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Diamond Light Source

Diamond Light Source is the United Kingdom's national synchrotron science facility, located at the Harwell Science and Innovation Campus in Oxfordshire, and serves as a world-leading source of synchrotron radiation for cutting-edge research across disciplines including biology, materials science, chemistry, and medicine.^[1] It operates as a third-generation synchrotron, accelerating electrons in a 3 GeV storage ring to produce intensely bright beams of X-rays, infrared, and ultraviolet light, enabling scientists to probe the structure and dynamics of matter at atomic and molecular scales.^[2] The facility supports an international user community, with approximately 70% of users from the UK and the rest from regions including the EU, US, China, Canada, Japan, Israel, and Australia, facilitating breakthroughs such as antibody therapies for COVID-19 and studies on quantum materials.^[3] Established in 2002 as a not-for-profit limited company, Diamond Light Source is a joint venture owned by the Science and Technology Facilities Council (STFC), which holds 86% of the shares, and the Wellcome Trust, with 14%.^[4] Construction began in 2003, and the facility opened to users in January 2007, marking the largest scientific infrastructure project built in the UK for over 40 years at the time.^[5] Funded primarily by the UK government through UK Research and Innovation (UKRI) and the Wellcome Trust in the same 86:14 proportion, its annual operating costs reached £82.1 million in 2023/24, supporting ongoing expansions and upgrades.^[6]^[3] Technically, Diamond features a 561-meter circumference storage ring capable of holding electron beams at 300 mA current, with in-vacuum undulators to generate high-brightness synchrotron light across more than 30 operational beamlines as of 2023/24, categorized for techniques like macromolecular crystallography, spectroscopy, and imaging.^[5]^[3] The facility achieves 97% machine uptime and supports both onsite and remote access, with 5,398 academic onsite visits and 4,078 remote visits in 2023/24.^[3] A major upgrade, Diamond-II, approved in 2023, will enhance beam brightness by orders of magnitude and add three new flagship beamlines, with construction of supporting infrastructure like the Diamond Extension Building underway since January 2024.^[6]^[3] Diamond's impact is evident in its research output, including over 13,000 peer-reviewed journal articles by December 2023, with contributions to high-profile studies on topics like twistronics, CO2 conversion, hydrogen embrittlement, and the analysis of ancient Herculaneum scrolls and asteroid Bennu samples.^[3] Employing 839 staff from 44 countries, it fosters international collaborations and public engagement, such as Project M involving over 1,000 students from 110 UK schools, while contributing to projects valued at more than £248 million.^[3] Notable achievements include developing an antibody therapy integrated into AstraZeneca's COVID-19 treatments and earning a Gold Award in the Employer Recognition Scheme for its inclusive workplace.^[3]

History and Development

Origins and Planning

The origins of Diamond Light Source trace back to the late 1990s, when a strategic review by UK scientific authorities identified the need to replace the aging Synchrotron Radiation Source (SRS) at Daresbury Laboratory, which had been operational since 1980 and was becoming uncompetitive for advanced research by the early 2000s.^[7]^[8] The SRS, the world's first dedicated high-energy X-ray synchrotron, had served as the UK's primary facility for synchrotron radiation experiments but lacked the brightness and capabilities required for emerging fields like structural biology. The SRS was closed on 4 August 2008 after 28 years of operation.^[8] This initiative was driven by the motivation to establish a state-of-the-art third-generation synchrotron to bolster UK research in structural biology, materials science, and related disciplines, positioning the country to compete with international facilities such as the European Synchrotron Radiation Facility (ESRF) in Grenoble and the Advanced Photon Source (APS) at Argonne National Laboratory.^[7]^[9] Planning for Diamond began in earnest following government approval in 1998, with initial funding commitments from the UK Government and the Wellcome Trust to support the development of a high-brightness X-ray source optimized for protein crystallography and life sciences applications.^[7] Key milestones included the selection of the site at the Harwell Science and Innovation Campus in Oxfordshire, adjacent to the Rutherford Appleton Laboratory, announced in March 2000 to leverage existing infrastructure and proximity to research hubs.^[7] The formal design phase commenced in November 2000, incorporating user consultations that shaped the facility's parameters, such as a 3 GeV electron energy and a 24-cell storage ring layout with double-bend achromat (DBA) structure for enhanced beam stability and low emittance.^[9]^[7] These choices emphasized a compact, efficient design to deliver X-ray beams 10^12 times brighter than conventional laboratory sources, addressing the limitations of the SRS while enabling breakthroughs in atomic-scale investigations.^[7] Early partnerships were central to the project's viability, with the Science and Technology Facilities Council (STFC, formerly the Council for the Central Laboratory of the Research Councils) and the Wellcome Trust collaborating from the outset to provide governance and financial backing. Diamond Light Source Ltd was incorporated on 18 February 2002, with the joint venture agreement signed on 27 March 2002 as a limited company, with the STFC holding an 86% stake and the Wellcome Trust 14%, marking the transition from planning to implementation.^[10]^[11]^[12] This structure ensured multidisciplinary input, reflecting the facility's role in advancing national and global scientific priorities beyond the SRS's capabilities.^[7]

Construction and Commissioning

Construction of the Diamond Light Source began with groundbreaking in March 2003 at the Harwell site in Oxfordshire, UK.^[13] Major construction activities spanned from 2004 to 2006, involving the excavation and building of the facility's core infrastructure, including the accelerator complex. The project was completed on schedule, with the first stored electron beam achieved in the storage ring on May 30, 2006, marking the initial observation of synchrotron light.^[14] User operations commenced in January 2007 with the integration and commissioning of the first seven beamlines, primarily focused on structural biology applications.^[15] The facility was officially opened by Queen Elizabeth II on October 19, 2007.^[16] Key engineering achievements included the construction of the 561.6-meter circumference storage ring tunnel, which forms the core of the synchrotron.^[14] The injector systems, comprising a 100 MeV linear accelerator (linac) and a 3 GeV booster synchrotron, were installed and tested to deliver electrons to the storage ring.^[17] These components were integrated with the initial seven beamlines during the construction phase, enabling early experiments in areas such as macromolecular crystallography. The storage ring achieved ultra-high vacuum levels of approximately 4.2 × 10^{-10} mbar without beam, essential for maintaining beam stability and lifetime.^[18] Construction at the Harwell site presented geotechnical challenges due to the underlying chalk bedrock and high groundwater levels, addressed by driving 1,500 concrete piles up to 15 meters deep to stabilize the foundations.^[19] Commissioning proceeded in phases, starting with accelerator testing in 2006, followed by beamline shakedown and user beam delivery in 2007. By 2012, the facility had expanded to 22 operational beamlines through Phase II construction, building on the initial design capacity for up to 40 beamlines.^[20] This progression established Diamond as a fully functional national synchrotron facility.^[15]

