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Full Picture of Lattice Deformation in a Ge 1 - x Sn x Micro-Disk by 5D X-ray Diffraction Microscopy.

Cedric Corley-WiciakMarvin Hartwig ZoellnerAgnieszka A Corley-WiciakFabrizio RovarisEdoardo ZatterinIgnatii ZaitsevGianfranco SfunciaGiuseppe NicotraDavide SpiritoNils von den DrieschCostanza Lucia ManganelliAnna MarzegalliTobias U SchulliDan BucaFrancesco MontalentiGiovanni CapelliniCarsten Richter
Published in: Small methods (2024)
Lattice strain in crystals can be exploited to effectively tune their physical properties. In microscopic structures, experimental access to the full strain tensor with spatial resolution at the (sub-)micrometer scale is at the same time very interesting and challenging. In this work, how scanning X-ray diffraction microscopy, an emerging model-free method based on synchrotron radiation, can shed light on the complex, anisotropic deformation landscape within three dimensional (3D) microstructures is shown. This technique allows the reconstruction of all lattice parameters within any type of crystal with submicron spatial resolution and requires no sample preparation. Consequently, the local state of deformation can be fully quantified. Exploiting this capability, all components of the strain tensor in a suspended, strained Ge 1 - x Sn x /Ge microdisk are mapped. Subtle elastic deformations are unambiguously correlated with structural defects, 3D microstructure geometry, and chemical variations, as verified by comparison with complementary electron microscopy and finite element simulations. The methodology described here is applicable to a wide range of fields, from bioengineering to metallurgy and semiconductor research.
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