are strangely grouped together in space.

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Strategies for limiting climate change must take into account their potential impact on water quality through nutrient overload, according to a new study from Carnegie’s Eva Sinha and Anna Michalak published by Nature Communications. Some efforts at reducing carbon emissions could actually increase the risk of water quality impairments, they found.

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Climate can play a major role in determining which tree communities will thrive in the harshest conditions, according to new work from Carnegie’s Leander Anderegg and University of Washington’s Janneke Hille Ris Lambers. Their findings are an important step in understanding how forest growth will respond to a climate altered by human activity.

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Heather Meyer, a postdoctoral fellow in David Ehrhardt’s Plant Biology lab since 2016, has been awarded Carnegie’s twelfth Postdoctoral Innovation and Excellence Award. These prizes are given to postdocs for their exceptionally creative approaches to science, strong mentoring, and contributing to the sense of campus community. The nominations are made by the departments and are chosen by the Office of the President.

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Carnegie’s Andrew Steele is a member of the Rensselaer Polytechnic Institute-led Earth First Origins project, which has been awarded a $9 million grant by NASA’s Astrobiology Program. The five-year project seeks to uncover the conditions on early Earth that gave rise to life by identifying, replicating, and exploring how prebiotic molecules and chemical pathways could have formed under realistic early Earth conditions.

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Chris Field is a co-principal investigator of the Jasper Ridge Global Change Experiment at the Jasper Ridge Biological Preserve in northern California. The site, designed to exploit grasslands as models for understanding how ecosystems may respond to climate change, hosts a number of studies of the...
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The Gall laboratory studies all aspects of the cell nucleus, particularly the structure of chromosomes, the transcription and processing of RNA, and the role of bodies inside the cell nucleus, especially the Cajal body (CB) and the histone locus body (HLB). Much of the work makes use of the giant...
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Carbon plays an unparalleled role in our lives: as the element of life, as the basis of most of society’s energy, as the backbone of most new materials, and as the central focus in efforts to understand Earth’s variable and uncertain climate. Yet in spite of carbon’s importance,...
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Broad Branch Road Neighborhood Lectures
Thursday, March 28, 2019 - 6:30pm to 7:45pm

As extreme weather, rising seas, and severe droughts bring home the reality of global climate change, we are increasingly aware of the world’s pressing need for carbon-free energy sources...

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Astronomy Lecture Series
Monday, April 1, 2019 - 7:00pm to 8:45pm

Popular images of galaxies, while beautiful, do not provide the information that astronomers need to measure their inherent properties, such as their dynamics and the compositions of their stars...

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Capital Science Evening Lectures
Tuesday, April 2, 2019 - 6:30pm to 7:45pm

One of our greatest scientific challenges is to effectively understand and make use of the vast amount of data being produced in a variety of fields. Visual data analysis will be among our most-...

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John Mulchaey is the director and the Crawford H. Greenewalt Chair of the Carnegie Observatories. He investigates groups and clusters of galaxies, elliptical galaxies, dark matter—the invisible material that makes up most of the universe—active galaxies and black holes. He is also...
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Leopoldo Infante became the director of the Las Campanas Observatory on July 31, 2017. Since 2009, Infante has been the founder and director of the Centre for Astro-Engineering at the Chilean university. He joined PUC as an assistant professor in 1990 and has been a full professor since 2006. He...
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We are all made of stardust. Almost all of the chemical elements were produced by nuclear reactions in the interiors of stars. When a star dies a fraction of the elements is released into the inter-stellar gas clouds, out of which successive generations of stars form.  Astronomers have a basic...
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March 13, 2019

Carolyn Beaumont, a senior at the Potomac School in McLean VA, won 5th place in the 78th Regeneron Science Talent Search. During the summer of 2018, she worked with Geophysical Laboratory staff members George Cody and Bjorn Mysen on a project to shed light on the molecular details of how water interacts with silicate melts. During her time, she learned how to run all aspects of the experiment, including how to operate a piston cylinder pressure apparatus that generates pressures on the order of 1.5 GPa and temperatures in excess of 1400°C. She also used molecular spectroscopy and nuclear magnetic resonance spectroscopy, to obtain detailed

