Lawrence Livermore National Laboratory scientists for the first time have experimentally re-created the conditions that exist deep inside giant planets, such as Jupiter, Uranus and many of the planets recently discovered outside our solar system. Researchers can now re-create and accurately measure material properties that control how these planets evolve over time, information essential for understanding how these massive objects form.
Lawrence Livermore National Laboratory scientists are developing electrode array technology for...
A microbe detection array technology developed by Lawrence Livermore National Laboratory (LLNL)...
Measuring the extreme pressures and temperatures of hydrothermal systems in the Earth's crust is no easy feat. However, Lawrence Livermore National Laboratory scientists have made a new tool that allows them to probe pressures up to 20 kbar (20,000 Earth atmospheres of pressure).
The absorption of petawatt laser light by solid matter is a crucial problem that has been the subject of theoretical and experimental study for more than two decades. In a newly published paper, Lawrence Livermore National Laboratory scientists have defined, for the first time, a set of theoretical boundaries for the absorption of petawatt laser light.
Imagine a material with the same weight and density as aerogel—a material so light it's called “frozen smoke”—but with 10,000 times more stiffness. This material could have a profound impact on the aerospace and automotive industries as well as other applications where lightweight, high-stiffness and high-strength materials are needed.
A biological detection technology developed by Lawrence Livermore National Laboratory scientists can detect bacterial pathogens in the wounds of U.S. soldiers that have previously been missed by other technologies. This advance may, in time, allow an improvement in how soldiers' wounds are treated.
Lawrence Livermore National Laboratory researchers have developed a new and more efficient approach to a challenging problem in additive manufacturing—using selective laser melting, namely, the selection of appropriate process parameters that result in parts with desired properties.
Lawrence Livermore National Laboratory recently received $5.6 million from DARPA to develop an implantable neural interface with the ability to record and stimulate neurons within the brain for treating neuropsychiatric disorders. The technology will help doctors to better understand and treat post-traumatic stress disorder (PTSD), traumatic brain injury (TBI), chronic pain and other conditions.
Earlier this year, Lawrence Livermore National Laboratory engineering technical associate Pam Danforth applied 30 years of laser experience to an out-of-this-world problem—bringing new life to the Univ. of California's Lick Observatory Laser Guide Star. The Lick Observatory's Laser Guide Star is vital to astronomers because a natural guide star isn't always near an object they want to observe.
New research by an international consortium may help physicians better understand the chronological development of a brain aneurysm. Using radiocarbon dating to date samples of ruptured and unruptured cerebral aneurysm tissue, the team, led by neurosurgeon Nima Etminan, found that the main structural constituent and protein—collagen type I—in cerebral aneurysms is distinctly younger than once thought.
Using one of the world's largest telescopes, a Lawrence Livermore National Laboratory team and international collaborators have tracked the orbit of a planet at least four times the size of Jupiter. The scientists were able to identify the orbit of the exoplanet, Beta Pictoris b, which sits 63 light-years from our solar system, by using the Gemini Planet Imager's next-generation, high-contrast adaptive optics system.
Element 117, first discovered by Lawrence Livermore National Laboratory scientists and international collaborators in 2010, is one step closer to being named. The existence of element 117 and its decay chain to elements 115 and 113 have been confirmed by a second international team led by scientists at GSI Helmholtz Centre for Heavy Ion Research, an accelerator laboratory located in Darmstadt, Germany.
In 2010 Lawrence Livermore National Laboratory introduced a new type of electron microscope that could study structural dynamics in condensed matter with the help of a nanosecond laser “pump” that could capture images. In 2013, the laboratory won another R&D 100 Award for speeding up this process more than 100,000 times, resulting in a “movie-mode” version of the instrument.
Using an ultra-fast laser system, a group in Physical and Life Sciences at Lawrence Livermore National Laboratory have subjected iron to extremely rapid dynamic compression and have shown that the transition from one crystal structure to another can take place in less than 100 trillionths of a second after the compression begins.
