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Main Authors: Lapkin, Dmitry, Yan, Cong, Gürsoy, Emre, Sternlicht, Hadas, Plunkett, Alexander, Bor, Büsra, Kim, Young Yong, Assalauova, Dameli, Westermeier, Fabian, Sprung, Michael, Krekeler, Tobias, Rout, Surya Snata, Ritter, Martin, Kulkarni, Satishkumar, Keller, Thomas F., Schneider, Gerold A., Vonbun-Feldbauer, Gregor B., Meissner, Robert H., Stierle, Andreas, Vartanyants, Ivan A., Giuntini, Diletta
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.20826
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author Lapkin, Dmitry
Yan, Cong
Gürsoy, Emre
Sternlicht, Hadas
Plunkett, Alexander
Bor, Büsra
Kim, Young Yong
Assalauova, Dameli
Westermeier, Fabian
Sprung, Michael
Krekeler, Tobias
Rout, Surya Snata
Ritter, Martin
Kulkarni, Satishkumar
Keller, Thomas F.
Schneider, Gerold A.
Vonbun-Feldbauer, Gregor B.
Meissner, Robert H.
Stierle, Andreas
Vartanyants, Ivan A.
Giuntini, Diletta
author_facet Lapkin, Dmitry
Yan, Cong
Gürsoy, Emre
Sternlicht, Hadas
Plunkett, Alexander
Bor, Büsra
Kim, Young Yong
Assalauova, Dameli
Westermeier, Fabian
Sprung, Michael
Krekeler, Tobias
Rout, Surya Snata
Ritter, Martin
Kulkarni, Satishkumar
Keller, Thomas F.
Schneider, Gerold A.
Vonbun-Feldbauer, Gregor B.
Meissner, Robert H.
Stierle, Andreas
Vartanyants, Ivan A.
Giuntini, Diletta
contents Supercrystalline nanocomposites (SCNCs) are nanostructured hybrid materials with unique emergent functional properties. Given their periodically arranged building blocks, they also offer interesting parallelisms with crystalline materials. They can be processed in multiple forms and at different scales, and crosslinking their organic ligands via heat treatment leads to a remarkable boost of their mechanical properties. This study shows, via X-ray and in-situ scanning transmission (STEM) electron microscopy analyses, how each of these processing steps plays a distinct role in the generation, migration, interaction and healing of supercrystalline defects. Pressing of SCNCs into bulk pellets leads to a distortion of the otherwise fcc superlattice, while emulsion-templated self-assembly yields supraparticles (SPs) with stacking faults and size-dependent symmetries. Interestingly, heat treatment at the same temperatures as those applied for the organic crosslinking has significant effects on planar defects. Stacking faults migrate and get healed, as also confirmed via molecular dynamics simulations, and inter-supercrystalline 'grain' boundaries undergo structural changes. These rearrangements of defects at the supercrystalline scale (tens of nm) in nanocomposites with such remarkable mechanical properties (compressive strength of 100-500 MPa) provide new insights into the formation and evolution of ordered assemblies of functionalized nanoparticles.
format Preprint
id arxiv_https___arxiv_org_abs_2507_20826
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Defect migration in supercrystalline nanocomposites
Lapkin, Dmitry
Yan, Cong
Gürsoy, Emre
Sternlicht, Hadas
Plunkett, Alexander
Bor, Büsra
Kim, Young Yong
Assalauova, Dameli
Westermeier, Fabian
Sprung, Michael
Krekeler, Tobias
Rout, Surya Snata
Ritter, Martin
Kulkarni, Satishkumar
Keller, Thomas F.
Schneider, Gerold A.
Vonbun-Feldbauer, Gregor B.
Meissner, Robert H.
Stierle, Andreas
Vartanyants, Ivan A.
Giuntini, Diletta
Materials Science
Supercrystalline nanocomposites (SCNCs) are nanostructured hybrid materials with unique emergent functional properties. Given their periodically arranged building blocks, they also offer interesting parallelisms with crystalline materials. They can be processed in multiple forms and at different scales, and crosslinking their organic ligands via heat treatment leads to a remarkable boost of their mechanical properties. This study shows, via X-ray and in-situ scanning transmission (STEM) electron microscopy analyses, how each of these processing steps plays a distinct role in the generation, migration, interaction and healing of supercrystalline defects. Pressing of SCNCs into bulk pellets leads to a distortion of the otherwise fcc superlattice, while emulsion-templated self-assembly yields supraparticles (SPs) with stacking faults and size-dependent symmetries. Interestingly, heat treatment at the same temperatures as those applied for the organic crosslinking has significant effects on planar defects. Stacking faults migrate and get healed, as also confirmed via molecular dynamics simulations, and inter-supercrystalline 'grain' boundaries undergo structural changes. These rearrangements of defects at the supercrystalline scale (tens of nm) in nanocomposites with such remarkable mechanical properties (compressive strength of 100-500 MPa) provide new insights into the formation and evolution of ordered assemblies of functionalized nanoparticles.
title Defect migration in supercrystalline nanocomposites
topic Materials Science
url https://arxiv.org/abs/2507.20826