forthcoming articles

We present an algorithm for unit-cell determination from a set of randomly oriented electron diffraction patterns and demonstrate its performance for two known structures (copper perchlorophthalocyanine and lysozyme) and one as-yet uncharacterized structure.

This article describes the re-formulation of Bloch waves using physical optics theory for more efficient simulation of large electron diffraction data sets.

The quasiperiodic nature of moiré patterns in homophase twisted bilayers is analyzed to understand the underlying basic periodicities and symmetries of homophase twisted bilayers built on any 2D structure.

Pressure-induced structural strain in (R)-3-quinuclidinol crystals is analysed over different pressure ranges[under pressure] and com­pared with structural strain on cooling.

The methodology proposed combines the DFT calculations and photoelasticity caused by uniaxial compression of the crystal lattice, with particular emphasis on its anisotropy. It can be considered as part of optical engineering aimed at preliminary assessment of the photoelastic properties of crystal materials, thus assisting in their selection for synthesis and relevant applications.

Several Li⁺/Fe³⁺-doped Pbca orthoenstatite and Pbcn protoenstatite crystals were characterized revealing that varying levels of doping preferentially affect the py­rox­ene topologies.

Electron density distribution in bis(guanidinium) disodium hypodiphosphate heptahydrate, (CH₆N₃)₂Na₂(P₂O₆)·7H₂O, is reported.

A rare complex incommensurate magnetic structure, an amplitude-modulated structure which itself is modulated, was determined in the Ho-based i-MAX phase (Mo_2/3Ho_1/3)₂GaC. It represents a particularly distinctive case of a 2-k magnetic structure with no symmetry relation between the propagation vectors.

The patterns of microbial crystallization are controlled by the chemical composition of biofilms associated with environmental exposure and the activity of microorganisms. The nutrition of microorganisms changes the oxalic acid and extracellular polymer substance content in the products of microbial metabolism, which significantly affects the medium pH promoting either the oxalate or carbonate crystallization.

Three bis­(acyl­thio­urea) positional isomers containing two ferrocenyl groups were synthesized and characterized by X-ray diffraction. Their various noncovalent inter­actions and crystal assemblies have been investigated.

We present the synthesis and characterization of four new crystalline forms of a N-derivative of L-phenyl­alanine with 2-naphthaldehyde, where the com­pound adopts different unfolded and folded conformations depending on its charge state and the supra­molecular environment. To characterize and classify such conformational differences, we propose the use of a dimensionless Shape Factor qu­antity defined as the Structural Aspect Ratio (SA_R), which proves to be a simple but useful tool for this purpose, and its application could be extended to other conformational studies.

The structure solution and refinement from three-dimensional electron diffraction (3D ED) data of elemental sulfur, known to sublimate in the vacuum of transmission electron microscopes, is enabled through the use of an environmental cell with a micro-electromechanical system. This work represents the first step in characterizing sulfur's transformation into lithium polysulfides using in-situ 3D ED.

Fast readout event-based electron counting (EBEC) is a promising detection strategy to determine accurate ab initio structures of beam-sensitive small mol­ecules by MicroED. A fast EBEC approach enhances the dynamic range of MicroED data by limiting the likelihood of coincidence loss (CL) – the undercounting of electrons due to their spatially and temporally unresolved arrival on a direct electron detector. As implemented by new counting detectors, fast EBEC allows structure-worthy data sets to be captured from individual small-mol­ecule crystals in under a minute.

Oxidations from P^N to P¹⁺/P²⁺ clusters correspond to coordinations with the hydroxyl group of serine residues and the amide group of cysteine, without electron and proton transfers.

A 3,6-disubstituted 1,2,4,5-tetra­zine was synthesized and characterized by single-crystal X-ray diffraction, revealing a complex hydrogen-bonded network with inter­actions between tetra­zine N atoms and hydroxyl groups, thereby complementing the only scarcely explored features of tetra­zines in the solid state.

In the title compound, the dihedral angle between the chromen-2-one ring system and the bromo­benzene ring is 10.29 (6)°. In the crystal, the mol­ecules are connected through C—H⋯O hydrogen bonds and π–π stacking inter­actions.

Analysis of a high-resolution structure of carboxyspermidine decarboxylase, a member of the PLP-dependent, β/α -barrel-fold, decarboxylase family.

TDE0362 is an essential factor for the pathogenicity of T. denticola in oral bacterial disease. This work provides insights into the regulatory mechanism of TDE0362 and identifies putative substrate-binding interfaces which could be used to guide further research towards inhibition of this enzyme.

Hydro­static properties of highly inert perhalogenated fluids were investigated using ruby fluorescence measurements.

A PVT equation of state has been determined for sodium fluoride with a range of validity between 12 and 950 K in temperature and 0 and 25 GPa in pressure based on a fourth-order Birch–Murnaghan expression for isothermal compression and a Mie–Grüneisen–Debye model for thermal pressure.