Organization and Funding

Governance and Management

Diamond Light Source Ltd operates as a not-for-profit limited company established in 2002 as a joint venture between the UK Government through the Science and Technology Facilities Council (STFC) and the Wellcome Trust, with STFC holding 86% of the shares and Wellcome Trust 14%. The governing body is the Board of Directors, which includes representatives from the STFC, Wellcome Trust, and independent members to represent broader stakeholder interests, including the user community. The Board oversees strategic direction, ensures compliance with regulatory requirements, and appoints the executive leadership. In 2024, Prof Sir Leszek Borysiewicz was appointed as the new Chair of the Board.^[4]^[21]^[22]^[23] The executive leadership is headed by the Chief Executive Officer (CEO), currently Professor Gianluigi Botton as of 2025, who is responsible for overall operational strategy and implementation. Supporting the CEO are key roles including the Deputy CEO and Chief Financial Officer (Andrea Ward), Technical Director (Richard Walker, overseeing accelerator and operations), Life Sciences Director (Professor Sir David Stuart), and Physical Sciences Director (Dr. Adrian Mancuso). These division heads manage scientific and technical activities across beamlines, accelerators, and support services, ensuring alignment with the facility's mission to deliver world-class synchrotron research capabilities. The facility employs over 820 staff as of 2024/25.^[24]^[25]^[23] Decision-making processes include annual business planning led by the executive team and approved by the Board, focusing on resource allocation, facility upgrades, and performance metrics. Beamtime allocation is managed through peer-reviewed proposals evaluated by independent access committees, such as the Diamond User Committee (DUC) and science-specific review panels, ensuring equitable and merit-based access for users. Diamond serves over 14,000 researchers annually from UK academia, industry, and international partners, with approximately 70% of users based in the UK. In 2024/25, there were 6,596 onsite user visits and 4,617 remote visits.^[26]^[27]^[28]^[3]^[23] Safety and ethics oversight is integrated into daily administration through dedicated policies and committees. The facility enforces rigorous radiation safety protocols under the Safety, Health, and Environment (SHE) framework to protect staff, users, and the public, while ensuring environmental compliance with UK regulations on waste and emissions. Ethical standards are upheld via a Code of Best Practice in Scientific Research, and open-access data policies require experimental data to be made publicly available after an embargo period, typically under a CC-BY-4.0 license, to promote transparency and reuse in the scientific community.^[29]^[30]^[31]

Financial Model and Support

The Diamond Light Source was established through an initial capital investment of £260 million for its construction between 2002 and 2007, with 86% provided by the UK Government via the Science and Technology Facilities Council (STFC) and 14% by the Wellcome Trust.^[32]^[16] This funding supported Phase I of the facility, which delivered seven operational beamlines by 2007.^[32] Ongoing operations are sustained by an annual budget of £77.8 million as of 2024/25, predominantly funded through government grants from UK Research and Innovation (UKRI) via STFC, which covers the majority of costs, supplemented by contributions from the Wellcome Trust and income from industrial users accounting for around 10% of total revenue.^[23]^[33] The facility's access model provides free beamtime for peer-reviewed academic research, while proprietary industrial access generates additional revenue through fees, supporting an estimated 3-7% of total beamtime allocation to over 180 companies since 2008.^[33] Facility expansion has proceeded in phases, with Phase II adding 15 beamlines to reach a total of 22 by 2012, funded by an additional £124 million primarily from the same government and Wellcome sources.^[5]^[33] Phase III, completed by 2024, incorporated 10 more beamlines for a total of 32, with the facility now operating 35 beamlines as of 2024/25, backed by £105.6 million in investments that enhanced capabilities in areas such as structural biology and materials science.^[34]^[33]^[23] In 2023, a £519.4 million commitment was approved for the Diamond-II upgrade, maintaining the established 86% UK Government (via UKRI) and 14% Wellcome Trust funding ratio, to enable multi-technique experiments and increased capacity. In 2024/25, £66.7 million was allocated to the upgrade.^[6]^[35]^[23] Diamond's financial model has delivered substantial economic returns, with a cumulative monetised socio-economic impact exceeding £2.6 billion on the UK economy as of 2022 through research outputs, technology transfer, and spin-offs that support industries in pharmaceuticals, energy, and manufacturing.^[36]^[33] This impact includes annual gross economic contributions of around £84 million, driven by enabling over 14,000 users and fostering collaborations that amplify public investment.^[33]^[3]

Facility Infrastructure

Site and Layout

Diamond Light Source is situated on the Harwell Science and Innovation Campus in Oxfordshire, United Kingdom, approximately 20 miles south of Oxford and sharing the site with facilities such as the Rutherford Appleton Laboratory.^[37]^[1] The campus provides a collaborative environment for scientific research, integrating multiple national laboratories and innovation centers.^[38] The facility's core layout features a central synchrotron building with a floor area of 45,000 m², designed in a distinctive toroidal shape to house the storage ring.^[16] From this central structure, beamlines extend radially like spokes, currently numbering over 30, with plans for expansion to support additional instruments.^[39] Adjacent to the main building are dedicated control rooms for operations, office spaces for staff and researchers, and specialized sample preparation laboratories equipped for handling diverse experimental materials.^[40] Supporting infrastructure includes an on-site guest house, Ridgeway House, providing accommodation for visiting researchers within a short walk of the facility.^[41] Diamond operates a high-performance computing cluster to manage data acquisition and analysis from experiments, enabling real-time processing of large datasets.^[42] Cryogenic facilities, particularly through the Electron Bio-Imaging Centre (eBIC), support sample preparation and imaging under ultra-low temperatures for structural biology studies.^[43] The site's accessibility enhances its utility, with Didcot Parkway railway station just six miles away, offering direct trains from London Paddington in under 60 minutes, followed by a short taxi ride.^[44] In 2024/25, the facility hosted 6,596 onsite academic user visits, contributing to extensive experimental sessions.^[23] Sustainability is integrated into the campus design, featuring a low-energy building envelope and extensive solar panels covering more than 32,000 m² of the synchrotron structure to generate renewable electricity.^[45] The Harwell Campus emphasizes green integration, with environmental policies focused on energy efficiency and resource management to minimize operational impact.^[46] Construction of the Diamond Extension Building, a £25 million facility providing space for girder assembly, temporary storage, offices, and laboratories, began in 2024 to support the Diamond-II upgrade.^[47]

Accelerator Systems

The accelerator systems at Diamond Light Source comprise the linear accelerator (linac) and booster synchrotron, which generate and accelerate electron bunches to full energy before transfer to the storage ring. These components ensure a reliable supply of high-quality electrons for sustained synchrotron operation. The linac serves as the initial injector, producing relativistic electrons that the booster further energizes in rapid cycles. The linac is an S-band linear accelerator approximately 235 m in length, designed to boost electrons from an electron gun to an energy of 100 MeV using radiofrequency (RF) cavities, including accelerating sections and bunching systems. It employs thermionic gun technology and operates with klystrons delivering up to 20 MW pulses at a repetition rate of up to 5 Hz, yielding electron bunches with charges exceeding 1.5 nC and full-width half-maximum (FWHM) durations around 0.2 ns. This configuration supports both single-bunch and multi-bunch modes, optimized for efficient injection into the downstream systems. The booster synchrotron is a full-energy injector ring with a circumference of 158.4 m, utilizing a FODO lattice with missing dipoles for on-axis injection and extraction via a single kicker magnet. It accelerates electrons from 100 MeV to 3 GeV by ramping dipole and quadrupole fields sinusoidally over approximately 100 ms within each cycle, operating at a repetition rate of 5 Hz to match the linac output. The resulting beam emittance is around 141 nm·rad, enabling high-brightness transfer through the beam transport line to the storage ring. Diamond employs top-up injection, where small numbers of electron bunches are periodically added to maintain a constant stored current of up to 300 mA, minimizing beam decay and ensuring stable light output for experiments. This mode, operational since 2008, involves cycles every 10 minutes or less, with injection efficiency enhanced by the booster's rapid repetition. The overall system reliability is supported by routine maintenance, including magnet warming, RF system checks, and fault rectification during scheduled machine development periods, achieving beam uptime exceeding 98% in user operations.

