SwissFEL

Die jüngste Grossforschungsanlage des PSI erzeugt sehr kurze Pulse von Röntgenlicht mit Lasereigenschaften. Damit können Forschende extrem schnelle Vorgänge wie die Entstehung neuer Moleküle bei chemischen Reaktionen verfolgen, die detaillierte Struktur lebenswichtiger Proteine bestimmen oder den genauen Aufbau von Materialien klären. Die Erkenntnisse erweitern unser Verständnis der Natur und führen zu praktischen Anwendungen wie etwa neuen Medikamenten, effizienteren Prozessen in der chemischen Industrie oder neuen Materialien in der Elektronik.

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Observed live with x-ray laser: Electricity controls magnetism

Researchers from the Paul Scherrer Institute PSI and ETH Zurich have now changed the magnetic arrangement in a material much faster than is possible with today’s hard drives. The researchers used a new technique where an electric field triggers these changes, in contrast to the magnetic fields commonly used in consumer devices.

Bipartite magnetic parent phases in the iron oxypnictide superconductor

High-temperature superconductivity appears as a consequence of doping charge carriers into an undoped parent compound exhibiting antiferromagnetic order; therefore, ground-state properties of the parent compound are highly relevant to the superconducting state. On the basis of this logic, spin fluctuations have been considered as the origin of pairing of the superconducting electrons in the cuprates.

Elemental and magnetic contrast images in the initial state before the magnetic field is applied

Direct Observation of Magnetic Metastability in Individual Iron Nanoparticles

Studying the magnetization of individual iron (Fe) nanoparticles by magnetic spectromicroscopy reveals that superparamagnetic (SPM) and ferromagnetic blocked (FM) nanoparticles can coexist in the investigated size range of 8-20 nm.

An illustration of ARPES in an antiferromagnetic order state

Comprehensive study of the spin-charge interplay in antiferromagnetic La2-xSrxCuO4

The origin of the pseudogap and its relationship with superconductivity in the cuprates remains vague. In particular, the interplay between the pseudogap and magnetism is mysterious. Recent low-temperature angle-resolved photoemission spectroscopy (ARPES) experiments on the underdoped cuprate superconductors indicate the presence of a fully gapped Fermi surface (FS); even in the antiferromagnetic phase.

Pressure-Induced Quantum Critical and Multicritical Points in a Frustrated Spin Liquid

The quantum spin-liquid compound (C4H12N2)Cu2Cl6 is studied by muon spin relaxation under hydrostatic pressures up to 23.6 kbar. At low temperatures, pressure-induced incommensurate magnetic order is detected beyond a quantum critical point at Pc ∼ 4.3 kbar. An additional phase transition to a different ordered phase is observed at P1 ∼ 13.4 kbar. The data indicate that the high-pressure phase may be a commensurate one. The established (P-T) phase diagram reveals the corresponding pressure-induced multicritical point at P1, T1 = 2.0 K.

Strong Meissner screening change in superconducting radio frequency cavities due to mild baking

We investigate 'hot' regions with anomalous high field dissipation in bulk niobium superconducting radio frequency cavities for particle accelerators by using low energy muon spin rotation (LE-μSR) on corresponding cavity cutouts. We demonstrate that superconducting properties at the hot region are well described by the non-local Pippard/BCS model for niobium in the clean limit with a London penetration depth λL=23+/-2 nm . In contrast, a cutout sample from the 120C baked cavity shows a much larger λ>100nm and a depth dependent mean free path, likely due to gradient in vacancy concentration. We suggest that these vacancies can efficiently trap hydrogen and hence prevent the formation of hydrides responsible for rf losses in hot regions.

(a) RIXS map of La2Ti2O7; (b) extracted spectra of HR-XAS (red) and valence-to-core XES (blue); (c) FEFF calculated orbital contribution.

Determination of conduction and valence band electronic structure of La2Ti2O7 thin film

The electronic structure of a La2Ti2O7-layered perovskite thin film was determined by resonant inelastic X-ray scattering (RIXS) measurements and FEFF calculations. It was found that the empty Ti and La d-band states dominate the conduction band of the structure, whereas the top edge of the valence band is mainly composed of filled O-p states. Furthermore, there is a pronounced overlap between occupied La-p states and O-s states, which are located deeper in the valence band.

