Latest-News – Page 2 – Lightsources.org

President of the Federal Republic of Germany visits SESAME laboratory

2026/02/182026/02/19

During a state visit to Jordan today, His Excellency Frank-Walter Steinmeier, President of the Federal Republic of Germany, took time out to visit the SESAME laboratory north-west of the capital Amman. In November last year, Germany announced its intention to become an Associate Member of SESAME, cementing the country’s already long-standing support for the Laboratory. At the end of his visit, the President signed the Laboratory’s guest book, in the company of SESAME Director Dr Khaled Toukan and young researchers from across the region: “I am fascinated by the succeeding cooperation of so many countries in the Middle East and worldwide. This important work of researchers shows what a treasure international cooperation to the benefit of all of us is. Germany continues to support this place of science in the years to come.”

Germany’s relationship with SESAME goes back to the origins of the laboratory. It was the donation of the BESSY I synchrotron that allowed the fledgling SESAME to establish itself as an intergovernmental organisation in 2004. BESSY I components today form the injector for the SESAME main ring accelerator. Germany has been an Observer to the SESAME Council since its establishment in 2004.

Read more on the SESAME website

Image: H.E. Frank-Walter Steinmeier and H.E. Khaled Toukan with the scientists at the ID11L-HESEB and ID11R-TXPES beamlines.

Credit: © SESAME 2026

Capturing Ghosts

2026/02/182026/02/26

Quantum “ghost imaging” technique paves the way for nanoscale-resolution images at a lower X-ray dose.

A group of researchers led by scientists at the National Synchrotron Light Source II (NSLS-II), a U.S. Department of Energy (DOE) Office of Science user facility at DOE’s Brookhaven National Laboratory, is exploring a quantum-inspired imaging approach that could set the stage for obtaining high-resolution data while reducing X-ray exposure. The method relies on pairs of quantum-entangled X-ray photons, linked particles of light from the same origin that share properties and information. In each entangled pair, one photon interacts with a sample while its partner does not. By analyzing these pairs, the team demonstrated that information carried by the untouched photon can be used to form an image, complementing information obtained from its partner. This early proof of concept could ultimately enable longer, lower-dose studies of delicate biological materials, such as plant tissues, and may one day inform lower-dose medical imaging. Their results were published in Optica.

Seeing “ghosts”

Quantum “ghost” imaging is a technique that is as intriguing as its name suggests. In conventional X-ray imaging, X-ray photons directly interact with the sample being studied. Ghost imaging, instead, uses pairs of photons that are created together and share linked properties, known as quantum correlations. One photon from each pair travels through the sample, while its partner never interacts with it at all. Despite this, the untouched photon behaves as if it has encountered the sample.

Read more on the BNL website

Image: A conceptual schematic of “ghost imaging” displays the samples being imaged, which include a cat-shaped tungsten test pattern and an E. cardamomum seed. The objects are placed inside a ring on the lower two detector chips, while the upper chips are left open. By measuring paired X-ray signals at the same time, the system produces two matching images.

Credit: Valerie A. Lentz/Brookhaven National Laboratory

Measuring time at the quantum level

2026/02/182026/02/26

Physicists using the Swiss Light Source SLS have found a way to measure the time involved in quantum events and found it depends on the symmetry of the material.

“The concept of time has troubled philosophers and physicists for thousands of years, and the advent of quantum mechanics has not simplified the problem,” says Hugo Dil, a physicist at Paul Scherrer Institute PSI and professor at EPFL. “The central problem is the general role of time in quantum mechanics, and especially the timescale associated with a quantum transition.”

Quantum events, like tunnelling, or an electron changing its state by absorbing a photon, happen at mind‑bending speeds. Some take only a few tens of attoseconds (10-18 seconds), which is so short that light would not even cross the width of a small virus.

But measuring time intervals this small is notoriously difficult, also because any external timing tool can distort the very thing we want to observe. “Although the 2023 Nobel prize in physics shows we can access such short times, the use of such an external time scale risks to induce artefacts,” says Dil. “This challenge can be resolved by using quantum interference methods, based on the link between accumulated phase and time.”

Measuring quantum time without an external clock

Dil and his team from EPFL have now led research that has developed a way to accurately measure time in quantum events. When electrons absorb a photon and leave a material, they carry information in the form of their spin, which changes depending on how the underlying quantum process unfolds. By reading these tiny changes, the researchers could infer how long the transition takes, without ever using an external clock.