Synchrotron Operations

Storage Ring Design

The storage ring at Diamond Light Source employs a 24-cell double-bend achromat (DBA) lattice design, which provides low emittance and efficient beam transport for synchrotron radiation production.^[48] The ring has a circumference of 561.6 meters and operates with electron beams at an energy of 3 GeV and a design maximum stored current of 500 mA, with current operations at 300 mA as of 2024, enabling high-flux photon beams across a wide spectral range.^[49]^[50] The magnet system consists of 48 bending magnets, each producing a magnetic field of 1.4 T to maintain the closed orbit, complemented by quadrupole and sextupole magnets for horizontal and vertical focusing as well as chromaticity correction.^[20] These elements are arranged in the DBA cells to achieve natural emittance values around 2.7 nm rad, optimizing beam quality for insertion device operation.^[48] To ensure beam longevity and minimal interactions, the storage ring maintains an ultra-high vacuum environment with base pressures on the order of 10^{-10} mbar, achieved through distributed non-evaporable getter pumps and careful material selection to mitigate outgassing.^[51] Beam orbit stability is actively controlled to within 1 micron using fast feedback systems incorporating beam position monitors and corrector magnets, critical for high-resolution experiments.^[34] The design incorporates 22 straight sections dedicated to insertion devices, with two sections reserved for injection and radiofrequency cavities.^[51] These sections host undulators up to 2 meters in length with magnetic periods around 14 mm, as well as wigglers, enhancing spectral brightness by forcing oscillatory electron motion.^[52] At the operational current of 300 mA, the beam lifetime is approximately 16 hours in top-up mode, limited primarily by Touschek scattering.^[53]

Beam Characteristics and Production

Synchrotron radiation at Diamond Light Source is generated through the acceleration of relativistic electrons circulating in the storage ring. Electrons are accelerated to an energy of 3 GeV, reaching speeds close to that of light, and are deflected by strong magnetic fields in the dipole bending magnets and insertion devices. This deflection causes the electrons to emit intense electromagnetic radiation as they undergo centripetal acceleration, producing synchrotron light with a broad spectrum ranging from the infrared to hard X-rays. The storage ring's design facilitates this continuous bending of the electron beam, enabling sustained production of the radiation over operational periods of several hours.^[54] The brightness of the emitted beams is a defining feature, achieving up to $10^{21} photons/s/mm²/mrad²/(0.1% bandwidth) in the X-ray regime, which represents approximately 100 times the brightness of second-generation synchrotron sources. This exceptional brightness stems from the low emittance of the electron beam and the use of advanced insertion devices. The light exhibits partial transverse coherence, particularly enhanced in the vertical direction due to the beam's small vertical emittance of 8 pm rad, and is predominantly linearly polarized, with the polarization plane determined by the magnetic field orientation. Circular polarization can be achieved using specialized helical undulators.^[55]^[54] The energy spectrum of the radiation has a critical energy of approximately 5 keV in the dipole magnets, allowing access to soft X-rays, while insertion devices extend tunability across a wider range. Undulators produce highly coherent, narrow-bandwidth beams ideal for experiments requiring phase-sensitive techniques, whereas wigglers generate broader spectra with higher flux for applications needing intense, polychromatic light. The facility operates primarily in hybrid mode, which couples the electron bunches to achieve a low horizontal emittance of about 2.7 nm rad, optimizing overall beam stability and brightness while supporting beam currents up to 300 mA as of 2024.^[56]^[54]

Beamlines and Instruments

Overview and Types

Diamond Light Source operates 33 beamlines as of 2024, an increase from 32 in 2019, alongside eight electron microscopes dedicated to experiments, including several cryo-electron microscopes within the Electron Bio-Imaging Centre (eBIC).^[57]^[58]^[43] These beamlines exploit the synchrotron's high-brightness X-ray beams to enable diverse structural and analytical studies across scientific domains.^[59] The facility's beamline portfolio began with seven initial beamlines commissioned in 2007 as part of Phase I construction, focusing on core capabilities in structural biology, materials science, and spectroscopy.^[34] Subsequent phases expanded the infrastructure, with ongoing developments such as the Dual Imaging and Diffraction (DIAD) beamline, which entered operation in 2024 to support combined imaging and diffraction experiments at energies from 7 to 38 keV.^[60] This phased growth has built a versatile suite tailored to evolving research demands, maintaining compatibility with the storage ring's beam properties for stable, high-flux delivery, with additional beamlines like SWIFT under construction as part of the Diamond-II upgrade.^[28] Beamlines are categorized by primary scientific focus, with approximately 40% dedicated to life sciences, including I03 and I04 for macromolecular crystallography to determine protein structures. About 30% serve materials science, exemplified by I11 for high-resolution powder diffraction to analyze crystalline structures under various conditions.^[61] Roughly 20% target physics and chemistry applications, such as I08 for soft X-ray spectroscopy and microscopy of electronic and magnetic properties. The remaining ~10% emphasize imaging and cultural heritage studies, enabling non-destructive analysis of artifacts and biological samples.^[62] Access to these beamlines follows a structured model, with approximately 90% allocated through a general user program based on competitive peer review of scientific proposals, ensuring equitable distribution to academic and public researchers.^[63] The remaining ~10% supports proprietary and industrial access, allowing confidential experiments for commercial development while contributing to facility sustainability.^[64] Utilization remains exceptionally high, exceeding 95% occupancy across the beamlines, supporting 1,312 awarded proposals and 15,972 experimental shifts in 2023/24 through user programs.^[57]^[28] This intense demand underscores the facility's role as a cornerstone for advanced research, with beamtime proposals rigorously evaluated for merit and feasibility.^[28]

