W.S. Brocklesby scite author profile

Ptychography is a scanning coherent diffractive imaging (CDI) technique that relies upon a high level of stability of the illumination during the course of an experiment. This is particularly an issue for coherent short wavelength sources, where the beam intensity is usually tightly focused on the sample in order to maximize the photon flux density on the illuminated region of the sample and thus a small change in the beam position results in a significant change in illumination of the sample. We present an improved ptychographic method that allows for limited stability of the illumination wavefront and thus significantly improve the reconstruction quality without additional prior knowledge. We have tested our reconstruction method in a proof of concept experiment, where the beam instability of a visible light source was emulated using a piezo driven mirror, and also in a short wavelength microscopy CDI setup using a high harmonic generation source in the extreme ultraviolet range. Our work shows a natural extension of the ptychography method that paves the way to use ptychographic imaging with any limited pointing stability coherent source such as free electron or soft X-ray lasers and improve reconstruction quality of long duration synchrotron experiments.

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Ion-exchanged Er/Yb waveguide laser at 1.5 µmpumped by laser diode

Román

Camy

Hempstead

et al. 1995

Electron. Lett.

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Wide-field broadband extreme ultraviolet transmission ptychography using a high-harmonic source

et al. 2016

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High-harmonic generation (HHG) provides a laboratory-scale source of coherent radiation ideally suited to lensless coherent diffractive imaging (CDI) in the EUV and x-ray spectral region. Here we demonstrate transmission extreme ultraviolet (EUV) ptychography, a scanning variant of CDI, using radiation at a wavelength around 29 nm from an HHG source. Image resolution is diffraction-limited at 54 nm and fields of view up to ∼100 μm are demonstrated. These results demonstrate the potential for wide-field, high-resolution, laboratory-scale EUV imaging using HHG-based sources with potential application in biological imaging or EUV lithography pellicle inspection.

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Progress in high average power ultrafast lasers

Brocklesby

2015

Eur. Phys. J. Spec. Top.

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The impact of femtosecond lasers across science and engineering has been significant. The one area which has so far proved hard to access for femtosecond lasers has been the combination of high peak power and high average power. This review seeks to highlight the issues which make high average power hard to achieve in many femtosecond systems, and looks at the routes that are now being taken to achieve the goal of high peak and high average power. Managing thermal and nonlinear effectsThe technological problems involved in producing high average power lasers and high peak power lasers are significantly different. In a high average power laser system, the principal problem is managing the thermal load within the laser, because any

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Quantitative and correlative extreme ultraviolet coherent imaging of mouse hippocampal neurons at high resolution

et al. 2020

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Microscopy with extreme ultraviolet (EUV) light can provide many advantages over optical, hard x-ray or electron-based techniques. However, traditional EUV sources and optics have large disadvantages of scale and cost. Here, we demonstrate the use of a laboratory-scale, coherent EUV source to image biological samples—mouse hippocampal neurons—providing quantitative phase and amplitude transmission information with a lateral resolution of 80 nm and an axial sensitivity of ~1 nm. A comparison with fluorescence imaging of the same samples demonstrated EUV imaging was able to identify, without the need for staining or superresolution techniques, <100-nm-wide and <10-nm-thick structures not observable from the fluorescence images. Unlike hard x-ray microscopy, no damage is observed of the delicate neuron structure. The combination of previously demonstrated tomographic imaging techniques with the latest advances in laser technologies and coherent EUV sources has the potential for high-resolution element-specific imaging within biological structures in 3D.

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W.S. Brocklesby

Ptychographic coherent diffractive imaging with orthogonal probe relaxation

Ion-exchanged Er/Yb waveguide laser at 1.5 µmpumped by laser diode

Wide-field broadband extreme ultraviolet transmission ptychography using a high-harmonic source

Progress in high average power ultrafast lasers

Quantitative and correlative extreme ultraviolet coherent imaging of mouse hippocampal neurons at high resolution

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