12 research outputs found
Ferroelectric domains in barium titanate by Bragg coherent X-ray diffraction imaging
My PhD work focused on studying the domain structures and the strain fields inside barium titanate (BaTiO3) nanocrystals. The results on the domain structure study have already been published. The results on the stripe-like strain fields inside nanocrystals are finalized and there is a plan for publication.
The first question my PhD work wants to address is what the domain structures inside BTO nanoparticles exist and how they evolve with temperature and when crossing the phase transition. Bragg coherent X-ray diffraction imaging (BCDI) experiments on nominal 200 nm size BTO nanoparticles were carried out at the Diamond I13-1 beamline and the Advanced Photon Source 34-ID-C beamline. The 90° domain walls were tracked in detail when crossing the tetragonal-cubic phase transition. This is presented in Chapter 3.
Upon studying the domain structure inside BTO nanocrystals, some unexpected stripe-like strain fields were found. Crystals with clear facets were chosen to restore resolve the crystallographic direction, after which the strain field direction and periodicity were studied in detail. This is shown in Chapter 4.
To understand the temperature dependence of the strain stripes, in-situ BCDI experiments were done at ESRF ID-01 beamline. Faceted BTO nanocrystals were chosen for temperature study. The strain stripes were found to be stable and preserved at both tetragonal and cubic phase with at elevated temperatures. This is illustrated in Chapter 5.
The Finite element analysis (FEA) approach was utilized to understand the origins of the strain stripes. Different piezoelectric blocks were defined to simulate the domain structures inside a BTO crystal. 180° domain walls were found to give more strain stripes features than 90° domain walls in the simulation. This is covered in Chapter 6.
The same patch of BTO nanocrystals were also studied using an X-ray Free-electron Laser as a function of time delay after laser excitation. Rather than seeing any significant thermal expansion effects, the diffraction peaks were found to move perpendicular to the momentum transfer direction. This suggests a laser driven rotation of the crystal lattice, which is delayed by the aggregated state of the crystals. Internal deformations associated with crystal contacts were also observed. These are shown in Chapter 7
Anisotropy of Antiferromagnetic Domains in a Spin-orbit Mott Insulator
The temperature-dependent behavior of magnetic domains plays an essential
role in the magnetic properties of materials, leading to widespread
applications. However, experimental methods to access the three-dimensional
(3D) magnetic domain structures are very limited, especially for
antiferromagnets. Over the past decades, the spin-orbit Mott insulator iridate
has attracted particular attention because of its interesting
magnetic structure and analogy to superconducting cuprates. Here, we apply
resonant x-ray magnetic Bragg coherent diffraction imaging to track the
real-space 3D evolution of antiferromagnetic ordering inside a
single crystal as a function of temperature, finding that the antiferromagnetic
domain shows anisotropic changes. The anisotropy of the domain shape reveals
the underlying anisotropy of the antiferromagnetic coupling strength within
. These results demonstrate the high potential significance of 3D
domain imaging in magnetism research
Imaging Light-Induced Migration of Dislocations in Halide Perovskites with 3D Nanoscale Strain Mapping
In recent years, halide perovskite materials have been used to make high
performance solar cell and light-emitting devices. However, material defects
still limit device performance and stability. Here, we use synchrotron-based
Bragg Coherent Diffraction Imaging to visualise nanoscale strain fields, such
as those local to defects, in halide perovskite microcrystals. We find
significant strain heterogeneity within MAPbBr (MA =
CHNH) crystals in spite of their high optoelectronic quality,
and identify both 100 and 110 edge
dislocations through analysis of their local strain fields. By imaging these
defects and strain fields in situ under continuous illumination, we uncover
dramatic light-induced dislocation migration across hundreds of nanometres.
Further, by selectively studying crystals that are damaged by the X-ray beam,
we correlate large dislocation densities and increased nanoscale strains with
material degradation and substantially altered optoelectronic properties
assessed using photoluminescence microscopy measurements. Our results
demonstrate the dynamic nature of extended defects and strain in halide
perovskites and their direct impact on device performance and operational
stability.Comment: Main text and Supplementary Information. Main text: 15 pages, 4
figures. Supplementary Information: 16 pages, 27 figures, 1 tabl
Three-dimensional Coherent X-ray Diffraction Imaging via Deep Convolutional Neural Networks
As a critical component of coherent X-ray diffraction imaging (CDI), phase
retrieval has been extensively applied in X-ray structural science to recover
the 3D morphological information inside measured particles. Despite meeting all
the oversampling requirements of Sayre and Shannon, current phase retrieval
approaches still have trouble achieving a unique inversion of experimental data
in the presence of noise. Here, we propose to overcome this limitation by
incorporating a 3D Machine Learning (ML) model combining (optional) supervised
learning with transfer learning. The trained ML model can rapidly provide an
immediate result with high accuracy which could benefit real-time experiments,
and the predicted result can be further refined with transfer learning. More
significantly, the proposed ML model can be used without any prior training to
learn the missing phases of an image based on minimization of an appropriate
'loss function' alone. We demonstrate significantly improved performance with
experimental Bragg CDI data over traditional iterative phase retrieval
algorithms
Unusual Breathing Behavior of Optically Excited Barium Titanate Nanocrystals
Coherent X-ray diffraction patterns were recorded by using an X-ray free-electron laser to illuminate barium titanate nanocrystals as a function of time delay after laser excitation. Rather than seeing any significant thermal expansion effects, the diffraction peaks were found to move perpendicular to the momentum transfer direction. This suggests a laser driven rotation of the crystal lattice, which is delayed by the aggregated state of the crystals. Internal deformations associated with crystal contacts were also observed
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Imaging Light-Induced Migration of Dislocations in Halide Perovskites with 3d Nanoscale Strain Mapping.
