Your search keyword '"Hovden, R"' showing total 6 results

1. Dynamic compressed sensing for real-time tomographic reconstruction.

Author

Schwartz J, Zheng H, Hanwell M, Jiang Y, and Hovden R

Subjects

Algorithms, Gold chemistry, Microscopy, Electron, Scanning Transmission methods, Nanoparticles chemistry, Oxides chemistry, Phantoms, Imaging, Strontium chemistry, Titanium chemistry, Tomography, X-Ray Computed methods, Data Compression methods, Electron Microscope Tomography methods, Imaging, Three-Dimensional instrumentation, Imaging, Three-Dimensional methods

Abstract

Electron tomography has achieved higher resolution and quality at reduced doses with recent advances in compressed sensing. Compressed sensing (CS) exploits the inherent sparse signal structure to efficiently reconstruct three-dimensional (3D) volumes at the nanoscale from undersampled measurements. However, the process bottlenecks 3D reconstruction with computation times that run from hours to days. Here we demonstrate a framework for dynamic compressed sensing that produces a 3D specimen structure that updates in real-time as new specimen projections are collected. Researchers can begin interpreting 3D specimens as data is collected to facilitate high-throughput and interactive analysis. Using scanning transmission electron microscopy (STEM), we show that dynamic compressed sensing accelerates the convergence speed by ~3-fold while also reducing its error by 27% for a Au/SrTiO 3 nanoparticle specimen. Before a tomography experiment is completed, the 3D tomogram has interpretable structure within ~33% of completion and fine details are visible as early as ~66%. Upon completion of an experiment, a high-fidelity 3D visualization is produced without further delay. Additionally, reconstruction parameters that tune data fidelity can be manipulated throughout the computation without re-running the entire process., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

2. Imaging Polarity in Two Dimensional Materials by Breaking Friedel's Law.

Author

Deb P, Cao MC, Han Y, Holtz ME, Xie S, Park J, Hovden R, and Muller DA

Abstract

Friedel's law guarantees an inversion-symmetric diffraction pattern for thin, light materials where a kinematic approximation or a single-scattering model holds. Typically, breaking Friedel symmetry is ascribed to multiple scattering events within thick, non-centrosymmetric crystals. However, two-dimensional (2D) materials such as a single monolayer of MoS 2 can also violate Friedel's law, with unexpected contrast between conjugate Bragg peaks. We show analytically that retaining higher order terms in the power series expansion of the scattered wavefunction can describe the anomalous contrast between hkl and hkl¯peaks that occurs in 2D crystals with broken in-plane inversion symmetry. These higher-order terms describe multiple scattering paths starting from the same atom in an atomically thin material. Furthermore, 2D materials containing heavy elements, such as WS 2 , always act as strong phase objects, violating Friedel's law no matter how high the energy of the incident electron beam. Experimentally, this understanding can enhance diffraction-based techniques to provide rapid imaging of polarity, twin domains, in-plane rotations, or other polar textures in 2D materials., Competing Interests: Declaration of Competing Interest None., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

3. Image registration of low signal-to-noise cryo-STEM data.

Author

Savitzky BH, El Baggari I, Clement CB, Waite E, Goodge BH, Baek DJ, Sheckelton JP, Pasco C, Nair H, Schreiber NJ, Hoffman J, Admasu AS, Kim J, Cheong SW, Bhattacharya A, Schlom DG, McQueen TM, Hovden R, and Kourkoutis LF

Abstract

Combining multiple fast image acquisitions to mitigate scan noise and drift artifacts has proven essential for picometer precision, quantitative analysis of atomic resolution scanning transmission electron microscopy (STEM) data. For very low signal-to-noise ratio (SNR) image stacks - frequently required for undistorted imaging at liquid nitrogen temperatures - image registration is particularly delicate, and standard approaches may either fail, or produce subtly specious reconstructed lattice images. We present an approach which effectively registers and averages image stacks which are challenging due to their low-SNR and propensity for unit cell misalignments. Registering all possible image pairs in a multi-image stack leads to significant information surplus. In combination with a simple physical picture of stage drift, this enables identification of incorrect image registrations, and determination of the optimal image shifts from the complete set of relative shifts. We demonstrate the effectiveness of our approach on experimental, cryogenic STEM datasets, highlighting subtle artifacts endemic to low-SNR lattice images and how they can be avoided. High-SNR average images with information transfer out to 0.72 Å are achieved at 300 kV and with the sample cooled to near liquid nitrogen temperature., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

