Exploiting high speed light for super slow science
Scientists at the world's premier science conference – the American Association for the Advancement of Science (AAAS) annual meeting – will this year be discussing the advances enabled by the UK's pioneering Long-Duration Experiment facility (LDE). Unmatched anywhere in the world, the LDE allows scientists to closely study the atomic and molecular behaviour of matter under different conditions and over a period of two years.
Based at the UK's synchrotron science facility, Diamond Light Source, the LDE exploits powerful synchrotron light — which is 10 billion times brighter than the sun — to penetrate to the heart of matter. But unlike Diamond's 25 other experimental stations, the LDE allows scientists to study the behaviour of material as it changes over an extended period of time, meaning that experiments can last not hours or days, but months or years.
Prof Trevor Rayment, Diamond's Director of Physical Sciences, "Historically, synchrotrons have been racing to provide scientists with experimental tools that glean rapid results. On some of our beamlines, we can now study hundreds or even thousands of samples each day. In areas like structural biology this is vitally important and super fast experiments have become quite routine at Diamond. However, we know that many scientific problems actually call for research to happen on super slow timescales and, counterintuitively, this research is actually much harder to plan for and to succeed in. Diamond's new LDE facility is already helping researchers to conduct long term experiments, focusing on areas such as making better batteries, improving the effectiveness of drugs in hot climates, and testing cement that can be used in the disposal of radioactive materials in the UK's planned geological disposal facility (GDF)."
The LDE is a unique facility and a resource designed to address problems that simply cannot be solved anywhere else. Diamond's synchrotron light illuminates samples around 1000 times better than laboratory microscopes. As well as providing an in-depth insight into materials over an extended period, the LDE can also be tailored to specific temperature or levels of humidity, meaning that scientists can assess material's long-term behaviours in varied environments.
The long-term behaviour of materials has never been studied in this level of detail before, and the facility is revealing new insights into how materials interact on the atomic scale under different conditions and over time.
One of the key projects currently taking place at this world-leading facility is looking into the long-term behaviour of nuclear waste cement as it gradually becomes hydrated by water. This work, led by Dr Claire Corkhill from the University of Sheffield's NucleUS research group, could be vital to informing the UK's strategy on radioactive waste disposal.
Claire explains: "The UK government plans to bury the most dangerous form of its radioactive waste in a geological disposal facility deep underground – somewhere between 200 and 1000 metres under the surface. To put this in context, the London Underground at its deepest is only 65 metres down.
"But because it can take hundreds of thousands of years for this waste to decay to a safe level, the facility needs to be able to endure for an extremely long time. That's why this study is so vital to energy research. By studying the molecular reactions between cement and water over two years, our team can extrapolate the impact over a much longer period."
Claire will be presenting her pioneering work on radioactive waste disposal at the AAAS conference this February 14th. As part of a symposium entitled Cleaner Energy Solutions: What Can 21st Century Large-Scale Physics Deliver? Claire will make up a panel of three leading energy scientists.
Together, the group will discuss their individual research projects and equip the audience with an understanding of pragmatic, achievable solutions to the global warming challenge. This is the ultimate goal for research like Claire's and, with the support of cutting-edge facilities like the LDE, scientists are helping to develop our approach to the challenges presented by climate change. Energy research is just one of the many areas in which the LDE can provide scientists support. The facility puts a call out once each year, and an external panel of experts selects the most intriguing scientific research for further study. Professor Chiu Tang is Principal Beamline Scientist for I11 and the LDE facility. He says: "We are here to support a class of experiments that could not otherwise be done within the existing science infrastructure. And that's what we're looking for – problems that couldn't be solved any other way and the opportunity to open up avenues of enquiry that have never been thought possible before."
The wider context: further energy research taking place on the LDE facility
The world-leading LDE facility is an important resource for many different scientific fields. Recent expansion has brought the number of experiments that can take place at the facility at once up from 6 to 20.