Glaciers and ice sheets are commonly thought to work like a belt sander. As they move over the land they scrape off everything, including vegetation, soil and even the top layer of bedrock. So a team of university scientists and a NASA colleague were greatly surprised to discover an ancient tundra landscape preserved under the Greenland Ice Sheet, below two miles of ice.
For nearly a century, electrophoretic deposition (EPD) has been used as a method of coating material by depositing particles of various substances onto the surfaces of various manufactured items. Since its earliest use, EPD has been used to deposit a wide range of materials onto surfaces. This process works well, but is limited. EPD can only deposit material across the entire surface and not in specific, predetermined locations, until now.
Joint BioEnergy Institute scientists have identified the genetic origins of a microbial resistance to ionic liquids and successfully introduced this resistance into a strain of E. coli bacteria for the production of advanced biofuels. The ionic liquid resistance is based on a pair of genes discovered in a bacterium native to a tropical rainforest in Puerto Rico.
Lawrence Livermore National Laboratory scientists have modeled actinide-based alloys, such as spent nuclear fuel, in an effort to predict the impact of evolving fuel chemistry on material performance. This work could have direct implications for the use of spent nuclear fuel as another source of energy.
Using the VUV Free-Electron Laser FLASH at Deutsches Elektronen-Synchrotron in Hamburg, Germany, Lawrence Livermore National Laboratory researchers were part of a team that took a sneak peek deep into the lower atmospheric layers of giant gas planets such as Jupiter or Saturn.
Scientists who study past pandemics, such as the 14th-century Black Death that devastated much of Europe, might soon be turning to an innovative biological detection technology for some extra help. The apparent first use of this technology, known as a microarray, for studying pathogens from ancient DNA, was reported by a team of scientists in Scientific Reports.
Lawrence Livermore National Laboratory has joined forces with two other national laboratories—Oak Ridge and Argonne—to deliver next-generation supercomputers able to perform up to 200 peak petaflops, about 10 times faster than today's most powerful high-performance computing (HPC) systems.
Volcanic eruptions in the early part of the 21st century have cooled the planet, according to a study led by Lawrence Livermore National Laboratory. This cooling partly offset the warming produced by greenhouse gases. Despite continuing increases in atmospheric levels of greenhouse gases, and in the total heat content of the ocean, global-mean temperatures at the surface of the planet have shown relatively little warming since 1998.
For the first time, an international team of astrophysicists has unraveled how stars blow up in supernova explosions. Using NASA's Nuclear Spectroscopic Telescope Array (NuSTAR), the international collaboration created the first-ever map of radioactive material in a supernova remnant, named Cassiopeia A. The findings reveal how shock waves likely rip apart massive dying stars, and ultimately end their lives.
Tularemia is endemic in the northeastern U.S., and is considered to be a risk to biosecurity, much like anthrax or smallpox, because it has already been weaponized in various regions of the world. A postdoctoral researcher at Lawrence Livermore National Laboratory has recently described his work to uncover the secrets of the bacterium Francisella tularensis, which causes tularemia, also known as "rabbit fever."
An international team of researchers has demonstrated a new method for studying the structure of proteins that could lead to important advances in biology and other fields. For the first time, protein crystals have been studied in 2-D at room temperature with x-rays, using a new technique that could open the door for scientists to learn more about an important class of proteins that constitute about one-third of all human proteins.
Ignition has long been considered the "holy grail" of inertial confinement fusion science. A key step along the path to ignition is to have "fuel gains" greater than unity, where the energy generated through fusion reactions exceeds the amount of energy deposited into the fusion fuel. Though ignition remains the ultimate goal, the milestone of achieving fuel gains greater than one has been reached for the first time ever on any facility.
A team of physicists have used statistical mechanics and mathematical modeling to shed light on something known as epigenetic memory, which allows an organism to create a biological memory of some variable condition, such as quality of nutrition or temperature. The model highlights the "engineering" challenge a cell must constantly face during molecular recognition.
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