The forensic field requires versatile equipment for non-destructive characterization, analysis and inspection of 2D and 3D objects. The robotic scanner introduced here allows transmission X-ray imaging and mapping of individual photons with high-sensitivity and -resolution detectors. The broad capabilities of X-ray diffraction (XRD) imaging are now being complemented by X-ray fluorescence point analysis and mapping, multispectral macro imaging, and multispectral XRD analysis.

A novel method for precise crystal alignment in a diamond anvil cell has been developed. This method leverages Snell's law providing immediate visual feedback for alignment and offering exceptional accuracy (<0.02 mm) while being simple and fast, facilitating high-pressure diffraction experiments.

The article presents the synthesis of new tetra­fluoro­borate and bromide salts of iso­thio­uronium compounds, followed by structural and spectroscopic studies, demonstrating that using ssNMR-derived intermolecular distances as restriction can increase the likelihood of finding the crystal structure model when solving crystal structure from powder diffraction data.

In Laue geometry, based on two-dimensional recurrence relations of X-ray diffraction in a crystal with a complex elastic strain distribution, the method for calculating reciprocal-space maps has been developed.

A computational and experimental investigation of integral X-ray diffuse scattering near Bragg reflections with a wide-open detector is presented for the case of small circular irradiation-induced dislocation loops in metals. The large wavevector asymptotic power-law falloff for such loops is determined computationally and incorporated into numerical and analytical integral X-ray diffuse scattering cross-section calculations. These calculations are shown to enable the experimental determination of the size distribution and concentrations of irradiation-induced dislocation loops in single-crystalline tungsten.

iPowder, software for high-throughput X-ray diffraction analysis, automates tasks like indexing and unit-cell refinement, streamlining the data processing workflow and enhancing efficiency in material science research.

We develop and evaluate a deep learning-based algorithm that demonstrates the potential to reconstruct simultaneously high resolution, high frame-rate x-ray image sequences with high fidelity through spatio-temporal fusion. Our experimental evaluation shows that our method can significantly improve the accuracy of the reconstruction, achieving an average peak signal-to-noise ratio (PSNR) of more than 35 dB on two representative x-ray image sequences with input data streams of 4 times lower spatial resolution and 20 times lower frame rate, respectively.

The SPXF has revolutionized structural biology research through its advanced light sources, enabling crucial breakthroughs in disease research. The facility's integration of automation and cutting-edge techniques provides world-class resources for global researchers.

An open-source software system for managing user office operations at a large-scale research facility is presented.

We applied advanced image-processing techniques, including fast Fourier Transform analysis, image registration and optical flow, to mitigate artifacts caused by system instabilities and accurately track battery electrode deformations during operation. This approach improves the reliability of high-resolution operando imaging, providing deeper insights into battery degradation and enhancing our understanding of chemomechanical interactions in battery performance.

Structure-based drug design has been a critical component of drug discovery for over 30 years, contributing to numerous approved drugs. The paper discusses the approach taken by AstraZeneca (Sweden) to synchrotron data collection for supporting a large portfolio of drug discovery projects and provides examples to demonstrate the continued importance of experimental structures.

This controlled radiation damage study at different temperatures allows the approaches to measuring radiation-damage-free/limited spectra from redox-sensitive metalloenzymes and metal complexes in the soft X-ray regime at synchrotrons to be refined.

A new online beam intensity synchronous monitoring system has been designed which can precisely and synchronously monitor X-ray beam intensity variations. This can be used to remove noise due to electron injection from STXM images, thereby markedly improving the quality of STXM imaging.

A method for compensating for the source drift of a free-electron laser beamline by adjusting the C_ff value of a grating monochromator is introduced.

This study employs quantum crystallography to elucidate the selectivity of NSAIDs, including ibuprofen, flurbiprofen, meloxicam and celecoxib, for cyclo­oxygenase-1 and cyclooxygenase-2 enzymes by analyzing binding energy and electrostatic interactions. The findings reveal key structural determinants of NSAID selectivity, providing valuable insights for the rational design of safer and more effective anti-inflammatory drugs.

We used the Bragg coherence diffraction imaging method at the Coherent Scattering and Imaging endstation of the Shanghai Soft X-ray Free Electron Laser Facility to characterize colloidal crystals. This method successfully reproduced the static shape of crystals and we observed the defect structure of colloidal samples.

Here we identify and characterize the warping of molecular crystal lattices induced by electron beam exposure during microcrystal electron diffraction (MicroED/3DED) data collection. We find changes to consensus crystal lattice orientation that are often dramatic, and appear ubiquitous in small organic molecule crystals. This evidence highlights the relevance of crystal bending or warping as a consequence of radiation-induced damage on molecular specimens, and points to it as a fundamental source of error in MicroED/3DED data collection and structure determination.

Differences in the electronic structures of Cu(I) and Cu(II) coordination compounds with the same ligand as the model structures of `blue copper proteins' were studied.