Synchrotron Big Data Science

Wang, Chunpeng; Steiner, Ullrich; Sepe, Alessandro

doi:10.1002/smll.201802291

Cited by 46 publications

(32 citation statements)

References 74 publications

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“…Many synchrotron beamlines generate on the orders of 1 TB/day of data; advanced detectors such as the GigaFRoST detector at the Swiss Light Source now generate 8.8 GB/s. 106 The rate-limiting step is no longer acquisition of materials information, but reconstruction and analysis of that information. Collaborative efforts across beamline facilities are underway to deploy massively parallel codes and real-time algorithms.…”

Section: Materials Datamentioning

confidence: 99%

The evolving landscape for alloy design

Pollock

Ven

2019

MRS Bull.

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Section: Materials Datamentioning

confidence: 99%

The evolving landscape for alloy design

Pollock

Ven

2019

MRS Bull.

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“…TR X-ray micro scopy generates multidimensional data corresponding to 3D real space, 3D reciprocal space, and multidimensional spectra, and the analysis of these data awakes the necessity of progress in the computer vision and image reconstruction. [168,169] Single-molecule absorption-scanning tunneling microscopy (SMA-STM) is an emerging tool to image the electronic excited states at different orientation that could give a better 3D structure view of the excited states. [170] The SMA-STM is advancing towards the possibility of single-particle tomography of excited states that could highlight the defects rather than an average structure obtained via cryo-TEM.…”

Section: Challenges and Future Developments Of Tr-and Sr-based Qd Metmentioning

confidence: 99%

Quantum Dots Microstructural Metrology: From Time‐Resolved Spectroscopy to Spatially Resolved Electron Microscopy

Hasna

Hou

Welland

2020

Part & Part Syst Charact

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Quantum dots (QDs) have gained broad acceptance, applicability, and much interest in current semiconductor technology due to their unique optical and electrical properties. [1,2] QDs are semiconductors with size between 3 and 20 nm where electron and hole wave functions are highly confined. [3] The dimension should be comparable to the Bohr exciton radius of the material, and that leads to discrete energy levels in QD. QDs are attracted by their unique atomiclike narrow emission that can be tuned easily by controlling their size, structure, and composition. [4-6] The optical and electrical properties of QDs are better than organic fluorophores. For instance, QD has high quantum efficiency, excellent color gamut, narrow emission bandwidths, broad color tunability, high photostability, and high air stability. [7] These excellent properties make QD a potential candidate for applications in various fields such as optoelectronics, sensing, and imaging. [1,8-10] QDs are typically composed of group II-VI, III-V, and IV-VI compound semiconductors such as CdS, CdSe, PbS, ZnS, InAs, and ZnInS. [11-16] Because of minimal particle diameter, QDs have a high surface-to-volume ratio, and these surface trap states act as centers for nonradiative transitions that diminish the performance of QDs. This can be overcome by the growth of inorganic shells such as ZnS, CdTe, and CdSe. Various core-shell QDs such as CdSe/ZnS,

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“…Sub-pixel inaccuracies may cause blurring of the network output, for example. Finally, with fewer than 50 synchrotron facilities worldwide, beamtime is a scarce resource 16 , and acquiring additional measurements may simply be too expensive.…”

Section: Introductionmentioning

confidence: 99%

Deep denoising for multi-dimensional synchrotron X-ray tomography without high-quality reference data

Hendriksen

Bührer

Leone

et al. 2021

Sci Rep

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Synchrotron X-ray tomography enables the examination of the internal structure of materials at submicron spatial resolution and subsecond temporal resolution. Unavoidable experimental constraints can impose dose and time limits on the measurements, introducing noise in the reconstructed images. Convolutional neural networks (CNNs) have emerged as a powerful tool to remove noise from reconstructed images. However, their training typically requires collecting a dataset of paired noisy and high-quality measurements, which is a major obstacle to their use in practice. To circumvent this problem, methods for CNN-based denoising have recently been proposed that require no separate training data beyond the already available noisy reconstructions. Among these, the Noise2Inverse method is specifically designed for tomography and related inverse problems. To date, applications of Noise2Inverse have only taken into account 2D spatial information. In this paper, we expand the application of Noise2Inverse in space, time, and spectrum-like domains. This development enhances applications to static and dynamic micro-tomography as well as X-ray diffraction tomography. Results on real-world datasets establish that Noise2Inverse is capable of accurate denoising and enables a substantial reduction in acquisition time while maintaining image quality.

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Synchrotron Big Data Science

Cited by 46 publications

References 74 publications

The evolving landscape for alloy design

The evolving landscape for alloy design

Quantum Dots Microstructural Metrology: From Time‐Resolved Spectroscopy to Spatially Resolved Electron Microscopy

Deep denoising for multi-dimensional synchrotron X-ray tomography without high-quality reference data

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