Key Techniques and Capabilities

Diamond Light Source enables a suite of core experimental techniques leveraging its high-brilliance synchrotron X-ray beams. Macromolecular X-ray crystallography (MX) determines atomic-resolution three-dimensional structures of proteins and biological macromolecules, supporting high-throughput data collection with energy tunability for anomalous dispersion methods.^[65] Small-angle X-ray scattering (SAXS) and wide-angle X-ray scattering (WAXS) probe the structure and dynamics of nanoscale assemblies, soft matter, and partially ordered materials in solution or solid states, benefiting from high flux for weak scattering signals.^[66] X-ray absorption spectroscopy (XAS), including extended X-ray absorption fine structure (EXAFS) and X-ray absorption near-edge structure (XANES), elucidates local electronic and geometric structures around specific atoms, with rapid acquisition over energies from 2 to 35 keV.^[67] X-ray tomography and imaging techniques generate three-dimensional reconstructions via absorption or phase contrast, capturing internal structures non-destructively.^[68] Photoelectron spectroscopy, particularly X-ray photoelectron spectroscopy (XPS) and hard X-ray photoelectron spectroscopy (HAXPES), analyzes surface chemistry, electronic states, and buried interfaces with depth sensitivity up to several nanometers.^[69] Specialized capabilities extend these techniques to dynamic and extreme conditions. Time-resolved studies span picosecond to millisecond timescales, enabled by the synchrotron's pulsed beam structure (1-20 picoseconds per bunch) and pump-probe setups, allowing observation of transient processes like photo-induced reactions or phase transitions.^[70] High-pressure experiments, utilizing diamond anvil cells, achieve pressures up to 300 GPa combined with variable temperatures, facilitating investigations of material behavior under geophysical or industrial extremes.^[71] Operando conditions simulate real-world environments for catalysis and battery research, integrating in situ cells for electrochemical or reactive gas flow to monitor structural evolution during operation.^[72] Complementary tools enhance precision and efficiency across beamlines. Nano-focus endstations deliver sub-micron beam sizes (down to ~200 nm), enabling spatially resolved measurements on heterogeneous samples like microcrystals or nanomaterials.^[73] Robotic sample changers, such as the BART system, automate high-throughput MX experiments, handling hundreds of samples for rapid screening.^[74] Resolution limits include atomic-scale structural detail at ~1 Å for crystallography and 4D imaging (three-dimensional plus time) for capturing dynamics in materials like semi-solid alloys.^[65]^[75] Data handling supports the facility's high-volume output, with on-site petabyte-scale storage (over 8 PB capacity) archiving vast datasets from intensive experiments.^[76] AI-assisted analysis pipelines automate processing, such as diffraction pattern recognition and reconstruction, accelerating insights from complex datasets.^[77]

Research Applications

Scientific Disciplines

Diamond Light Source supports a diverse array of scientific disciplines, primarily encompassing life sciences, materials science, physical sciences, environmental and earth sciences, cultural heritage, and engineering. These fields leverage the facility's synchrotron radiation capabilities to address fundamental and applied research questions, with beamtime allocated through peer-reviewed proposals based on scientific merit. In the 2023/24 operational year, a total of 15,972 experimental shifts were awarded across 33 beamlines and seven electron microscopes, reflecting the facility's role in advancing interdisciplinary science aligned with UK Research and Innovation (UKRI) priorities. Beamtime allocations included: Biology/Biomaterials 16%, Materials science 39.45%, Chemistry 15.49%, Physics 13.16%, Environment 4.51%, Engineering 3.94%, Energy 1.96%, and Others 6.03%.^[3] In life sciences, which accounted for 16% of beamtime allocation, research focuses on structural biology to elucidate protein structures, enzyme mechanisms, and biological processes relevant to drug discovery and health. Applications include studies of membrane proteins, inflammation signaling pathways, and antiviral nanomaterials, such as investigations into bacterial complexes and poly-L-lysine-based materials for combating infections. These efforts contribute to understanding disease mechanisms, including tuberculosis inhibitors and coeliac disease therapies, while also extending to ecological biology like bumblebee vision.^[3] Materials science represents the largest share of beamtime at 39.45%, emphasizing the development of advanced materials for energy and technology applications. Key areas involve phase transitions, nanomaterials, and energy storage solutions like batteries and fuel cells, with techniques such as pair distribution function (PDF) analysis used to probe local atomic structures. Representative examples include research on twistronics in graphene for electronics, boron nitride for photocatalysis, and CO2-derived polymers for sustainable manufacturing, alongside studies of hydrogen embrittlement in stainless steel and metal-organic framework (MOF) composites for energy harvesting.^[3] Physical sciences, encompassing chemistry (15.49%) and physics (13.16%) of allocated beamtime, cover condensed matter physics, surfaces and interfaces, and soft matter systems. Investigations target magnetic materials, quantum dots, and axion insulators to advance quantum technologies and materials understanding, as well as soft matter behaviors in polymers and colloids through small-angle X-ray scattering (SAXS). Examples include analyses of polymer melting dynamics and aerosol films, contributing to insights into material properties at the atomic and molecular scales.^[3] Environmental and earth sciences utilize 4.51% of beamtime to explore geochemistry, pollution remediation, and climate-related processes, often employing X-ray fluorescence (XRF) for elemental analysis. Research addresses CO2 conversion to useful materials, microplastic environmental impacts, chromium remediation in soils, and aerosol behavior from sources like cooking residues, supporting sustainable energy and pollution control strategies.^[3] Cultural heritage and engineering together account for about 8% of beamtime (Engineering 3.94%, with cultural heritage under Others), focusing on non-destructive analysis. In cultural heritage, synchrotron techniques enable the study of artifacts, such as the deciphering of Herculaneum scrolls without damage. Engineering applications include failure analysis in aerospace components, strain mapping in perovskites for solar cells, and semiconductor synthesis, aiding advancements in high-performance materials and detector technologies.^[3] The user community is predominantly academic, with the vast majority of access provided free of charge to researchers from universities and public institutions; industry users receive up to 10% of available beamtime on a proprietary, fee-based basis. Approximately 70% of peer-reviewed beamtime is awarded to UK-based users, with the remaining 30% supporting international collaborators from regions including Europe, the US, China, Canada, Japan, and Australia, fostering global research partnerships. In 2023/24, this resulted in 5,398 onsite academic visits and 4,078 remote user sessions from 1,312 awarded proposals.^[78]^[3]^[79]

Notable Case Studies and Impacts

In the field of biology and medicine, Diamond Light Source has contributed pivotal structural insights that advanced therapeutic development. In 2020, researchers utilized Diamond's beamlines to determine high-resolution structures of the SARS-CoV-2 spike protein, revealing its interaction with host cells and facilitating rapid vaccine design by confirming the efficacy of spike-based immunogens.^[80] This work, part of an international open-access effort, accelerated global vaccine initiatives by providing essential data for stabilizing the protein in prefusion conformations. Earlier, in 2011, structural studies at Diamond elucidated the histamine H1 receptor's binding site, enabling the design of more selective antihistamines for treating allergies with reduced side effects.^[81] Materials science applications have highlighted Diamond's role in sustainable technologies. A 2018 study on beamline I03 characterized the PETase enzyme from Ideonella sakaiensis, demonstrating its mechanism for breaking down polyethylene terephthalate plastics into monomers, which informs enzymatic recycling processes to mitigate plastic pollution.^[82] Ongoing operando imaging at beamlines like I12 has visualized lithium dendrite formation in real-time during battery charging, aiding the development of safer, higher-capacity lithium-ion batteries for electric vehicles by identifying failure modes in solid-state electrolytes.^[83] Heritage conservation efforts underscore Diamond's interdisciplinary impact. Analysis of timbers from Henry VIII's Mary Rose warship, using X-ray techniques on beamline I18, identified sulfur-induced acid degradation post-salvage, guiding polyethylene glycol treatments to prevent structural collapse and preserve the artifact for future study.^[84] In 2024, non-destructive X-ray phase-contrast imaging at Diamond's I12 beamline supported the Vesuvius Challenge by scanning a carbonized Herculaneum papyrus scroll, enabling AI-assisted virtual unrolling and text decipherment of lost ancient philosophical works without physical damage.^[85] Additional studies have explored biomimicry and nuclear safety. Synchrotron tomography of moth wing scales revealed nanoscale acoustic metamaterials that scatter ultrasound for predator evasion, inspiring lightweight, sound-absorbing designs in aerospace engineering.^[86] In 2025, investigations into irradiated nuclear graphite at Diamond aim to model degradation under reactor conditions, enhancing lifecycle predictions to improve safety and waste management in advanced nuclear reactors.^[87] Diamond's broader impacts include contributing to a cumulative total of over 13,000 peer-reviewed publications by December 2023, fostering advancements across disciplines.^[3] An independent socio-economic study estimates a return of approximately £7 for every £1 invested, through innovations in health, energy, and manufacturing that have delivered at least £2.6 billion in cumulative UK benefits since 2007.^[36] Notable spin-offs include pharmaceutical collaborations from the COVID Moonshot project, yielding broad-spectrum antivirals like main protease inhibitors now advancing toward clinical trials.^[88]

