Meeting Reports: 2005 Annual Meeting of JSSRR (Japanese Society for Synchrotron Radiation Research)

The 18th Annual Meeting and General Assembly of the Japanese Society for Synchrotron Radiation Research (JSSRR) and the joint symposium of synchrotron radiation facility user's society groups were held at Sun-Messe Tosu Conference Hall in Tosu City, Japan, from January 7 to 9, 2005. The meeting was attended by 607 people and included 6 symposiums, 96 oral presentations, and 356 poster presentations covering all aspects of synchrotron radiation research and technology. The meeting also included 49 industrial exhibitions.

The six symposiums were on “Recent progress on soft X-ray optical elements,” “Now and the future on SR-XRF analysis for biological and environmental sciences,” “Recent development of THz Coherent Synchrotron Radiation,” “Super high-resolution protein structure analysis,” “Frontlines of Bio-Nano-microspectroscopy by UV-SX high brilliance SR,” and “The role of synchrotron radiation in the future of science: groundbreaking SR utilization for research on excited states”.     

XRMS 2008 Workshop at DESY

From January 23–24, 2008, the Deutsches Elektronen Synchrotron (DESY) provided a forum for more than 75 scientists from 12 countries to discuss recent developments in the investigation of magnetic solids with synchrotron radiation. The framework for this meeting was the International Workshop for X-ray Spectroscopy of Magnetic Solids (XRMS 2008). The XRMS workshop series was established in 2000 when the first meeting was held at BESSY (Berlin, Germany). It then continued annually or bi-annually, always in conjunction with a users meeting at one of the European synchrotron radiation facilities. In this year, the XRMS workshop preceded the HASYLAB Users Meeting at DESY on January 25.     

VUVX2010: 37th International Conference on Vacuum Ultraviolet and X-ray Physics

UVX2010, the 37^th International Conference on Vacuum Ultraviolet and X-ray Physics, took place from July 11-16, 2010, on the campus of the University of British Columbia (UBC). This meeting was the first of the merged Vacuum Ultraviolet Radiation Physics and X-ray and Inner Shell Processes conference series. The immediate preceding conferences were VUV15 (Berlin, 2007), and X-08 (Paris, 2008). VUVX2010 brought together scientists from countries all over the world working with synchrotron-, laser-, and plasma-based sources of electromagnetic radiation in the vacuum ultraviolet (VUV), soft X-ray, and hard X-ray regions, and developing novel applications of these sources in a variety of fields. Topics presented ranged from basic physics to materials science and technology, from molecular reactions to the characterization of catalysts under working conditions, from biology to medical diagnostics, from metrology to the development of advanced synchrotron and optical instrumentation. There were over 500 oral and poster presentations, with 480 attendees from 29 different countries. This conference took place on the fiftieth anniversary of the invention of the laser and in the year following the first operation of the Linear Coherent Light Source (LCLS), the world's first accelerator-based X-ray laser. It brought together the global community of VUV and X-ray scientists who use synchrotron-, laser-, and plasma-based sources of vacuum ultraviolet, soft X-ray, and hard X-ray light to explore new phenomena and to develop a better understanding of the physics of the interaction of light and matter.     

Seeded X‐ray free electron laser workshop at the NSLS

SESAME (Synchrotron Light for Experimental Science and Applications in the Middle East, www.sesame.org.jo) is being built in Jordan under the umbrella of UNESCO as an international synchrotron radiation source. Scientists from the members (Jordan, Israel, Egypt, Turkey, Bahrain, Pakistan and the Palestinian Authority) and observer countries (Iran, France, Germany, Greece, Kuwait, Russia, USA, UK) have been meeting annually since 2002 with the aim of presenting their work in the field, discussing the latest developments in the project and spreading the word about SESAME and strengthening contacts in the SESAME users' community. The first Users Meeting was held in Amman, Jordan, in 2002 with the generous help of the Japanese Society for Physical Sciences.     

