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PhAI: A deep-learning approach to solve the crystallographic phase problem

Anders S. Larsen, Toms Rekis, Anders Ø. Madsen

2024Science21 citationsDOI

Abstract

X-ray crystallography provides a distinctive view on the three-dimensional structure of crystals. To reconstruct the electron density map, the complex structure factors [Formula: see text] of a sufficiently large number of diffracted reflections must be known. In a conventional experiment, only the amplitudes [Formula: see text] are obtained, and the phases ϕ are lost. This is the crystallographic phase problem. In this work, we show that a neural network, trained on millions of artificial structure data, can solve the phase problem at a resolution of only 2 angstroms, using only 10 to 20% of the data needed for direct methods. The network works in common space groups and for modest unit-cell dimensions and suggests that neural networks could be used to solve the phase problem in the general case for weakly scattering crystals.

Topics & Concepts

Phase problemArtificial neural networkPhase (matter)AngstromDiffractionPhaserResolution (logic)AmplitudeComputer scienceSpace (punctuation)Crystal structureElectron densityCrystallographyPhysicsAlgorithmArtificial intelligenceElectronOpticsChemistryQuantum mechanicsOperating systemMachine Learning in Materials ScienceX-ray Diffraction in CrystallographyElectron and X-Ray Spectroscopy Techniques
PhAI: A deep-learning approach to solve the crystallographic phase problem | Litcius