Read more on the PSI website

Image: Quantum events can unfold on attosecond timescales, making them notoriously difficult to measure. Researchers have now devised a way to measure the duration of quantum transitions without relying on an external clock.

Credit: © EPFL 2026/iStock (bymuratdeniz)

Filming a vitamin B12 photoreceptor in action

2026/02/132026/02/19

Using X-ray free-electron lasers and synchrotron light at facilities in Switzerland, Japan, France and the UK, a worldwide collaboration of scientists have discovered how a vitamin B12-based photoreceptor works. Understanding how photoreceptors function aids future technological applications, such as optogenetics, that involve controlling cellular processes with light. The findings are published in Nature.

Vitamin B12 is an organometallic cofactor found in many enzymes that control essential processes in various organisms, including humans. It came as a surprise a decade ago that vitamin B12 derivatives had been repurposed for light sensing by a large family of previously unknown photoreceptors in bacteria that fulfil various functions.

The prototypical B12 photoreceptor CarH, for example, regulates the expression of genes involved in protecting bacteria against excess sunlight. It achieves this by binding to DNA in the dark, acting as a molecular doorstop. Upon illumination, its tetrameric architecture breaks apart, enabling transcription by unbinding from DNA.

The way in which this and other B12 photoreceptors function at a molecular level has remained a mystery ever since. However, an international consortium led by scientists at the Institut de Biologie Structurale in Grenoble, France has now combined experimental techniques using X-ray free-electron lasers at the Paul Scherrer Institute PSI in Switzerland (SwissFEL) and Japan (SACLA), as well as the synchrotrons in France (ESRF) and the UK (Diamond Light Source), with quantum-chemical calculations to uncover the inner workings of CarH.

Read more on the PSI website

Image: John Beale is responsible for macromolecular crystallography at the Cristallina experimental station of SwissFEL

Credit: © Paul Scherrer Institute PSI / Markus Fische

European XFEL celebrates a successful restart

2026/02/112026/02/19

European XFEL today celebrated the restart of the world’s largest X-ray laser with a ceremony attended by Hamburg’s Senator for Science Maryam Blumenthal and Guido Wendt, State Secretary in Schleswig-Holstein’s Ministry of Education, Science, Research and Culture. This was preceded by a so-called Long Installation and Maintenance Period (LIMP) with maintenance work and numerous upgrades to the infrastructure in underground tunnels and the scientific instruments on the European XFEL campus.

Employees of European XFEL and DESY, who were significantly involved in the extensive work, watched as Blumenthal and Wendt started the electron accelerator with a click of a mouse. Electron packets now speed again through the accelerator section to the so-called dump after about two-thirds of the 3.4-kilometre-long facility. The remaining parts of the X-ray laser, where the X-ray light is generated using the accelerated electrons, and the experiment stations will go into operation in the coming days and weeks. After more than seven months, the facility will be available to researchers again from mid-April.

Innovations for scientific excellence

At the ceremony in the Lighthouse visitor centre, European XFEL Managing Director Prof. Thomas Feurer emphasized the importance of the modification and upgrade work for the long-term performance, reliability and scientific excellence of the large-scale research facility. In addition to the successful maintenance work, for which the accelerator, which normally operates at minus 271 degrees Celsius, was warmed to room temperature and then cooled down again, teams from European XFEL and the DESY research centre installed numerous technical innovations to further expand the research options at the X-ray laser. Important upgrades include the new GUN5 electron source, which enables a pulse rate that is around 30 percent higher, and the expansion of beamlines and instruments for attosecond experiments, which can be used to observe ultrafast processes such as the formation of chemical bonds. In addition, preparatory work has been completed for the installation of superconducting undulators, which will deliver particularly short and highly intense X-ray pulses with very short wavelengths, enabling researchers to achieve even better resolution, among other things.

Read more on the European XFEL website

Image: Thomas Feurer emphasized the smooth cooperation between European XFEL and DESY, involving many teams from different disciplines.

Credit: European XFEL

ESRF X-rays capture vitamin B12 sensing light

2026/02/102026/02/12

Scientists led by the Institut de Biologie Structurale have combined advanced X-ray methods to unveil how a photoreceptor regulates carotenoid production in bacteria, including experiments at the ESRF. The results are out in Nature.

CarH is a photoreceptor which senses light through a vitamin B12 derivative and regulates carotenoid expression through direct interaction with genes. Bacteria use this remarkable machinery to regulate gene expression and produce carotenoid to protect themselves from photo-damage upon sun exposure. What scientists had never seen before was how tiny photoinduced changes at the vitamin B12 level, propagate into large-scale structural changes triggering a biological response. Now, an international collaboration has managed to film this process in unprecedented detail, with key experiments carried out at the ESRF and at XFELs.