Energy - dispersive X - ray diffraction of the ammonium - halides under pressure

Abstract

The structure of the ammonium halides NH₄X (X = Cl, Br, I) has been studied under pressure up to 40 GPa by energy dispersive X-ray diffraction using synchrotron radiation. Equations of state and a discussion on the possible structure of phase V will be presented.     

Dielectric loss measurements on silver halide sheet crystals

Abstract

A series of studies on the partial X-ray diffuse scattering intensities from ternary alloys analysed through synchrotron radiation experiments has been reviewed. An intensity expression for the short-range order diffuse scattering has been developed, which is necessary in understanding the separation method of an observed X-ray diffuse intensity into partial intensities contributed from different origins. Techniques have been described in detail mainly concerning the Cu₂NiZn alloy, which have shown the benefits of the anomalous scattering effect of synchrotron radiation. The negative partial intensity maximum for the Cu-Ni pair found in the Cu-Ni-Zn alloy has been discussed from the viewpoints of crystallography and thermodynamics. In addition, at the end of the paper, local atomic arrangements causing the diffuse scatterings have been discussed.     

Ultrafast X-ray science at the advanced light source

On May 19, 2004, 250 guests from all over the world joined the DESY research center to celebrate 40 years of research with synchrotron radiation at DESY in Hamburg. “The first measurements with the light beam from the DESY ring accelerator started in 1964. DESY was one of the seed laboratories in which the worldwide success story of research with synchrotron radiation began,” Albrecht Wagner, chairman of the DESY Board of Directors, explained in his welcoming address. “Today, more than 1,900 scientists from 31 countries come to DESY every year to carry out experiments with synchrotron radiation.”

Forty years ago, synchrotron radiation at DESY started from scratch. At the beginning of the 1960s, the radiation generated by the electrons in the bending magnets of their new 6 GeV electron synchrotron was regarded by DESY particle physicists as an unwanted, disruptive effect.     

Meeting Reports: International Workshop on the Protein Circular Dichroism Data Bank

The International Workshop on the Protein Circular Dichroism Data Bank (PCDDB) was held on April 11–13, 2005, at Birkbeck College, University of London, UK, under the sponsorship of the UK Biotechnology and Biological Sciences Research Council. The meeting was chaired by Bonnie Ann Wallace, Professor in the Department of Crystallography at Birkbeck College. The workshop organizing committee consisted of Dr. Robert W. Janes, Queen Mary, University of London, and Dr. Lee Whitmore, also of Birkbeck College.

Participants included experts in both conventional circular dichroism (CD) spectroscopy and representatives from synchrotron radiation circular dichroism (SRCD) beamlines: Prof. J. Sutherland of the NSLS SRCD beamlines U9b and U11 and East Carolina University (USA);     

Protein crystallography with the PILATUS 1M detector at the Swiss Light Source

The last few years have seen an increase in the demand of automation at synchrotron radiation facilities. The main driving forces behind this quest are the Structural Genomics Centers and related projects [1], with their need for large throughput of samples and an increasing number of relatively unskilled users with ever increasing demands.

In order to meet the needs of this diverse community, the structure determination process must be streamlined. A production pipeline for high volume determination of structures requires optimization and automation of current processes in use at synchrotron facilities. The ultimate goal is to arrive at a system that, with little more input than a sample, will provide the researcher with the final molecular structure.     

Synthesis of Novel Superhard Phases in the B-C-N System

Novel ternary diamond-like phases of the B-C-N system were synthesized at pressures up to 30 GPa and temperatures up to 3500 K by static and dynamic compression of graphite-like BN-C solid solutions. Structure and properties of these new phases were studied using X-ray diffraction with synchrotron radiation, analytical transmission electron microscopy (ATEM), electron energy loss spectroscopy (EELS), microhardness measurements and nanoindentation.     

A compact warm ring for industrial applications

The ultrafast, high brightness X-ray free electron laser (XFEL) sources of the future have the potential to revolutionize the study of time-dependent phenomena in the natural sciences. These linear accelerator (linac) sources will generate femtosecond (fs) X-ray pulses with peak flux comparable to conventional lasers, and far exceeding all other X-ray sources. The Stanford Linear Accelerator Center (SLAC) has pioneered the development of linac science and technology for decades, and since 2000 SLAC and the Stanford Synchrotron Radiation Laboratory (SSRL) have focused on the development of linac based ultrafast electron and X-ray sources.     

