Author
Listed:
- Elyse A. Schriber
(University of Connecticut
University of Connecticut)
- Daniel W. Paley
(Lawrence Berkeley National Laboratory)
- Robert Bolotovsky
(Lawrence Berkeley National Laboratory)
- Daniel J. Rosenberg
(Lawrence Berkeley National Laboratory
University of California)
- Raymond G. Sierra
(SLAC National Accelerator Laboratory)
- Andrew Aquila
(SLAC National Accelerator Laboratory)
- Derek Mendez
(Lawrence Berkeley National Laboratory)
- Frédéric Poitevin
(SLAC National Accelerator Laboratory)
- Johannes P. Blaschke
(Lawrence Berkeley National Laboratory)
- Asmit Bhowmick
(Lawrence Berkeley National Laboratory)
- Ryan P. Kelly
(University of Connecticut
University of Connecticut)
- Mark Hunter
(SLAC National Accelerator Laboratory)
- Brandon Hayes
(SLAC National Accelerator Laboratory)
- Derek C. Popple
(Lawrence Berkeley National Laboratory
University of California, Berkeley)
- Matthew Yeung
(Massachusetts Institute of Technology)
- Carina Pareja-Rivera
(Universidad Nacional Autónoma de México)
- Stella Lisova
(Arizona State University)
- Kensuke Tono
(Japan Synchrotron Radiation Research Institute)
- Michihiro Sugahara
(RIKEN SPring-8 Center)
- Shigeki Owada
(Japan Synchrotron Radiation Research Institute)
- Tevye Kuykendall
(Lawrence Berkeley National Laboratory)
- Kaiyuan Yao
(Columbia University)
- P. James Schuck
(Columbia University)
- Diego Solis-Ibarra
(Universidad Nacional Autónoma de México)
- Nicholas K. Sauter
(Lawrence Berkeley National Laboratory)
- Aaron S. Brewster
(Lawrence Berkeley National Laboratory)
- J. Nathan Hohman
(University of Connecticut
University of Connecticut)
Abstract
Inorganic–organic hybrid materials represent a large share of newly reported structures, owing to their simple synthetic routes and customizable properties1. This proliferation has led to a characterization bottleneck: many hybrid materials are obligate microcrystals with low symmetry and severe radiation sensitivity, interfering with the standard techniques of single-crystal X-ray diffraction2,3 and electron microdiffraction4–11. Here we demonstrate small-molecule serial femtosecond X-ray crystallography (smSFX) for the determination of material crystal structures from microcrystals. We subjected microcrystalline suspensions to X-ray free-electron laser radiation12,13 and obtained thousands of randomly oriented diffraction patterns. We determined unit cells by aggregating spot-finding results into high-resolution powder diffractograms. After indexing the sparse serial patterns by a graph theory approach14, the resulting datasets can be solved and refined using standard tools for single-crystal diffraction data15–17. We describe the ab initio structure solutions of mithrene (AgSePh)18–20, thiorene (AgSPh) and tethrene (AgTePh), of which the latter two were previously unknown structures. In thiorene, we identify a geometric change in the silver–silver bonding network that is linked to its divergent optoelectronic properties20. We demonstrate that smSFX can be applied as a general technique for structure determination of beam-sensitive microcrystalline materials at near-ambient temperature and pressure.
Suggested Citation
Elyse A. Schriber & Daniel W. Paley & Robert Bolotovsky & Daniel J. Rosenberg & Raymond G. Sierra & Andrew Aquila & Derek Mendez & Frédéric Poitevin & Johannes P. Blaschke & Asmit Bhowmick & Ryan P. K, 2022.
"Chemical crystallography by serial femtosecond X-ray diffraction,"
Nature, Nature, vol. 601(7893), pages 360-365, January.
Handle:
RePEc:nat:nature:v:601:y:2022:i:7893:d:10.1038_s41586-021-04218-3
DOI: 10.1038/s41586-021-04218-3
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