Aerial view of red tide along Florida’s gulf coast - summer/fall 2018 by Ryan McGill, purchased form Shutterstock
February 26, 2019

Washington, DC—Strategies for limiting climate change must take into account their potential impact on water quality through nutrient overload, according to a new study from Carnegie’s Eva Sinha and Anna Michalak published by Nature Communications. Some efforts at reducing carbon emissions could actually increase the risk of water quality impairments, they found.

Rainfall and other precipitation wash nutrients from human activities like agriculture into waterways. When waterways get overloaded with nutrients, a dangerous phenomenon called eutrophication can occur, which can sometime lead to toxin-producing algal blooms or low-oxygen dead zones called hypoxia.

Subalpine forests of the Colorado Rockies are expected to be strongly affected by climate change. Photo courtesy of Lee Anderegg.
February 25, 2019

Washington, DC— On the mountain slopes of the western United States, climate can play a major role in determining which tree communities will thrive in the harshest conditions, according to new work from Carnegie’s Leander Anderegg and University of Washington’s Janneke Hille Ris Lambers.

Their findings, published in Ecology Letters, are an important step in understanding how forest growth will respond to a climate altered by human activity.

As researchers try to anticipate how climate change will affect forest ecosystems, it is crucial to understand the factors that influence how forest habitats change over time—including both environmental

February 19, 2019

Heather Meyer, a postdoctoral fellow in David Ehrhardt’s Plant Biology lab since 2016, has been awarded Carnegie’s twelfth Postdoctoral Innovation and Excellence Award. These prizes are given to postdocs for their exceptionally creative approaches to science, strong mentoring, and contributing to the sense of campus community. The nominations are made by the departments and are chosen by the Office of the President. The recipients receive a cash prize and are celebrated at an event at their departments.  

Heather initiated a pioneering scientific project to identify the molecular mechanisms that plants use to sense and respond to seasonal temperatures in order to

March 28, 2019

As extreme weather, rising seas, and severe droughts bring home the reality of global climate change, we are increasingly aware of the world’s pressing need for carbon-free energy sources and reliable, affordable energy storage systems.

Already, we’re seeing the forefront of a new energy economy, with Denmark generating almost half of its power through wind energy and California moving toward its goal of operating on 100 percent clean energy by 2045. We also are gaining a deeper, more-nuanced understanding of the highly specific local impacts of pollution from shortened life expectancy to coral reef bleaching. But we still face daunting obstacles in our search for new

April 1, 2019

Popular images of galaxies, while beautiful, do not provide the information that astronomers need to measure their inherent properties, such as their dynamics and the compositions of their stars and gases. Using the latest technological advances, Dr. McGurk is building a new, custom-designed instrument for Carnegie Observatories' Magellan Telescopes, which will reveal the universe in extreme detail–making it possible to efficiently create 3-D maps of galaxies, nebulae, and more.

Dr. Rosalie McGurk: Fellow in Instrumentation, Carnegie Observatories

#GalaxyMap

April 2, 2019

One of our greatest scientific challenges is to effectively understand and make use of the vast amount of data being produced in a variety of fields. Visual data analysis will be among our most-important tools for understanding such large-scale, complex data sets. Visualization facilitates the reasoning process by supporting the human capacity to perceive, understand, and discuss complex data. In this talk, Dr. Johnson will present visual analysis techniques, insights, and examples of how visualization can enable understanding in the fields of biology, astronomy, medicine, and engineering.

He will be joined for a discussion of how data visualization can drive scientific discovery

April 15, 2019

Some meteorites contain rare, tiny grains of dust that formed in the explosions of ancient stars and became part of the gas and dust cloud that formed our Solar System. Dr. Nittler will discuss how he uses microscopic analyses to understand what these “presolar” stellar fossils tell us about the evolution and inner workings of stars, and the chemical history of the matter that became the Sun and planets.