CarH’s role has been clear since around 2015. In the dark, the protein binds to DNA and blocks the production of carotenoids. When light is present, CarH releases the DNA, allowing the cell to produce carotenoids that help defend against light-induced damage.

Previous crystal structures revealed the start and end points of this process. But the crucial missing piece was the journey in between — from the short-lived structural changes that occur immediately after light hits the vitamin B12 molecule to the large-scale conformational changes involving the whole protein structure and its interaction with DNA.

Read more on the ESRF website

Image credit: CEA and Maria Davila Miliani

Argonne celebrates successful completion of the APS Upgrade

2026/02/052026/02/10

The U.S. Department of Energy has granted its final approval to the project, bringing the decade-plus-long effort to a close

The upgraded APS is now the brightest synchrotron X-ray light source in the world, and extraordinary new scientific experiments are underway.

The comprehensive upgrade of the Advanced Photon Source (APS) is officially completed.

The U.S. Department of Energy (DOE) has given its final approval to the APS Upgrade Project, an $815 million effort to transform the APS into the brightest synchrotron X-ray facility in the world. The effort has taken more than a decade to plan and complete and has resulted in a facility with unprecedented capabilities for scientific discovery. The APS is a DOE Office of Science user facility at DOE’s Argonne National Laboratory.

The upgraded APS now generates X-ray beams that are up to 500 times brighter than before and sports nine new experiment stations (called beamlines) built to take full advantage of those enhanced beams. Scientists have been using the revamped facility for more than a year, exploring its new capabilities for research into more durable materials (for airplane turbines and other high-stress uses), longer-lasting batteries (for laptops and cell phones) and microelectronics (for our device-driven modern lives).

Read more on the Argonne website

Image: Advanced Photon Source

Credit: Argonne National Laboratory

Enhanced rice could address iron deficiencies around the world

2026/02/042026/02/05

Rice is one of the most consumed foods in world: “In places like Bangladesh, almost 80 per cent of the calories that people consume come from rice.”

“About two billion people are suffering from iron deficiency, which makes people sick and can even cause death,” says Felipe Ricachenevsky, a professor with the Federal University of Rio Grande do Sul in Brazil.

He and colleagues in Brazil, Italy, Chile, and Germany are working to increase the amount of iron in rice, one of the most consumed foods in the world. “In places like Bangladesh, almost 80 per cent of the calories that people consume come from rice. So, if there isn’t enough iron in rice, then people aren’t getting enough iron,” he explains.Video: Enhanced rice could address iron deficiencies around the world

Studies have shown it is possible to increase iron content in rice by modifying an individual gene in the plant. Building on this work, Ricachenevsky and colleagues altered two similar genes in the same plant, hoping it would produce an even greater increase in iron content.

They then used the Canadian Light Source (CLS) at the University of Saskatchewan to analyze their modified rice. The team also imaged their samples at the Brazilian Synchrotron Light Laboratory (SIRIUS) in Campinas, Brazil.

Read more on the CLS website

Image: Felipe Ricachenevsky, centre, with the research team

Credit: CLS

MXene for energy storage: More versatile than expected

2026/02/032026/02/05

MXene materials are promising candidates for a new energy storage technology. However, the processes by which the charge storage takes place were not yet fully understood. A team at HZB has examined, for the first time, individual MXene flakes to explore these processes in detail. Using the in situ Scanning transmission X-ray microscope ‘MYSTIIC’ at BESSY II, the scientists mapped the chemical states of Titanium atoms on the MXene flake surfaces. The results revealed two distinct redox reactions, depending on the electrolyte. This lays the groundwork for understanding charge transfer processes at the nanoscale and provides a basis for future research aimed at optimising pseudocapacitive energy storage devices.

Energy storage is crucial for achieving a climate-neutral and efficient energy supply, based on renewable energy sources. Current technologies have their pros and cons. Batteries, for example, require a certain amount of time to charge but can store enormous amounts of energy, whereas electric double-layer capacitors (EDLCs) charge quickly but can only absorb a limited amount of energy. So called pseudocapacitors could combine high storage capacity with speed, due to a charge transfer process based on chemical changes without changing the phase of material. Up to now, this technology has not yet been realised due to a lack of promising materials.