Compression behavior of NiO in a diamond cell

Abstract

The compressibility of synthetic polycrystalline NiO was studied in a diamond anvil cell at room temperature utilizing two different X-ray sources. A standard film with a conventional X-ray source and the energy dispersive X-ray diffraction (EDXRD) method with synchrotron radiation were used for data acquisition. In the film method, the sample was compressed in a 4:1 methanol to ethanol solution up to 7 GPa with ruby fluorescence as a pressure calibrant. In the energy dispersive method, NiO powder was mixed with gold and compressed in two different conditions: gasketed and ungasketed up to 30 GPa. In the gasketed run, water was used as the pressure transmitting medium while gold was used as pressure calibrant in both runs.

Hydrostatic compression of NiO in both diffraction methods yields a bulk modulus (K _o) of 187 ± 7 GPa assuming K′ = 4. The compression of gasketed NiO of the synchrotron experiment, however, showed an obvious break at pressure exceeding 4 GPa due to the loss of hydrostaticity. NiO in a nonhydrostatic condition behaves with less compressibility than the hydrostatic results with a nominal K _o of 238 ± 10 GPa. The lower compressibility of NiO in synchrotron runs is attributed to the uniaxial loading effect which was more easily detected by the EDXRD geometry. The discrepancy in the bulk modulus can be attributed to the contrast in the shear strength between the sample and pressure medium and the Poisson effect of the sample under uniaxial loading.     

Application of Advanced Synchrotron Radiation–Based and Conventional Molecular Techniques in Recent Research on Molecular Structure,Metabolic Characteristics,and Nutrition in Coproducts from Biofuel Processing

Abstract

Advanced synchrotron radiation infrared microspectroscopy, as a nondestructive and rapid analytical technique, is able to simultaneously reveal the structural, chemical, and environmental features of biomaterials at cellular and molecular levels within intact tissue. However, to date, this advanced synchrotron-based technique is still seldom used by feed and nutrition scientists. This article aims to provide detailed information regarding how to apply advanced synchrotron radiation–based and conventional molecular techniques to research in coproducts from biofuel processing on the molecular structure, metabolic characteristics, and nutrition. The information described in this article provides better insight on coproduct research progress and updates with advanced synchrotron radiation-based and globar-based (conventional) molecular spectroscopy.     

Synthesis experiments on B-Sb,Ge-Sb,and Xe-Pd systems using a laser heated diamond anvil cell

Abstract

In an effort to synthesize B-Sb, Ge-Sb and Xe-Pd compounds under high pressure, the respective system was laser-heated in a diamond anvil cell at temperatures above 2500 K and up to a maximum pressure of 51 GPa. The product was characterized by X-ray diffraction using rotating anode and synchrotron radiation X-ray sources. No reaction was observed in any of these systems up to pressures of 32, 20 and 51 GPa, respectively. In the case of Ge-Sb, new peaks were observed in the pressurequenched samples, but they were identified with the known metastable phases of Ge. In this regard our results are contrary to the earlier work on Ge-Sb.     

National school on Neutron and X‐ray scattering alumni presentations

The 4th joint Stanford–Berkeley summer school on synchrotron radiation and its applications in physical science was held June 12–17, 2005, at the Stanford Linear Accelerator Center (SLAC). The Stanford–Berkeley summer school is jointly organized by Stanford University, University of California Berkeley, Lawrence Berkeley National Laboratory (LBNL), and the Stanford Synchrotron Radiation Laboratory (SSRL). Since 2001, Anders Nilsson (Stanford/SSRL) and Dave Attwood (UC Berkeley) have been the organizers of this annual weeklong summer school, which alternates each year between Stanford and Berkeley. The summer school provides lecture programs on synchrotron radiation and its broad range of scientific applications in the physical science as well as visits to the Stanford Synchrotron Radiation Laboratory and the Advanced Light Source (ALS), where the students also have the opportunity to experience a beam line.     