Future Developments

Diamond-II Upgrade

The Diamond-II upgrade represents a major overhaul of the Diamond Light Source facility, centered on replacing the existing storage ring with a multi-bend achromat lattice to dramatically enhance beam quality for advanced scientific investigations. The new design adopts a modified hybrid 6-bend achromat (MH6BA) structure, featuring 6 superperiods with specialized dipoles for dispersion control, which reduces the horizontal emittance from the current 2.7 nm-rad to approximately 162 pm-rad in its natural state and 121 pm-rad with insertion devices.^[89] This upgrade increases photon brightness by a factor of 100 and improves transverse coherence, enabling micro- and nano-scale probing essential for resolving atomic structures and dynamic processes.^[90] The project also includes a redesigned radio-frequency (RF) system, transitioning from superconducting CESR-type cavities to normal-conducting, higher-order-mode-damped cavities to support stable multi-bunch operation at higher currents.^[91] Additionally, the injector complex will be upgraded with a new booster synchrotron delivering lower emittance beams (around 17 nm-rad) and shorter bunch lengths (38 ps), ensuring efficient top-up injection into the storage ring.^[92] The upgrade timeline was approved in September 2023 by the UK government, with initial funding from the UK Research and Innovation (UKRI) Infrastructure Fund and the Wellcome Trust.^[93] Preparatory work, including the construction of an extension building, began in early 2024, with machine installation slated to start in late 2027 following an 18-month dark period to minimize overall facility downtime.^[94] As of 2025, progress includes the arrival of critical components from China in March 2025, a contract award for octupole corrector magnets in February 2025, and ongoing construction of beamline hutches for the flagship beamlines as of May 2025.^[95]^[96]^[97] The implementation will be staged, with critical upgrades and some beamlines completed prior to the dark period, and full operations resuming by 2030 to ensure continued user access with limited interruption. This phased approach allows for the progressive delivery of enhanced capabilities while maintaining the facility's high uptime, currently exceeding 97%.^[98] Key new facilities include three flagship beamlines optimized for the upgraded source: K04, an ultra-high-throughput beamline for macromolecular crystallography (MX) and fragment-based drug discovery (XChem), replacing the existing I04-1 and supporting serial crystallography for time-resolved studies of protein dynamics.^[99] SWIFT, focused on advanced imaging for life sciences, will enable correlative multi-modal techniques for biological samples at nanoscale resolution.^[100] The third, CSXID, targets coherent scattering and X-ray imaging diffraction for materials science, facilitating 4D investigations of dynamic processes in energy storage and catalysis.^[100] These beamlines, along with upgrades to optics, detectors, and computing infrastructure, will boost experimental throughput and automation. The total cost of the Diamond-II project is £519.4 million, positioning it as a transformative investment that extends the facility's leadership in synchrotron science for decades.^[90] By achieving diffraction-limited performance in the hard X-ray regime, the upgrade will unlock breakthroughs in pharmaceutical development, such as rapid drug screening, and materials research, including real-time observation of phase transitions for sustainable technologies.^[93]

Expansion and Sustainability Initiatives

Following the Diamond-II upgrade, Diamond Light Source plans to expand its beamline portfolio to support emerging research needs, including the addition of up to three new beamlines enabled by the upgraded storage ring design.^[101] These will complement existing facilities, with a focus on specialized capabilities such as high-pressure studies and quantum materials characterization, building on current infrastructure like the I15 beamline for extreme conditions. The facility aims to ultimately host up to 40 beamlines in the long term, enhancing its capacity for multidisciplinary experiments across life, physical, and environmental sciences.^[102] Diamond integrates with complementary facilities on the Harwell Campus to broaden its research ecosystem. As a founding member of the Rosalind Franklin Institute since 2019, it collaborates on cryo-electron microscopy (cryo-EM) advancements, combining synchrotron techniques with high-resolution imaging for structural biology applications like protein scaffolding design.^[103] Additionally, the Active Materials Laboratory, opened in November 2022, supports in-situ testing of radioactive and nuclear materials under operational conditions, facilitating studies in energy and waste management.^[104]^[105] Sustainability efforts at Diamond prioritize environmental responsibility in line with the UN Sustainable Development Goals and the Paris Agreement. The facility endorses the UK's net-zero emissions target by 2050, implementing measures such as a fully operational solar panel array installed in 2024, which as of July 2025 contributed 30% of the facility's power needs and generates approximately 2.3 GWh annually to reduce reliance on grid power and lower operational carbon emissions.^[45]^[106]^[107] Energy efficiency upgrades include fan conversions in cooling systems, which have improved overall thermal management without compromising experimental precision.^[108] International collaborations strengthen Diamond's global role, particularly through partnerships with facilities like SESAME in Jordan. Since 2018, the Diamond SESAME Rutherford Fellowship programme has hosted fellows for advanced training in synchrotron techniques, fostering knowledge exchange and regional capacity building in the Middle East.^[109] Domestically and internationally, annual training initiatives such as the Synchrotron Radiation School—running since at least 2010—provide postgraduate and early-career researchers with hands-on experience in beamline experiments and data analysis.^[110]^[111] These initiatives position the UK as a leader in fourth-generation light sources, with Diamond-II synergies enabling brighter, more coherent X-rays for transformative science in clean energy and materials innovation.^[112]^[113]