The hidden talents of MXenes

This might change with MXene materials. MXenes are two-dimensional materials with a layered structure, such as titanium carbide, which form a conductive core and a highly reactive surface. The distance between layers is in the order of a few nanometers. Via aqueous electrolytes, protons and Li ions can intercalate between MXene layers and act as charge carriers. The charge carriers bind to the surface terminations on the Titanium atoms via redox reactions. Another advantage: Aqueous electrolytes are generally much more environmentally friendly than organic electrolytes used in batteries.

Read more on the HZB website

Image: In a neutral electrolyte Li₂SO₄ the interaction of partially desolvated Li⁺ ions and water with the MXene surface results in an increased Titanium oxidation state. The two different chemical behaviours also change the interlayer spacing of the flakes.

Credit: © Energy & Environmental Science / HZB

Lasing achieved with hard X-rays in a resonator

2026/01/282026/01/29

Novel “XFELO” laser system produces razor-sharp X-ray light

For the first time, researchers have amplified X-ray light multiple times in a resonator cavity, in a way highly similar to traditional lasers. With great success: the new technique delivers extremely energetic X-ray pulses for high-precision experiments. This development opens up entirely new possibilities for research in physics, chemistry, or biology. The system is called “XFELO”. Researchers from European XFEL, DESY and Hamburg University have published their findings in the latest edition of the journal Nature.

The team of engineers and scientists have shown for the first time that a hard-X-ray cavity can provide net X-ray gain, with X-ray pulses being circulated between crystal mirrors and amplified in the process, much like happens with an optical laser. The result of the proof-of-concept at European XFEL is a particularly coherent, laser-like light of a quality that is unprecedented in the hard X-ray spectrum. Lasing inside a cavity had been challenging to achieve with short-wavelength X-rays for a variety of reasons, including – on a basic level – that the nature of the light makes it difficult to reflect the beam at large angles. The “XFELO” (short for: X-Ray Free-Electron Laser Oscillator) technique opens new perspectives for scientific investigations, from ultrafast chemical reactions to detailed analyses of the smallest biological structures.

Read more on the European XFEL website

Image: Illustration of the XFELO system: a hard X-ray pulse (red) is reflected by a set of diamond mirrors and oscillates through arrays of magnets, so called undulators. On each roundtrip the pulse meets a new electron bunch (blue), which emits X-rays while passing through the undulators on a slalom course.

Credit: European XFEL

Thin-Film Coating Boosts X-Ray Instrument Performance

2026/01/272026/02/12

Researchers developed optimized coatings for diffraction gratings at the Advanced Light Source (ALS) that use thin-film interference to double the light reaching the sample, capturing power otherwise lost to absorption.

Every soft x-ray beamline monochromator uses gratings and can benefit from increased diffraction efficiency.

How to win back lost x-rays

Soft x-rays allow us glimpses into the most fundamental properties of many materials by revealing what electrons are doing in a solid. But, the gratings that separate and bend x-rays in these studies struggle to deliver more than a small fraction of an incoming beam’s energy to its target. This has led researchers on a quest to improve the efficiency of gratings, without compromising the resolution of the output data.

Gratings are the key technology for soft x-ray experiments and most spectroscopy tools. Their periodic structures parse light into separate wavelengths, which are then either selected individually or dispersed across a detector. To achieve high resolution, these metal-coated gratings need an extremely high number of closely packed grooves. The grooves, however, are a double-edged sword: they deflect incoming x-rays toward the sample, but some x-rays are absorbed by the coating and cannot usefully contribute.

In this study, researchers sought to win back some of the x-rays that are lost. They examined how very thin metal coatings impacted a grating’s performance. The team, led by ALS Staff Scientist Dmitriy Voronov, tested gratings coated with atoms-thick layers of chromium (Cr) and gold (Au) and showed that an optimized configuration doubled the efficiency compared with standard designs.

Read more on the ALS website

Image: A silicon grating with half a million grooves and coated with atoms-thick layers of chromium and gold will provide higher energy resolution at Advanced Light Source Beamline 6.0.2 QERLIN. QERLIN is a double-dispersion resonant inelastic x-ray scattering (RIXS) beamline.

Diamond helps uncover a lost branch of life

2026/01/232026/02/05

Synchrotron infrared analysis helps reveal that enigmatic Devonian fossils were not fungi, but members of a previously unknown lineage of complex life

Researchers studying one of palaeontology’s longest-running mysteries have shown that Prototaxites, giant column-like fossils that dominated Earth’s earliest terrestrial landscapes, do not belong to the fungal kingdom, as long suspected. Instead, new evidence suggests they represent a completely distinct and now extinct branch of complex eukaryotic life.

