Taiwan Light Source (TLS, 1.5 GeV) and Taiwan Photon Source (TPS, 3.0 GeV) are the two synchrotron light sources currently operated by the National Synchrotron Radiation Research Center (NSRRC). There are around 13,000 academic user visits to NSRRC every year; approximately 10% are international.
Called the Laboratory of BioMolecular Structure, the new cryo-electron microscope center will offer world-leading imaging capabilities for life sciences research.
Today, the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory broke ground on the Laboratory of BioMolecular Structure (LBMS), a state-of-the-art research center for life science imaging. At the heart of the center will be two new NY-State-funded cryo-electron microscopes (cryo-EM) specialized for studying biomaterials, such as complex protein structures.
“Cryo-electron microscopy is a rapidly-advancing imaging technique that is posting impressive results on a weekly basis,” said LBMS Director Sean McSweeney. “The mission of LBMS is to advance the scientific understanding of key biological processes and fundamental molecular structures.”
“Throughout my career, I have worked hard to make our region of the State a high-tech hub, bringing together the talents and expertise of scientists and facilities across Long Island. I am pleased to have played a part in the creation of the new cryo-EM center, which will add to the incredible facilities at Brookhaven National Lab and enable our scientific community to lead the way in world-class imaging research and discovery,” said NY State Senator Ken LaValle.
Image: New York State Senator Ken LaValle joined leaders of Empire State Development and Brookhaven Lab for the LBMS groundbreaking ceremony. Pictured from left to right are Jim Misewich (Associate Laboratory Director for Energy and Photon Sciences, Brookhaven Lab), Erik Johnson (NSLS-II Deputy for Construction), Sean McSweeney (LBMS Director and NSLS-II Structural Biology Program Manager), Robert Gordon (DOE-Brookhaven Site Office Manager), Ken LaValle, Cara Longworth (Regional Director, Empire State Development), Danah Alexander (Senior Project Manager, Empire State Development), and John Hill (NSLS-II Director).
The inner workings of a lethal giant freshwater prawn virus have been revealed by an international team of researchers using data gathered at Diamond Light Source. The results reveal a possible new class of virus and presents the prospect of tackling a disease that can devastate prawn farms around the world.
The detailed structure of a virus that can devastate valuable freshwater prawn fisheries has been revealed by an international team using image data collected in the Electron Bio-Imaging Centre (eBIC) based at Diamond Light Source. The researchers produced high-resolution images of virus like particles, VLP’s, composed of virus shell proteins which they compared with lower resolution images of the complete virus purified from prawn larvae. They found strong similarities between the two suggesting that the more detailed VLP images are a good representation of the intact virus. This research, exposing the inner workings of the MrNV, could make it easier to develop ways of combating the economically important disease, but also suggests that it belongs in a new, separate, group of nodaviruses.
The researchers used the rapidly developing technique of cryo-electron microscopy, cryoEM, which has the ability to produce very high-resolution images of frozen virus particles. Images so detailed that the positions of individual atoms could be inferred. Recent breakthroughs in this technique have transformed the study of relatively large biological complexes like viruses allowing researchers to determine their structures comparatively quickly. The data to produce the MrNV structure described here was captured in two days at the eBIC facility.
Image: 3D model of the MrNV
Credit: Dr David Bhella
Soft X-ray experiments used to characterise new thin film topological Dirac Semimetal
A large international collaboration including scientists from Monash University, the ARC Centre for Future Low Energy Electronics (FLEET), the Monash Centre for Anatomically Thin Materials and the Australian Synchrotron reported today in Nature on the development of an advanced material that is able to switch between an electrically conductive state to an insulating state, simply by applying an electric field.
The work represents a step towards the development of a new generation of ultra-low energy electronics at room temperature.
Co-author Dr Anton Tadich, a beamline scientist at the Soft X-ray beamline and Partner Investigator with FLEET, collaborated with investigators from Monash University, Singapore and Lawrence Berkeley National Lab on the use of photoemission techniques at the Australian Synchrotron X-ray Photoelectron Spectroscopy (XPS) and the Advanced Light Source in the US Angle Resolved Photoelectron Spectroscopy, (ARPES).
The chemical composition and growth mechanisms of thin films of the topological Dirac semi-metal sodium bismuthide Na3Bi on a silicon substrate was investigated using XPS at the Australian Synchrotron’s Soft X-ray beamline.
X-ray experiments at Berkeley Lab provide first demonstration of room temperature switching in ultrathin material that could serve as a ‘topological transistor’
Billions of tiny transistors supply the processing power in modern smartphones, controlling the flow of electrons with rapid on-and-off switching. But continual progress in packing more transistors into smaller devices is pushing toward the physical limits of conventional materials. Common inefficiencies in transistor materials cause energy loss that results in heat buildup and shorter battery life, so researchers are in hot pursuit of alternative materials that allow devices to operate more efficiently at lower power.
Now, an experiment conducted at the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) has demonstrated, for the first time, electronic switching in an exotic, ultrathin material that can carry a charge with nearly zero loss at room temperature. Researchers demonstrated this switching when subjecting the material to a low-current electric field.
Image: James Collins, a researcher at Monash University in Australia, works on an experiment at Beamline 10.0.1, part of Berkeley Lab’s Advanced Light Source.
Credit: Marilyn Chung/Berkeley Lab
The 10th December 2018, marks a key date in the history of the ESRF.
Thirty years after the signature of the ESRF Convention, the beam has been stopped for the last time in the original storage ring. Now begins a 20-month shutdown to dismantle the storage ring that has served the international scientific community with bright and reliable X-rays for the last 30 years, to make way for a new and revolutionary X-ray source, the Extremely Brilliant Source (EBS) which will open to users in 2020.
“Today, the EBS project is officially entering a new stage, which is the fruit of our hard work of the last four years. Our imagination, engineering design, quality control and assembly, guided by strict project management, has made it possible to start the swap in our tunnel between the old and the new storage ring. This is possible thanks to the great capability of ESRF staff”, said Francesco Sette, ESRF Director General.
Facility double experiment capacity.
Two additional experiment stations—or instruments—have now started operation at European XFEL. The instruments for Small Quantum Systems (SQS) and Spectroscopy and Coherent Scattering (SCS) welcomed their first user groups for experiments last week and this week respectively. With the successful start of operation of the new instruments, European XFEL has now doubled its capacity to conduct research. With the first three groups coming to the new instruments in 2018, the total number of users who will have visited the facility in 2018 will reach over 500.
The two already operational instruments, SPB/SFX and FXE, have been used to examine biomolecules or biological processes and ultrafast reactions respectively since September 2017. In the future, two of the four now operational instruments will be run in parallel in twelve hour shifts. Two more instruments are scheduled to start user operation in the first half of 2019.
Image: Scientists at the SQS instrument.
Credit: European XFEL / Jan Hosan