References

[1]
Diamond Light Source
Diamond Light Source is the UK's national synchrotron science facility, located at the Harwell Science and Innovation Campus in Oxfordshire.About Us · Careers · Contact Us · Vacancies
[2]
How Diamond Works - Diamond Light Source
Explore Diamond by using our interactive map and discover the synchrotron, beamlines and much more. For a more in depth insight, visit our Virtual Visit page ...
[3]
None
Below is a merged summary of the key facts and figures about Diamond Light Source (2023/24) based on the provided segments. To retain all information in a dense and organized manner, I will use a combination of narrative text and tables in CSV format where appropriate. The response consolidates overlapping data while preserving unique details from each segment.
[4]
Governance - - Diamond Light Source
Diamond Light Source Ltd was established in 2002 as a joint venture limited company funded by the UK Government through the Science and Technology Facilities ...
[5]
[PDF] Diamond Light Source Introduction and Overview
Sited on Harwell Science and Innovation Campus. Largest scientific facility to built in the UK for over 40 years. Opened for operations in January 2007.
[6]
Funding for Diamond-II approved
The investment will see 86% come from the UK Government and 14% from Wellcome, the same proportion that has funded Diamond from its beginning.
[7]
[PDF] Evolution of the DIAMOND Light Source
Initial plans had been for a 16 cell, 3 GeV storage ring with a TBA lattice, in part because of a proposed scheme to upgrade the source by replacing central ...
[8]
Synchrotron Radiation Source - ASTEC
The below tells the story of the development of one the most useful and widely used scientific instruments of late 20th and early 21st century.
[9]
[PDF] The DIAMOND Project: An Advanced Light Source for the UK - JACoW
The formal Design Phase was initiated in. November 2000 with scheduled completion early in 2002; a storage ring with an energy of 3 GeV, a 24 cell structure and ...
[10]
Celebrating 22 years of Diamond Light Source
Today marks a milestone in Diamond's annual calendar as on the 27th March, 2002, Wellcome Trust and the UK Government signed the Joint Venture agreement ...
[11]
[PDF] Diamond Light Source Ltd Review 2017/18
Hears from the board and makes wider strategic decisions. Diamond Light Source Ltd was established in 2002 as a joint venture limited company funded by the UK ...Missing: history | Show results with:history
[12]
Diamond Light Source: The Jewel in the Crown of UK Science and ...
Dec 17, 2015 · The construction of Diamond began in South Oxfordshire in March 2003; the first seven beamlines opened their doors for users in January 2007. It ...
[13]
Diamond First Observation of Synchrotron Light
May 30, 2006 · Diamond's accelerator team achieved stored beam in the 561.6 metre Storage Ring, which in turn allowed the first observation of synchrotron light.Missing: construction history groundbreaking
[14]
Diamond Light Source: status and perspectives - Journals
Mar 6, 2015 · A limited company, Diamond Light Source, was formed in April 2002 to design, build, operate and eventually decommission the facility.
[15]
Her Majesty the Queen Officially opens Diamond Light Source
Oct 19, 2007 · Her Majesty The Queen, accompanied by His Royal Highness The Duke of Edinburgh, officially opened Diamond Light Source, the UK's new national ...Missing: history | Show results with:history
[16]
[PDF] The Diamond Light Source - The CERN Accelerator School
Sep 12, 2007 · 2007 Official Opening. Page 18. Diamond Light Source Ltd. Shareholders. The Wellcome Trust is an independent charity funding research to ...
[17]
Commissioning of the diamond light source storage ring vacuum ...
The pressure in the storage ring is 4.2 10-10 mbar without beam, rising to 7.9 10-10 mbar with 125 mA of stored beam. Data on the storage ring vacuum ...
[18]
A decade of success for Diamond Light Source | Laboratory News
Jul 12, 2012 · Over the next five years, the Diamond synchrotron grew literally from the ground up – 1,500 concrete piles were anchored into the chalk bed 15 ...
[19]
Inside the Machine - - Diamond Light Source
By the end of 2012, Phase II was complete and there were 22 operational beamlines. Further funding for a Phase III of construction was then granted and the ...
[20]
Governance and Management - - Diamond Light Source
Simon Jeffreys Wellcome Trust representative; Prof Tony Ryan Pro Vice ... STFC; joining STFC after many years in the R&D Division of Pfizer.
[21]
[PDF] Non-Executive Director, Diamond Light Source Ltd candidate ... - UKRI
Diamond is a limited company registered in the UK and governed by a Board comprising eight Directors including: two Executive Directors (the Chief Executive.
[22]
Management Team and Board of Directors - - Diamond Light Source
Board of Directors ; Prof Sir Leszek Borysiewicz Read biography. Chair ; Prof Gianluigi Botton Read biography. CEO of Diamond Light Source ; Andrea Ward Read ...
[23]
Diamond Light Source Management Team | Org Chart - RocketReach
Gianluigi Botton (Chief Executive Officer) | Andrea Ward (Chief Financial Officer and Deputy CEO (Board Member)) | Sarah Macdonell (Head of Engineering) ...
[24]
Governance and Management - - Diamond Light Source
Diamond Light Source Ltd was established in 2002 as a joint venture limited company funded by the UK Government via the Science and Technology Facilities ...
[25]
Diamond User Committee - Diamond Light Source
Diamond Light Source is the UK's national synchrotron science facility, located at the Harwell Science and Innovation Campus in Oxfordshire.Missing: statistics | Show results with:statistics
[26]
Publication of the Diamond Annual Review
Nov 20, 2024 · The 2023/2024 Annual Review of Diamond Light Source reveals a challenging and successful year for its scientists and 14,000 users.Missing: key facts
[27]
The launch of the START project: how Diamond Light Source is ...
May 20, 2019 · The START project will bring African researchers to Diamond so that they can engage with both the excellent facilities and the excellent staff, ...
[28]
Policy Statement - - Diamond Light Source
Diamond is committed to injury and ill-health prevention, minimisation of pollution and resource usage and promotion of positive mental and physical wellbeing.Missing: governance | Show results with:governance
[29]
Code of Best Practice in the Conduct of Scientific Research
In cases of misconduct in research by an approved user, Diamond reserves the right to take any action it deems appropriate, including bringing their misconduct ...
[30]
Experimental Data Management - - Diamond Light Source
Dec 10, 2018 · After the Embargo Period, Diamond may make Experimental Data available on an open access basis under a CC-BY-4.0 licence.
[31]
Diamond Welcome first User
February 2007. This week marks the dawn of a new era of scientific endeavour as Diamond Light Source, the UK's brand new synchrotron facility, ...
[32]
[PDF] Socio-Economic Impact Study Report | UKRI
Diamond Light Source Industrial Liaison Office. 6.2.3. Diamond's response to ... Since 2008, the number of industrial customers using Diamond for their research ...
[33]
[PDF] Current Commentary - The Diamond Light Source - NCBI
The Diamond facility cost an initial £260 m to build, including the ... The following examples are taken from the Diamond Annual Review 2014: http ...<|control11|><|separator|>
[34]
£520 million to add three beamlines to U.K.'s National Synchrotron
The amount represents the same proportion that has funded Diamond Light Source since it was established in 2002. The £519.4M funding for Diamond-II was ...
[35]
Diamond's socio-economic impact of over £2.6 billion on UK science ...
£589 million in direct benefits to individual users through access to beamtime and support – which has been inferred from the fees that users are willing to pay ...
[36]
How to Find Us - - Diamond Light Source