The findings, published in Science Advances, were supported by experiments carried out on Diamond’s B22 infrared microspectroscopy beamline.

A 400-million-year-old puzzle

Prototaxites fossils date back more than 400 million years to the early Devonian period and could reach several metres in height, making them the largest known organisms on land at the time. They are typically preserved as massive, trunk-like columns found in some of the earliest terrestrial ecosystems, long before trees had evolved. For over 160 years, scientists have debated their biological identity, with fungi long considered the most likely explanation due to their tubular internal structure and lack of obvious plant features.

Read more on the Diamond website

Engineering Division pilots equipment protection interlock system for Berkeley Lab user endstations

2026/01/232026/01/28

A new user-configurable equipment protection interlock system that helps protect scientific equipment and users will provide more flexibility and reliability while improving safety at the Lab.

Equipment protection interlock systems are a vital component of the infrastructure for many types of scientific equipment and facilities, especially at Berkeley Lab facilities like the Advanced Light Source (ALS), BELLA, and the Joint Genome Institute. These specialized interlock systems control the mechanisms that prevent unsafe conditions when using equipment. Actions like protecting beamline slits and components from overheating fall to interlock systems that have been custom-configured to meet the specific requirements of equipment and experiments. The Engineering Division is currently piloting a system for Berkeley Lab that will make setting up and using equipment protection system interlocks safer, faster, and more consistent—with minimal training and no need for coding on the user side.

This new tool has been developed at the ALS in collaboration with the European Synchrotron Radiation Facility (ESRF). The underlying idea for the interlock system comes from ESRF, where more than 400 of the devices are already in use. When Ernesto Paiser, ALS Instrument Software Support Group Lead, formerly of ESRF, arrived at Berkeley Lab, he saw an opportunity to implement a similar system that would provide increased reliability and flexibility while improving safety and efficiency.

“When I started at the Lab,” says Paiser, “I was immediately confronted with numerous challenges related to the equipment protection system (EPS). One of the most significant issues was how complex and inaccessible the system was for end users when they needed to define or modify interlock requirements at the end stations. Even a minor request often required changes to the main front-end interlock program. Each modification triggered a full system retest, regardless of the scope of the change. In many cases, by the time the work was completed, the original request was no longer needed, yet the changes remained permanently embedded in the system.”

Read more on the LBL website

Image: Ernesto Paiser, ALS Instrument Software Support Group Lead, pictured with the new no-code interlock system.

Credit: Engineering Division

A breakthrough cyanide-bridged molecular magnet

2026/01/222026/02/18

Researchers at the Jagiellonian University have developed a new Prussian Blue analogue that exhibits ferrimagnetic ordering at a record-high temperature exceeding 400 K (127 °C). The discovery, reported in the Advanced Science article “Heavy Prussian Blue Analog with Magnetic Ordering above 400 K”, concerns a cyanide-bridged molecular magnet composed of vanadium(II) and molybdenum(III) ions, which replace the traditional iron ions found in the Prussian Blue structure. The experimental work described in the publication was carried out at SOLARIS on the ASTRA beamline.

The study reports the synthesis, structural analysis and magnetic characterisation of the amorphous compound {[K(crypt222)]_0.34V^II_1.37Mo^III(CN)₆(BF₄)_0.08·xCH₃CN} _n(V^II–Mo^III(CN)₆), demonstrating its ferrimagnetic behaviour up to 400 K (127 °C) – a temperature range previously inaccessible for conventional cyanide–bridged magnets.

Read more on the SOLARIS website

Image: A single frame from the video illustrating the behaviour of V^II–Cr^III(CN)₆ in a varying magnetic field between 0 and 0.5 T.

Contribution of the HERMES beamline to the study of “Tubenets”

2026/01/162026/01/20

Network-like structures built by bacteria inside insect cells to feed more efficiently

The cereal weevil, one of the world’s main crop pests, harbors symbiotic bacteria that live inside its cells. Scientists from INRAE and INSA Lyon, in collaboration with experts from the SOLEIL Synchrotron and Claude Bernard University in France, as well as the Max Planck Institute and EMBL in Germany, have discovered that these bacteria build complex, network-shaped membrane structures. These structures increase their surface area for exchange with the host cell, allowing the bacteria to absorb an essential nutrient: sugar.

This is the first time that bacterial structures of this scale have been observed. The SOLEIL’s HERMES beamline contributed to this discovery.