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X-ray tomography reaches 16 nm isotropic 3D resolution

Researchers at PSI reported a demonstration of X-ray tomography with an unmatched isotropic 3D resolution of 16 nm in Scientific Reports. The measurement was performed at the cSAXS beamline at the Swiss Light Source using a prototype instrument of the OMNY (tOMography Nano crYo) project. Whereas this prototype measures at room temperature and atmospheric pressure, the OMNY system, to be commissioned later this year, will provide a cryogenic sample environment in ultra-high vacuum without compromising imaging capabilities. The researchers believe that such a combination of advanced imaging with state-of-the-art instrumentation is a promising path to fill the resolution gap between electron microscopy and X-ray imaging, also in case of radiation-sensitive materials such as polymer structures and biological systems.

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PSI summer school 2014

The PSI summer school 2014 on Condensed Matter Research will be organized at the Institut Montana in Zug, Switzerland from August 9-15, 2014. The topic of the school will be 'Exploring time, energy and length scales in condensed matter' and the school will be followed by hands-on practical training at the PSI large user facilities SINQ, SμS and SLS. Online registration and detailed information is available from the school's webpage.

(top) 3D rendering of density distribution within carbon fibers, where high- and low-density regions are shown in black and in a semitransparent gray tone, respectively. On the left we show a fiber of 25 µm diameter, and on the right a 10 µm-diameter fiber made from a different precursor. Remarkable differences are observed between the two fibers.

Unique insight into carbon fibers on the nanoscale

Novel carbon materials are promising candidates for light and robust low-cost materials of the future. Understanding their mechanical properties benefits from highly resolved three-dimensional (3D) maps of their porosity and density fluctuations in uninterrupted representative volumes, but these are difficult to obtain with conventional imaging methods.

Frustration-induced nanometre-scale inhomogeneity in a triangular antiferromagnet

Phase inhomogeneity of otherwise chemically homogenous electronic systems is an essential ingredient leading to fascinating functional properties, such as high-Tc superconductivity in cuprates, colossal magnetoresistance in manganites and giant electrostriction in relaxors. In these materials distinct phases compete and can coexist owing to intertwined ordered parameters. Charge degrees of freedom play a fundamental role, although phase-separated ground states have been envisioned theoretically also for pure spin systems with geometrical frustration that serves as a source of phase competition.

Section of the tomogram, parallel to the rotation axis. Three distinct gray levels are visible for air (black), glass (gray), and Ta2O5 (white).

X-ray tomography reaches 16 nm isotropic 3D resolution

Tomographic microscopy has become an invaluable imaging method in both life and materials sciences. Oftentimes, high resolving power is required simultaneously with the ability to characterize large, statistically representative sample volumes. To this task, researchers at the Paul Scherrer Institut have established ptychographic computed tomography.

© 2014 J Hugo Dil/EPFL

Spintronics: deciphering a material for future electronics

Topological insulators are the key to future spintronics technologies. EPFL scientists have unraveled how these strange materials work, overcoming one of the biggest obstacles on the way to next-generation applications.Read the full story

Switching of magnetic domains reveals spatially inhomogeneous superconductivity

The interplay of magnetic and charge fluctuations can lead to quantum phases with exceptional electronic properties. A case in point is magnetically-driven superconductivity, where magnetic correlations fundamentally affect the underlying symmetry and generate new physical properties. The superconducting wavefunction in most known magnetic superconductors does not break translational symmetry.

Magnetoelastic Excitations in the Pyrochlore Spin Liquid Tb2Ti2O7

Tb2Ti2O7 is often referred to as a spin liquid as it does indeed remain in a magnetically disordered phase with spin dynamics down to 0.05 K, but this itself is a surprise since there are strong expectations of magnetic order and/or a structural distortion. However, throughout the spin liquid regime there are also strong signs of magnetoelastic coupling, leading to the suggestion that both spin and structural degrees of freedom are frustrated.

The ash formations in La Garita Caldera in Colorado, USA, are the result of eruptions of a supervolcano approximately 25 million years ago. (Photo: Courtesy of www.danielmcvey.com)

Supervolcano eruptions driven by melt buoyancy in large silicic magma chambers

Super-eruptions that dwarf all historical volcanic episodes in erupted volume and environmental impact are abundant in the geological record. Such eruptions of silica-rich magmas form large calderas. The mechanisms that trigger these supereruptions are elusive because the processes occurring in conventional volcanic systems cannot simply be scaled up to the much larger magma chambers beneath super volcanoes.