Jan 28, 2019 · Diamond is at Harwell Science and Innovation Campus, Didcot, Oxfordshire, OX11 0DE. Go to RAL Main Gate, notify reception, and get a pass. ...
[37]
Diamond Light Source - Harwell Science and Innovation Campus
Diamond Light Source is a world-leading medium energy synchrotron facility producing high intensity x-rays. It works like a giant microscope.
[38]
Storage Ring - - Diamond Light Source
Diamond's storage ring consists of twenty five straight sections angled together to form a closed loop. Large electromagnets (called dipole magnets, or bending ...
[39]
Support Facilities - - Diamond Light Source
In addition to the beamline experimental stations, Diamond provides an extensive range of support facilities for users.
[40]
Travel & Subsistence - eBIC - Diamond Light Source
Diamond Light Source is the UK's national synchrotron science facility, located at the Harwell Science and Innovation Campus in Oxfordshire. Copyright © Diamond ...
[41]
Scientific Software, Controls and Computation - Diamond Light Source
A year long process of procurement and installation brings into service a new data centric HPC computing platform for the acquisition and analysis of scientific ...
[42]
eBIC: The UK National Cryo-EM Facility - Diamond Light Source
eBIC is a CryoEM center providing scientists with state-of-the-art experimental equipment and expertise in the field of cryo-electron microscopy.People · User Guide · eBIC Capabilities · Current Calls
[43]
Taking the train, taxi or bus - - Diamond Light Source
The Harwell Science and Innovation Campus is six miles south-west of Didcot Parkway station, less than 60 minutes journey from London Paddington.
[44]
The big switch on: solar panels fully operational at Diamond
Jul 15, 2024 · The facility has introduced a renewable energy solution, emphasising sustainability and cost-effectiveness.
[45]
Corporate Social Responsibility - - Diamond Light Source
Diamond Light Source considers the effective management of its environmental policy including energy usage to be an important corporate responsibility.Missing: low- rainwater harvesting green
[46]
[PDF] Effect of Insertion Devices on Beam Dynamics of the Diamond ...
The Diamond storage ring [1] is a 24 cell DBA lattice with a nominal emittance of 2.7 nm, obtained by breaking the achromatic condition in the straight sections ...
[47]
Machine - - Diamond Light Source
Nov 25, 2019 · STORAGE RING PERFORMANCE. Storage Ring Main Parameters. Energy. 3 GeV. Circumference. 561.571 m. Maximum beam current. 300 mA. Horizontal ...Missing: design | Show results with:design
[48]
B22 Contact - Diamond Light Source
Dipole aperture, 50 mrad (H) x 30 mrad (V) ; Diamond storage ring, E=3 GeV and I=500 mA ; Dipole source. Heat load: peak value 8 W/mm2 @ 5 m and +40mrad; Bending ...
[49]
Commissioning of the diamond light source storage ring vacuum ...
The pressure in the storage ring is 4.2 10-10 mbar without beam, rising to 7.9 10-10 mbar with 125 mA of stored beam. Data on the storage ring vacuum ...
[50]
[PDF] Insertion Devices at Diamond Light Source - Inspire HEP
Phase I saw the installation of seven insertion devices: five in-vacuum pure permanent magnet undulators (IVUs), one. APPLE-II undulator, and a superconducting ...
[51]
[PDF] Long-term Stability of the Diamond Light Source Storage Ring
The machine usually runs in top-up mode, at a typical current of 300 mA, with differ- ent injection patterns. The typical lifetime is presently 16 hr. The ...
[52]
Diamond Light Source: status and perspectives - PMC
The Synchrotron Radiation Source (SRS) at Daresbury was an accelerator with small (96 m) circumference and relatively low electron energy (2.0 GeV) and X-rays ...Missing: motivations | Show results with:motivations
[53]
[PDF] Status of the DIAMOND LIGHT SOURCE Project
generate an electron beam of extremely high brightness. (emittance 2.7 nm-rad) with excellent dynamic properties permitting long beam lifetimes (10–20 hrs).
[54]
Welcome to B18 - - Diamond Light Source
Beamline B18 covers the energy ranges of both I18 and I20. It is used for an extensive range of studies that underpin research programmes across a wide range of ...
[55]
[PDF] diamond light source annual review 2023/24
The high-energy electron Xtallography Instrument (HeXI) funded by. Wellcome will further enhance the MX group's capabilities to perform micro to nano crystal ...Missing: ownership | Show results with:ownership
[56]
Beamline Development and Technical Summary
Diamond is now operating with 32 beamlines and 11 electron microscopes. The next year will see the completion of the latest phase of construction.
[57]
[PDF] A 10-Year Vision for Diamond Light Source
The Diamond Light Source has been operational for 8 years, providing brilliant beams of light to probe the structure and composition of matter in the most ...
[58]
Welcome to DIAD - - Diamond Light Source
The Dual Imaging And Diffraction (DIAD) beamline is dual beam X-ray instrument for imaging, diffraction and scattering, which operates at energies of 7-38 keV.Missing: 2024 | Show results with:2024
[59]
Welcome to I11 - Diamond Light Source
Beamline Phone Number: +44 (0)1235 778905. Principal Beamline Scientist: Stephen Thompson Tel: +44 (0)1235 778546. E-mail: stephen.thompson@diamond.ac.uk.Missing: list | Show results with:list<|control11|><|separator|>
[60]
Imaging and Microscopy - Diamond Light Source
Imaging and Microscopy is a newly formed science group, which brings together eight experimental facilities (I08, I08-1 (J08), DIAD, I12, I13-1, I13-2, I14 and ...
[61]
Diamond in Detail
The IP on discoveries made by employees of Diamond Light Source is owned by Diamond. Industrial researchers may opt not to publicly release their results ...Missing: ownership | Show results with:ownership
[62]
How Diamond is underpinning the UK's industrial strategy
It has directly supported proprietary work for over 130 companies, and about 40% of all delivered beamtime in FY2017/18 had direct or indirect industrial access ...Missing: percentage | Show results with:percentage
[63]
Small Molecule X-ray Crystallography - Diamond Light Source
Diamond's facilities allow for high-resolution, atomic-resolution 3D structure determination, with high photon flux, low divergence, and rapid data collection.
[64]
Scattering - SAXS and WAXS - - Diamond Light Source
Small Angle X-ray Scattering provides essential information on the structure and dynamics of large molecular assemblies in low ordered environments.
[65]
XAS: X-ray Absorption Spectroscopy - - Diamond Light Source
Combining the high brightness with the small spot size available makes it possible to examine samples with very high spatial resolution. Applications. X-ray ...
[66]
Tomography - - Diamond Light Source
X-ray tomography creates a 3D image from 2D projections at different orientations, using phase or absorption contrast imaging.
[67]
XPS: X-ray Photoelectron Spectroscopy - - Diamond Light Source
XPS can be used to analyse the surface chemistry of a material after an applied treatment such as fracturing, cutting or scraping. From characterisation of ...
[68]
Applications - - Diamond Light Source
Applications include developing spectral biomarkers for disease diagnosis - particularly cancer research, location of stem cells within tissues.Missing: capabilities | Show results with:capabilities
[69]
In situ characterization of the phase diagram of Ir via X-ray diffraction ...
Oct 13, 2025 · For some metals, these stresses can reach 900 GPa at a pressure of 300 GPa. ... Diamond Light Source. This factor also explains the ...
[70]
Advanced Chemical Analysis & Operando Studies
Explore how Diamond Light Source empowers chemical innovation through advanced synchrotron techniques. From operando studies of catalytic reactions to ...
[71]
VMXm - - Diamond Light Source
VMXm is a micro/nanofocus Macromolecular Crystallography (MX) beamline designed for atomic structure determination in situations where producing large ...
[72]
BART – the new robotic sample changer for MX beamlines at Diamond