Currently in progress are experiments into the long-term melting patterns of Arctic sea ice, research into the possible reactions behind the formation of Saturn's icy moons, and studies of the behaviour of common drug compounds under high humidity, mimicking conditions that are common in much of Asia and the pacific.
However, the LDE is especially useful to a particular area of research: energy. Understanding the long-term behaviour of materials involved in our energy infrastructure is vital to improving performance and efficiency at time when we are faced with many questions about the future of our energy resourcing.
In addition to the radioactive waste disposal experiments being led by Dr Claire Corkihill, the LDE currently has two other ongoing experiments that are closely tied to this field. Research into lithium ion batteries is trying to assess how the degradation of cathodes within the batteries cause decreased performance over time. This work could be important to improving battery life for a range of consumer products and may help to make battery power a more widely-used resource.
Further research is looking into the carbon capture potential of metal-organic frameworks (MOFs). These cage-like structures are capable of ensnaring carbon molecules and removing them from the atmosphere. In time, they may offer a valuable means of reducing the damage caused by industrial processes by removing some of the carbon emitted into the air.
However scientists need to know that MOFs can continue to work over long timescales. That's why it's so helpful to be able to test for and assess degradation on the atomic level over a two year period on the LDE.
For these and many other research projects, the cutting-edge LDE facility offers scientists the opportunity to carry out research in a broad range of fields using equipment that is unmatched anywhere else in the world.
For further information, please contact Silvana Westbury
Email: [email protected] or Mob: +44 (0)7920 594660
Images on request. Please contact Stefania Mazzorana
Email: [email protected] or Tel: +44-0-1235-567599
About Diamond Light Source
Diamond Light Source is funded by the UK Government through the Science and Technology Facilities Council (STFC), and by the Wellcome Trust.
Diamond generates extremely intense pin-point beams of synchrotron light. These are of exceptional quality, and range from X-rays to ultra-violet to infrared. Diamond's X-rays are around 10 billion times brighter than the sun.
Diamond Light Source is used by over 8,000 academic and industrial researchers across a wide range of disciplines, including structural biology, health and medicine, solid-state physics, materials & magnetism, nanoscience, electronics, earth & environmental sciences, chemistry, cultural heritage, energy and engineering. Many everyday commodities that we take for granted, from food manufacturing to consumer products, from revolutionary drugs to surgical tools, from computers to mobile phones, have all been developed or improved using synchrotron light. For more information about Diamond visit http://www.diamond.ac.uk
Further information on the AAAS 2016 Annual Meeting can be found here.
For further information, please contact Dr Claire Corkhill
Email: [email protected] or Tel: 44-114-222-3632
About University of Sheffield
With almost 26,000 of the brightest students from around 120 countries, learning alongside over 1,200 of the best academics from across the globe, the University of Sheffield is one of the world's leading universities.
A member of the UK's prestigious Russell Group of leading research-led institutions, Sheffield offers world-class teaching and research excellence across a wide range of disciplines.
Unified by the power of discovery and understanding, staff and students at the university are committed to finding new ways to transform the world we live in.
The NucleUS Immobilisation Science Laboratory group was set up in the Department of Materials Science and Engineering in 2001 as one of four BNFL University Research Alliances, with a focus on radioactive waste research. Since then, the group has significantly grown to encompass 9 academic staff, 13 research staff and 41 PhD students, with research spanning radioactive waste materials, geological disposal, nuclear fuels and reactor materials, and nuclear waste policy. The group currently has a live grant portfolio in excess of £15M, with current grants spanning the next 5 years.
We are a key member of the University of Sheffield's Energy2050 research institute, which has a strategic vision to develop energy technology and train the next generation of energy leaders by 2050. The NucleUS Immobilisation Science Laboratory is the spearhead of Energy2050's nuclear energy research and we work closely with other parts of the University in our research, for example, the Nuclear Advanced Manufacturing Research Centre. The group is also part of the national training centre for nuclear PhDs. The group's strategic vision is closely aligned with that of Energy2050, thus we hope to be continuing our research in 2050 and beyond.