The cereal weevil is one of the major pests affecting cereals such as wheat, rice, and maize, both in the field and in storage. It feeds directly on the grains, but it is not alone: it hosts symbiotic bacteria that live inside its cells. These bacteria, named Sodalis pierantonius, reside in large numbers within specialized insect cells. They provide the weevil with essential nutrients that are absent from its cereal-based diet. This is a mutually beneficial relationship: the bacteria use the sugars produced during the digestion of grains and, in return, supply the insect with essential nutrients such as vitamins and certain amino acids.

While scientists have long understood the importance of this exchange, its exact mechanisms remained unknown. To investigate, the researchers used electron microscopy with an advanced sample preparation method that preserves membranes more effectively. For the first time, the team observed original tubular patterns forming complex membrane structures built by the bacteria. To study the architecture and composition of these structures, the scientists developed new 3D microscopy and analytical methods using the SOLEIL Synchrotron particle accelerator.

Read more on the SOLEIL website

Image: Scale 200 nm. Transmission electron microscopy image showing intracellular symbiotic bacteria from the cereal weevil Sitophilus oryzae. The bacteria form a three-dimensional network of tubular structures, called tubenets. These structures enhance host–bacterium nutritional exchanges, allowing efficient transfer of sugars from the host’s diet to the symbiotic bacteria. In purple, an example of a bacterium and its tubenets can be seen within the cytoplasm of the host cell.

Swiss X-ray laser reveals the hidden dance of electrons

2026/01/152026/01/15

Scientists at the X-ray free-electron laser SwissFEL have realised a long-pursued experimental goal in physics: to show how electrons dance together. The technique, known as X-ray four-wave mixing, opens a new way to see how energy and information flow within atoms and molecules. In the future, it could illuminate how quantum information is stored and lost, eventually aiding the design of more error-tolerant quantum devices. The findings are reported in Nature.

Much of the behaviour of matter arises not from electrons acting alone, but from the ways they influence each other. From chemical systems to advanced materials, their interactions shape how molecules rearrange, how materials conduct or insulate and how energy flows.

In many quantum technologies – not least quantum computing – information is stored in delicate patterns of these interactions, known as coherences. When these coherences are lost, information disappears – a process known as decoherence. Learning how to understand and ultimately control such fleeting states is one of the major challenges facing quantum technologies today.

Until now, although many techniques let us study how individual electrons behave, we have mostly been blind to these coherences. Scientists at SwissFEL from the Paul Scherrer Institute PSI and Swiss Federal Institute of Technology in Lausanne (EPFL), in collaboration with the Max Planck Institute of Nuclear Physics in Germany and University of Bern, have now developed a way to access them using a technique known as X-ray four-wave mixing.

“We learn how the electrons dance with each other – whether they hold hands, or if they dance alone,” says Gregor Knopp, senior scientist in the Center for Photon Sciences at Paul Scherrer Institute PSI, who led the study. “This gives us a new view on quantum phenomena and can change how we understand matter.”

Like NMR, but with X-rays

Conceptually, X-ray four-wave mixing is similar to nuclear magnetic resonance (NMR), which today is used daily in hospitals for MRI scans. Both techniques use multiple pulses to create and read out coherences in matter.

The process of four-wave mixing is also already well-established using infrared and visible light, where it allows scientists to investigate how molecules move, vibrate and interact with one another – with applications ranging from optical communications to imaging biological samples.

X-rays bring this same kind of powerful approach to a smaller scale and allow us to step into the world of the electrons. “Whereas other approaches tell us about how atoms or molecules as a whole interact with each other or with their surroundings, with X-rays we can zoom right in to the electrons,” says Ana Sofia Morillo Candas, first author of the paper.

This ability to zoom in on the interactions between electron has the potential to provide completely new insights not only into quantum information, but also into many other areas – for example biological molecules or materials for solar cells and batteries.

ow you would do it.” This approach is very different to previous attempts made at X-rays four-wave mixing, but to Knopp, it seemed like the obvious method to try. “We were amazed when we saw how large the signal was,” he adds.

It was the middle of the night, when Morillo Candas, at that time a postdoc at PSI, saw the signal in the control room of the Maloja experimental station at SwissFEL. She remembers: “It glowed like a light on the screen. To anyone else, it would look like nothing. But we jumped for joy.”

Read more on the PSI website

Image: Artistic impression of X-ray four-wave mixing – a technique that reveals how electrons interact with each other or with their surroundings. The ability to access this information is important for many fields: from understanding how quantum information is stored and lost to designing better materials for solar cells and batteries.