BART – the new robotic sample changer for MX beamlines at Diamond. Katherine ... Diamond Light Source is the UK's national synchrotron science facility ...
[73]
The granular behaviour of semi-solid alloys revealed using 4D ...
Diamond Light Source's Joint Engineering, Environment, and Processing beamline (I12) has revealed, for the first time, how semi-solid materials develop at the ...
[74]
Diamond honours Margaret Hamilton in the naming of their new ...
Feb 11, 2019 · It will initially provide the facility eight petabytes of storage ... Diamond Light Source is the UK's national synchrotron science ...
[75]
Advancing UK Science Goals - - Diamond Light Source
Diamond Light Source plays a vital role in engineering biology, using advanced X-ray and imaging techniques to study biological structures at the atomic level.Missing: capabilities | Show results with:capabilities
[76]
General Questions - - Diamond Light Source
Diamond Light Source is a synchrotron – a particle accelerator that accelerates electrons up to very high speeds. These electrons produce very bright beams ...
[77]
Gianluigi Botton: maintaining the Diamond synchrotron's cutting edge
Jul 25, 2024 · Diamond serves a user community of around 14,000 scientists working ... The Diamond Light Source A brilliant place The Diamond Light Source ...
[78]
From nought to sixty in six months…the unmasking of the virus ...
Nov 10, 2020 · A new video animation has been released showing how the SARS-CoV-2 (or COVID-19) virus infection mechanism works at the cellular level.
[79]
Improved antihistamines - - Diamond Light Source
Jun 22, 2011 · Histamine H1 receptor breakthrough heralds improved allergy treatments. New 3D picture of human membrane protein enables development of ...<|separator|>
[80]
Solution to plastic pollution on the horizon - - Diamond Light Source
Apr 16, 2018 · The bacterium had the amazing ability to degrade PET and use it to provide carbon for energy. Central to this ability was the production of a ...
[81]
A breakthrough in lithium-ion battery research - Diamond Light Source
Jan 17, 2025 · We're building 2.5 Amp cells and combining operando X-ray studies at Diamond with operando neutron studies at the Isis Neutron and Muon ...
[82]
New Research provides crucial information on degradation ...
A new paper provides crucial information on the degradation processes which will be used to develop remediation strategies to save the Mary Rose.
[83]
Uncovering ancient text from the Oxford Herculaneum scroll
Feb 5, 2025 · In July 2024, Diamond's powerful light enabled a team from the nearby Bodleian Libraries to scan a 2,000-year-old Herculaneum scroll.
[84]
how a Moths invisibility cloak could lead to bio-inspired sound ...
Jun 23, 2023 · Researchers from University of Bristol and Diamond Light Source have uncovered how moths create a powerful stealth cloak preventing detection by biosonar.
[85]
Sustainable nuclear graphite research powered by Diamond
Diamond Light Source will aid research which aims to transform the lifecycle of graphite in nuclear energy.Missing: safety | Show results with:safety
[86]
Open science yields broad-spectrum coronavirus antiviral
The candidate is a result of research from the COVID Moonshot initiative which originated at Diamond Light Source. It is a main protease inhibitor that ...Missing: spin- offs
[87]
Lattice design for the Diamond-II light source storage ring
Nov 22, 2024 · A novel multibend achromat (MBA) lattice structure has been developed for the Diamond-II storage ring upgrade.
[88]
Diamond-II
Recordings now available! news. Sisk set to deliver £25M Diamond Light Source extension building May 14, 2024.
[89]
[PDF] Diamond-II | Conceptual Design Report
This disruptive technology became a reality in 2016 with the start-up of operations of MAX IV, the world's first multibend-achromat (MBA) light source [2].
[90]
[PDF] Upgrades to the Injector Complex for Diamond-II - Indico Global
Diamond Light Source is the UK's national synchrotron radiation facility ... Linac-To-Booster (LTB). I Martin, Upgrades to the Injector Complex for ...
[91]
Visit to Diamond Light Source launches £500m upgrade programme
Sep 7, 2023 · Professor Sir Adrian Smith, Chair of Diamond; Professor Mark Thomson, STFC Executive Chair; Dr Beth Thompson, Chief Strategy Officer at Wellcome.Missing: representatives | Show results with:representatives
[92]
Sisk set to deliver £25M Diamond Light Source extension building
May 14, 2024 · Sisk has been selected to build a brand new £25M building as part of the Diamond-II upgrade for Diamond Light Source (Diamond), the UK's national synchrotron.
[93]
Machine Operation and Development - - Diamond Light Source
Dec 20, 2024 · The 97% uptime was however below the target of 98% for many reasons including various new faults which consequently took longer to rectify, as ...Missing: maintenance | Show results with:maintenance
[94]
K04 Ultra-high throughput beamline for MX and XChem
The Diamond-II machine configuration necessitates removing beamline I04-1, providing the opportunity to rebuild it on the new K04 straight, delivering a ...
[95]
Flagship Beamlines - - Diamond Light Source
The delivery of the Flagship beamlines will be phased over the duration of the project, with our K04, SWIFT and CSXID beamlines being delivered for day-one ...
[96]
An Innovative Update and Expansion Programme to the UK's ...
Mar 12, 2024 · ... Diamond Light Source is the UK's national synchrotron light sourc ... straight sections where insertion devices can be installed. Figure 1 ...<|separator|>
[97]
Beamline - Diamond Light Source
A beamline has four major sections: Front end where light is extracted from the storage ring; Optics hutch where certain wavelengths of light are selected ...
[98]
Diamond Light Source - RFI - Rosalind Franklin Institute
Diamond Light Source may be The Franklin's newest member, officially joining in September 2019, but its involvement in the Institute dates back to The ...<|control11|><|separator|>
[99]
New Active Materials Lab opens at Diamond Light Source
Today, 30th November 2022, the new Active Materials Laboratory at Diamond was officially opened by Dr Robin Ibbotson, Chief Technology Officer at Sellafield ...
[100]
Diamond Active Materials Laboratory | National Nuclear User Facility
Delivering new opportunities for active materials research at Diamond Light Source: an Active Materials Laboratory. PI: Prof Fred Mosselmans
[101]
[PDF] Diamond Light Source ANNUAL REVIEW 2022/23
The key commitments of our strategy for sustainable operations include the following: Decision Making & Engagement: We will embed environmental sustainability ...Missing: history | Show results with:history
[102]
Diamond Light Source Project - Fan Conversion by STULZ
See how STULZ boosted cooling efficiency at Diamond Light Source by upgrading fans and cutting energy use.
[103]
First Fellows from SESAME Project welcomed at Diamond
The UK's synchrotron science facility Diamond Light Source has welcomed the first four fellows on the newly created Diamond SESAME Rutherford Fellowship ...
[104]
Synchrotron Radiation School 2025 - - Diamond Light Source
The Synchrotron Radiation School introduces postgraduates to SR experiments, with lectures, experiments on beamlines, and a symposium, held at Diamond and ...
[105]
Full article: Synchrotron Radiation School at Diamond Light Source
Feb 2, 2011 · Jesus College, Oxford, provided the stylish setting for the second Diamond Synchrotron Radiation School, which was held in September 2010.
[106]
About Us - - Diamond Light Source
Diamond Light Source is the UK's national synchrotron serving scientists and researchers from around the world. It is a not-for-profit joint venture funded ...How Diamond Works · Diamond's Core Values · Vision
[107]
[PDF] A Strategic Vision for the UK's Large-Scale Light Source User Facilities
Diamond Light Source, to date, while the CLF's suite of laser systems typically have over 500 total users each year. UK researchers also make significant use.