Four-dimensional emittance measurements of ultrafast electron diffraction optics corrected up to sextupole order

Gordon, Mollie; Li, W. H.; Andorf, Matthew; Bartnik, Adam; Duncan, Cameron; Kaemingk, M.; Pennington, Christopher; Bazarov, Ivan; Kim, Young-Kee; Maxson, Jared

doi:10.1103/physrevaccelbeams.25.084001

Cited by 5 publications

(4 citation statements)

References 52 publications

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“…High quantum efficiency (QE) and low-emittance electron beams provided by multi-alkali photocathodes make them of great interest for next-generation high-brightness photoinjectors. When operated with photon energy close to their workfunction, these photocathodes can provide electron beams suitable for ultrafast electron diffraction (UED) and/or ultrafast electron microscopy (UEM) by having a lower emittance and higher QEs compared to those of metals [41,42].…”

Section: Critial Components 231 Photocathode Electron Sourcementioning

confidence: 99%

“…Even with a state-of-the art photoemission MTE of 35 meV as demonstrated in alkali antimonide photocathodes [41,42], 10 pm normalized source emittance requires an RMS emission size of 20 nm. However, due to the proximity of the optical diffraction limit, generating laser spots of even a few microns is a non-trivial task: photocathodes in most photoinjectors are typically operated in reflection mode in high electric fields of highvoltage DC or RF guns, and the final lens of the optical imaging system for the laser to the photocathode surface cannot be located closer than tens of centimeters from the cathode surface itself, which typically yields photoemission source sizes >10 µm in RMS.…”

Section: Critial Components 231 Photocathode Electron Sourcementioning

confidence: 99%

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Towards Construction of a Novel Nanometer-Resolution MeV-STEM for Imaging Thick Frozen Biological Samples

Yang,

Wang,

Maxson

et al. 2024

Photonics

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Driven by life-science applications, a mega-electron-volt Scanning Transmission Electron Microscope (MeV-STEM) has been proposed here to image thick frozen biological samples as a conventional Transmission Electron Microscope (TEM) may not be suitable to image samples thicker than 300–500 nm and various volume electron microscopy (EM) techniques either suffering from low resolution, or low speed. The high penetration of inelastic scattering signals of MeV electrons could make the MeV-STEM an appropriate microscope for biological samples as thick as 10 μm or more with a nanoscale resolution, considering the effect of electron energy, beam broadening, and low-dose limit on resolution. The best resolution is inversely related to the sample thickness and changes from 6 nm to 24 nm when the sample thickness increases from 1 μm to 10 μm. To achieve such a resolution in STEM, the imaging electrons must be focused on the specimen with a nm size and an mrad semi-convergence angle. This requires an electron beam emittance of a few picometers, which is ~1000 times smaller than the presently achieved nm emittance, in conjunction with less than 10−4 energy spread and 1 nA current. We numerically simulated two different approaches that are potentially applicable to build a compact MeV-STEM instrument: (1) DC (Direct Current) gun, aperture, superconducting radio-frequency (SRF) cavities, and STEM column; (2) SRF gun, aperture, SRF cavities, and STEM column. Beam dynamic simulations show promising results, which meet the needs of an MeV-STEM, a few-picometer emittance, less than 10−4 energy spread, and 0.1–1 nA current from both options. Also, we designed a compact STEM column based on permanent quadrupole quintuplet, not only to demagnify the beam size from 1 μm at the source point to 2 nm at the specimen but also to provide the freedom of changing the magnifications at the specimen and a scanning system to raster the electron beam across the sample with a step size of 2 nm and the repetition rate of 1 MHz. This makes it possible to build a compact MeV-STEM and use it to study thick, large-volume samples in cell biology.

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Section: Critial Components 231 Photocathode Electron Sourcementioning

confidence: 99%

Section: Critial Components 231 Photocathode Electron Sourcementioning

confidence: 99%

Towards Construction of a Novel Nanometer-Resolution MeV-STEM for Imaging Thick Frozen Biological Samples

Yang,

Wang,

Maxson

et al. 2024

Photonics

View full text Add to dashboard Cite

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“…Tomographic measurement techniques are used in accelerators to determine the density distribution of beam particles in phase space ρ(x, p x , y, p y , z, p z ) from limited measurements [12,13,14,15,16,17]. While these methods have been shown to effectively reconstruct 2D phase spaces from image projections using algebraic methods, application to higher-dimensional spaces requires independence assumptions between the phase spaces of principal coordinate axes (x, y, z), complicated phase space rotation procedures [18], or measurement of multiple 2D sub-spaces with specialized diagnostic hardware [19].…”

Section: Phase Space Reconstructionmentioning

confidence: 99%

Applications of Differentiable Physics Simulations in Particle Accelerator Modeling

Roussel¹,

Edelen²

2022

Preprint

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Current physics models used to interpret experimental measurements of particle beams require either simplifying assumptions to be made in order to ensure analytical tractability, or black box optimization methods to perform model based inference. This reduces the quantity and quality of information gained from experimental measurements, in a system where measurements have a limited availability. However differentiable physics modeling, combined with machine learning techniques, can overcome these analysis limitations, enabling accurate, detailed model creation of physical accelerators. Here we examine two applications of differentiable modeling, first to characterize beam responses to accelerator elements exhibiting hysteretic behavior, and second to characterize beam distributions in high dimensional phase spaces.

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“… 20,21 After the sample, preliminary experiments have shown that the use of a magnetic lens can improve the reciprocal space resolution. 22,23 However, most beamlines still utilize a propagation drift to convert the scattering angles into a spatial offset at the detector.…”

Section: Introductionmentioning

confidence: 99%

High energy electron diffraction instrument with tunable camera length

Denham,

Yang,

Guo

et al. 2024

Structural Dynamics

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Ultrafast electron diffraction (UED) stands as a powerful technique for real-time observation of structural dynamics at the atomic level. In recent years, the use of MeV electrons from radio frequency guns has been widely adopted to take advantage of the relativistic suppression of the space charge effects that otherwise limit the temporal resolution of the technique. Nevertheless, there is not a clear choice for the optimal energy for a UED instrument. Scaling to beam energies higher than a few MeV does pose significant technical challenges, mainly related to the inherent increase in diffraction camera length associated with the smaller Bragg angles. In this study, we report a solution by using a compact post-sample magnetic optical system to magnify the diffraction pattern from a crystal Au sample illuminated by an 8.2 MeV electron beam. Our method employs, as one of the lenses of the optical system, a triplet of compact, high field gradients (>500 T/m), small-gap (3.5 mm) Halbach permanent magnet quadrupoles. Shifting the relative position of the quadrupoles, we demonstrate tuning the magnification by more than a factor of two, a 6× improvement in camera length, and reciprocal space resolution better than 0.1 Å−1 in agreement with beam transport simulations.

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Four-dimensional emittance measurements of ultrafast electron diffraction optics corrected up to sextupole order

Cited by 5 publications

References 52 publications

Towards Construction of a Novel Nanometer-Resolution MeV-STEM for Imaging Thick Frozen Biological Samples

Towards Construction of a Novel Nanometer-Resolution MeV-STEM for Imaging Thick Frozen Biological Samples

Applications of Differentiable Physics Simulations in Particle Accelerator Modeling

High energy electron diffraction instrument with tunable camera length

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