Dr. Larry Nittler: Staff Scientist, Department of Terrestrial Magnetism, Carnegie Science

#StellarFossils

The fund supports a postdoctoral fellowship in astronomy that rotates between the Carnegie Science departments of Terrestrial Magnetism in Washington, D.C., and the Observatories in Pasadena California. 

CALL FOR PROPOSALS

Following Andrew Carnegie’s founding encouragement of liberal discovery-driven research, the Carnegie Institution for Science offers its scientists a new resource for pursuing bold ideas.

Carnegie Science Venture grants are internal awards of up to $100,000 that are intended to foster entirely new directions of research by teams of scientists that ignore departmental boundaries. Up to six adventurous investigations may be funded each year. The period of the award is two

The thyroid gland secretes thyroxine (TH), a hormone essential for the growth and development of all vertebrates including humans. To understand TH action, the Donald Brown lab studies one of the most dramatic roles of the hormone, the control of amphibian metamorphosis—the process by which a tadpole turns into a frog. He studies the frog Xenopus laevis, from South Africa, because it is easy to rear. Events as different as the formation of limbs, the remodeling of organs, and the resorption of tadpole tissues such as the tail are all directed by TH. How can a simple molecule control so many different developmental changes? The hormone works by regulating the expression of groups of

The recent discovery that the universe is expanding at an accelerating rate has profoundly affected physics. If the universe were gravity-dominated then it should be decelerating. These contrary results suggest a new form of “dark energy”—some kind of repulsive force—is driving the universe. To get a grasp of dark energy, it is extremely important that scientists get the most accurate measurements possible of Type Ia supernovae. These are specific types of exploring stars with exceptional luminosity that allow astronomers to determine distances and the acceleration rate at different distances. At the moment, the reality of the accelerating universe remains

Sally June Tracy applies cutting-edge experimental and analytical techniques to understand the fundamental physical behavior of materials at extreme conditions. She uses dynamic compression techniques with high-flux X-ray sources to probe the structural changes and phase transitions in materials at conditions that mimic impacts and the interiors of terrestrial and exoplanets. She is also an expert in nuclear resonant scattering and synchrotron X-ray diffraction. She uses these techniques to understand novel behavior at the electronic level.  Tracy received her Ph.D. from the California Institute of

Scientists simulate the high pressures and temperatures of planetary interiors to measure their physical properties. Yingwei Fei studies the composition and structure of planetary interiors with high-pressure instrumentation including the multianvil apparatus, the piston cylinder, and the diamond anvil cell. 

The Earth was formed through energetic and dynamic processes. Giant impacts, radioactive elements, and gravitational energy heated the  planet in its early stage, melting materials and paving the way for the silicate mantle and metallic core to separate.  As the planet cooled and solidified geochemical and geophysical “fingerprints” resulted from

Juna Kollmeier’s research is an unusual combination—she is as observationally-oriented theorist making predictions that can be compared to current and future observations. Her primary focus is on the emergence of structure in the universe. She combines cosmological hydrodynamic simulations and analytic theory to figure out how the tiny fluctuations in density that were present when the universe was only 300 thousand years old, become the galaxies and black holes that we see now, after 14 billion years of cosmic evolution. 

 She has a three-pronged approach to unravelling the mysteries of the universe. On the largest scales, she studies the intergalactic

Andrew Newman works in several areas in extragalactic astronomy, including the distribution of dark matter--the mysterious, invisible  matter that makes up most of the universe--on galaxies, the evolution of the structure and dynamics of massive early galaxies including dwarf galaxies, ellipticals and cluster. He uses tools such as gravitational lensing, stellar dynamics, and stellar population synthesis from data gathered from the Magellan, Keck, Palomar, and Hubble telescopes.

Newman received his AB in physics and mathematics from the Washington University in St. Louis, and his MS and Ph D in astrophysics from Caltech. Before becomming a staff astronomer in 2015, he was a