4. Sampling limits for electron tomography with sparsity-exploiting reconstructions.

Author

Jiang Y, Padgett E, Hovden R, and Muller DA

Abstract

Electron tomography (ET) has become a standard technique for 3D characterization of materials at the nano-scale. Traditional reconstruction algorithms such as weighted back projection suffer from disruptive artifacts with insufficient projections. Popularized by compressed sensing, sparsity-exploiting algorithms have been applied to experimental ET data and show promise for improving reconstruction quality or reducing the total beam dose applied to a specimen. Nevertheless, theoretical bounds for these methods have been less explored in the context of ET applications. Here, we perform numerical simulations to investigate performance of ℓ 1 -norm and total-variation (TV) minimization under various imaging conditions. From 36,100 different simulated structures, our results show specimens with more complex structures generally require more projections for exact reconstruction. However, once sufficient data is acquired, dividing the beam dose over more projections provides no improvements-analogous to the traditional dose-fraction theorem. Moreover, a limited tilt range of ±75° or less can result in distorting artifacts in sparsity-exploiting reconstructions. The influence of optimization parameters on reconstructions is also discussed., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2018

5. Breaking the Crowther limit: combining depth-sectioning and tilt tomography for high-resolution, wide-field 3D reconstructions.

Author

Hovden R, Ercius P, Jiang Y, Wang D, Yu Y, Abruña HD, Elser V, and Muller DA

Abstract

To date, high-resolution (<1 nm) imaging of extended objects in three-dimensions (3D) has not been possible. A restriction known as the Crowther criterion forces a tradeoff between object size and resolution for 3D reconstructions by tomography. Further, the sub-Angstrom resolution of aberration-corrected electron microscopes is accompanied by a greatly diminished depth of field, causing regions of larger specimens (>6 nm) to appear blurred or missing. Here we demonstrate a three-dimensional imaging method that overcomes both these limits by combining through-focal depth sectioning and traditional tilt-series tomography to reconstruct extended objects, with high-resolution, in all three dimensions. The large convergence angle in aberration corrected instruments now becomes a benefit and not a hindrance to higher quality reconstructions. A through-focal reconstruction over a 390 nm 3D carbon support containing over 100 dealloyed and nanoporous PtCu catalyst particles revealed with sub-nanometer detail the extensive and connected interior pore structure that is created by the dealloying instability., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

6. Efficient elastic imaging of single atoms on ultrathin supports in a scanning transmission electron microscope.

Author

Hovden R and Muller DA

Subjects

Adenosine Triphosphate chemistry, Graphite chemistry, Quantum Theory, Microscopy, Electron, Scanning Transmission instrumentation, Microscopy, Electron, Scanning Transmission methods

Abstract

Mono-atomic-layer membranes such as graphene offer new opportunities for imaging and detecting individual light atoms in transmission electron microscopes (TEM). For such applications where multiple scattering and diffraction effects are weak, we evaluate the detection efficiency and interpretability of single atom images for the most common detector geometries using quantitative quantum mechanical simulations. For well-resolved and atomically-thin specimens, the low angle annular dark field (LAADF) detector can provide a significant increase in signal-to-noise over other common detector geometries including annular bright field and incoherent bright field. This dramatically improves the visibility of organic specimens on atomic-layer membranes. Simulations of Adenosine Triphosphate (ATP) imaged under ideal conditions indicate the minimal dose requirements for elastic imaging by STEM or conventional TEM still exceed previously reported dose limits., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012