Radiometry with synchrotron radiation at the PTB laboratory at Bessy ii

A workshop on Engineering Applications of Neutrons and Synchrotron Radiation took place on September 13–14, 2004, at the ESRF in Grenoble, France. The workshop brought together around 100 leading scientists and engineers who discussed the application of synchrotron X-ray and neutron central facilities for engineering problems. The event was organized by the FaME38 materials engineering facility at ILL-ESRF. FaME38 is jointly funded by the UK research council EPSRC and ILL-ESRF and provides support to enable materials engineers to make the best use of the advanced synchrotron X-ray and neutron scientific facilities at ILL-ESRF.

The programme included formal presentations, a poster session, informal workgroup sessions and an opportunity to meet staff at the ILL-ESRF materials science beamlines. The formal presentations were structured into three sessions entitled Progress, Complementarity, and Applications chaired by Giovanni Bruno (ILL), Thomas Buslaps (ESRF), and Darren Hughes (FaME38).     

Technical Reports: Time-Resolved Activities at the Advanced Photon Source Requiring the Pulsed Structure of the X-ray Beam

Scientific research in the time domain using the pulsed structure of the X-ray beams from a third-generation synchrotron source, such as the Advanced Photon Source (APS), has become a major interest among synchrotron users. The traditional material science, chemistry, and biology communities are getting an early glimpse of the potential impact of fast time-resolved X-ray studies. The scientific disciplines that have benefited from these studies include atomic and molecular physics, biology, chemical science, condensed matter physics, engineering science, environmental science, material science, and nuclear science. Technically, the turn-key-type femtosecond (fs) optical lasers with high peak power, used as pumps in many X-ray pump-probe experiments, have only recently become available.     

High-pressure Mössbauer spectroscopy with nuclear forward scattering of synchrotron radiation

Abstract

Using a diamond anvil cell, high-pressure ⁵⁷Fe Mössbauer spectroscopy has been performed with the nuclear forward scattering of synchrotron radiation. A pressure-induced magnetic hyperfine interaction at ⁵⁷Fe in SrFeO_{2, 97} has been detected at 44 GPa and 300 K for a first time by a quantum-beat modulation of the decay rate after collective nuclear excitation by the synchrotron pulse. The basic concept and method used to detect nuclear forward scattering with synchrotron radiation are discussed.     

A large volume pressure cell for high temperatures

Abstract

Studies of matter under very high pressure at synchrotron radiation sources are mostly done using pressure cells with single-crystal diamond anvils. In some cases the available volume (≤ 10^?3mm³)in such cells causes problems especially at high temperature and for crystal synthesis. To ensure sufficient homogeneity of pressure and temperature, the use of cells with large sample volumes (≥ 1 mm³) is necessary.

Existing devices for such measurements are compared with a novel setup which consists of a toroidal anvil arrangement and a lightweight (50 kg) press with 250 tonnes (2.5 MN) capacity. Preliminary tests of this instrument with synchrotron radiation are reported.

Presented at the IUCr Workshop on ‘Synchrotron Radiation Instrumentation for HighPressure Crystallography’. Daresbury Laboratory 20-21 July 1991     

Pressure effect on the electromotive force of the type R thermocouple

ABSTRACT

The pressure effect on the electromotive force (EMF) of a Pt13Rh–Pt (type R) thermocouple was examined to determine the temperature measurement accuracy of solid pressure medium apparatuses in high-pressure experiments. Single-wire EMFs were measured up to pressure of 13?GPa and temperature of 1173?K with a Kawai-type multi-anvil apparatus for Pt13Rh and Pt based on the single-wire method. The pressure conditions along the wires were evaluated by in situ X-ray diffraction using synchrotron X-ray radiation. The pressure effect of the Seebeck coefficients of Pt13Rh and Pt were determined by the analysis of the single-wire EMFs and pressure–temperature profiles along the wires and was virtually consistent with those determined in previous studies at lower pressures and temperatures. For type R thermocouple, the difference between the nominal and real temperatures was determined to be as large as –75?K at 13?GPa and 873?K.