Funder: King Abdullah University of Science and Technology; doi: http://dx.doi.org/10.13039/501100004052Funder: U.S. Department of Energy; doi: http://dx.doi.org/10.13039/100000015Funder: Office of Science; doi: http://dx.doi.org/10.13039/100006132Funder: HORIZON EUROPE European Research Council; doi: http://dx.doi.org/10.13039/100019180Funder: China Scholarship Council; doi: http://dx.doi.org/10.13039/501100004543Funder: British Spanish SocietyFunder: Sir Richard Stapley Educational Trust; doi: http://dx.doi.org/10.13039/501100016406Funder: Rank Prize FundFunder: Winton Sustainability FundFunder: George and Lilian Schiff FoundationFunder: Ernest Oppenheimer Early Career FellowshipFunder: Schmidt Science FellowshipIn recent years, halide perovskite materials have been used to make high-performance solar cells and light-emitting devices. However, material defects still limit device performance and stability. Here, synchrotron-based Bragg coherent diffraction imaging is used to visualize nanoscale strain fields, such as those local to defects, in halide perovskite microcrystals. Significant strain heterogeneity within MAPbBr3 (MA = CH3 NH3 + ) crystals is found in spite of their high optoelectronic quality, and both 〈100〉 and 〈110〉 edge dislocations are identified through analysis of their local strain fields. By imaging these defects and strain fields in situ under continuous illumination, dramatic light-induced dislocation migration across hundreds of nanometers is uncovered. Further, by selectively studying crystals that are damaged by the X-ray beam, large dislocation densities and increased nanoscale strains are correlated with material degradation and substantially altered optoelectronic properties assessed using photoluminescence microscopy measurements. These results demonstrate the dynamic nature of extended defects and strain in halide perovskites, which will have important consequences for device performance and operational stability
Recommended from our members
Imaging Light-Induced Migration of Dislocations in Halide Perovskites with 3d Nanoscale Strain Mapping.
In recent years, halide perovskite materials have been used to make high performance solar cell and light-emitting devices. However, material defects still limit device performance and stability. Here, we use synchrotron-based Bragg Coherent Diffraction Imaging to visualise nanoscale strain fields, such as those local to defects, in halide perovskite microcrystals. We find significant strain heterogeneity within MAPbBr3 (MA = CH3 NH3 + ) crystals in spite of their high optoelectronic quality, and identify both 〈100〉 and 〈110〉 edge dislocations through analysis of their local strain fields. By imaging these defects and strain fields in situ under continuous illumination, we uncover dramatic light-induced dislocation migration across hundreds of nanometers. Further, by selectively studying crystals that are damaged by the X-ray beam, we correlate large dislocation densities and increased nanoscale strains with material degradation and substantially altered optoelectronic properties assessed using photoluminescence microscopy measurements. Our results demonstrate the dynamic nature of extended defects and strain in halide perovskites, which will have important consequences for device performance and operational stability. This article is protected by copyright. All rights reserved
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Strain Heterogeneity and Extended Defects in Halide Perovskite Devices
Publication status: PublishedStrain is an important property in halide perovskite semiconductors used for optoelectronic applications because of its ability to influence device efficiency and stability. However, descriptions of strain in these materials are generally limited to bulk averages of bare films, which miss important property-determining heterogeneities that occur on the nanoscale and at interfaces in multilayer device stacks. Here, we present three-dimensional nanoscale strain mapping using Bragg coherent diffraction imaging of individual grains in Cs0.1FA0.9PbÂ(I0.95Br0.05)3 and Cs0.15FA0.85SnI3 (FA = formamidinium) halide perovskite absorbers buried in full solar cell devices. We discover large local strains and striking intragrain and grain-to-grain strain heterogeneity, identifying distinct islands of tensile and compressive strain inside grains. Additionally, we directly image dislocations with surprising regularity in Cs0.15FA0.85SnI3 grains and find evidence for dislocation-induced antiphase boundary formation. Our results shine a rare light on the nanoscale strains in these materials in their technologically relevant device setting
Ultrafast Bragg coherent diffraction imaging of epitaxial thin films using deep complex-valued neural networks
Abstract Domain wall structures form spontaneously due to epitaxial misfit during thin film growth. Imaging the dynamics of domains and domain walls at ultrafast timescales can provide fundamental clues to features that impact electrical transport in electronic devices. Recently, deep learning based methods showed promising phase retrieval (PR) performance, allowing intensity-only measurements to be transformed into snapshot real space images. While the Fourier imaging model involves complex-valued quantities, most existing deep learning based methods solve the PR problem with real-valued based models, where the connection between amplitude and phase is ignored. To this end, we involve complex numbers operation in the neural network to preserve the amplitude and phase connection. Therefore, we employ the complex-valued neural network for solving the PR problem and evaluate it on Bragg coherent diffraction data streams collected from an epitaxial La2-xSrxCuO4 (LSCO) thin film using an X-ray Free Electron Laser (XFEL). Our proposed complex-valued neural network based approach outperforms the traditional real-valued neural network methods in both supervised and unsupervised learning manner. Phase domains are also observed from the LSCO thin film at an ultrafast timescale using the complex-valued neural network