Nano-machining for advanced X-ray crystal optics

Zápražný, Zdenko; Korytár, D.; Jergel, M.; Šiffalovič, Peter; Halahovets, Yuriy; Keckes, Jozef; Maťko, I.; Ferrari, C.; Vagovič, Patrik; Mikloška, Marek

doi:10.1063/1.4961133

Cited by 5 publications

(3 citation statements)

References 8 publications

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“…The manufacturer guarantees a shape accuracy ≤ 150 nm over 75 mm diameter and a surface roughness ≤ 3 nm (Ra). More nominal parameters are summarized in [7]. Round nose (𝑅 = 1, 494 mm) single crystal diamond tool with cutting edge radius below 50 nm and negative rake angle of −25 deg was used for nanomachining (SPDT).…”

Section: Sample Preparationmentioning

confidence: 99%

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Testing of thickness homogeneity of Si crystal membranes using GaAs Timepix detector

Zápražný¹,

Затько²,

Korytár³

et al. 2021

J. Inst.

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Silicon (Si) membranes were prepared using high precision advance nanomachining technology utilizing single point diamond turning (SPDT). We showed that SPDT allowed to produce membranes with a surface undulation down to 500 nm over diameter of 7800 μm which corresponds to a high accuracy of the surface profile. We used X-ray digital radiography based on absorption contrast for a non-destructive measurement of the thickness distribution within a thin Si crystal membrane. The semi-insulating Gallium Arsenide (SI GaAs) pixel detector bump-bonded to the Timepix readout chip was used as a highly efficient single photon counting X-ray imaging detector. Comparison of thickness values obtained by the SI GaAs Timepix detector with values obtained with a surface stand-type micrometer gauge showed comparable results and the thickness variation within the membrane was clearly detected with a standard deviation down to 8.4 μm. The thickness resolution down to 5 μm over distances of 4–8 mm was achieved in selected areas of the sample.

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Section: Sample Preparationmentioning

confidence: 99%

“…In this paper, we present a study of the thickness homogeneity of a Si single-crystal membrane produced by nanomachining using single point diamond turning (SPDT) [7][8][9][10]. Using a precise beam hardening correction of the absorption data from GaAs Timepix detector we are able to calculate the thickness of the testing object [11].…”

Section: Introductionmentioning

confidence: 99%

Testing of thickness homogeneity of Si crystal membranes using GaAs Timepix detector

Zápražný¹,

Затько²,

Korytár³

et al. 2021

J. Inst.

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show abstract

“…This result thus demonstrates the limitations of the V-shaped CCM design imposed by present technology of X-ray surfaces, which is particularly demanding for constrained surfaces such as CCM channel walls. To face this challenge, we are working at present on using the single-point diamond turning technology for deterministic nanomachining of X-ray surfaces (Zá pražný et al, 2016;Jergel et al, 2018).…”

Section: Figure 14mentioning

confidence: 99%

Exploiting the potential of beam-compressing channel-cut monochromators for laboratory high-resolution small-angle X-ray scattering experiments

et al. 2019

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A systematic study of beam‐compressing monolithic channel‐cut monochromators (CCMs) with a V‐shaped channel was performed. The CCMs were optimized in terms of a chosen output beam parameter for exploitation in laboratory high‐resolution small‐angle X‐ray scattering (SAXS) and grazing‐incidence SAXS (GISAXS) experiments. Ray‐tracing simulations provided maps of particular Ge(220) CCM output beam parameters over the complete set of asymmetry angles of the two CCM diffractions. This allowed the design and fabrication of two dedicated CCMs, one optimized for maximum photon flux per detector pixel and the other for Kα2 suppression. The output beam quality was tested in SAXS/GISAXS experiments on a commercial setup with a liquid‐metal‐jet Ga microfocus X‐ray source connected to 2D collimating Montel optics. The performance of the CCM optimized for maximum photon flux per detector pixel was limited by the quality of the inner channel walls owing to a strongly asymmetric design. However, the CCM optimized for Kα2 suppression exhibited an excellent resolution of 314 nm in real space. This was further enhanced up to 524 nm by a parallel Ge(220) CCM in the dispersive configuration at a still applicable output flux of 3 × 106 photon s−1. The 314 nm resolution outperforms by more than 2.5× the upper resolution limit of the same setup with a pinhole collimator instead of the CCM. Comparative SAXS measurements on the same setup with a Kratky block collimator as an alternative to the CCM showed that the CCM provided more than one order higher transmittance at a comparable resolution or twice higher resolution at a comparable transmittance. These results qualify CCMs for a new type of integrated reflective–diffractive optics consisting of Göbel mirrors and V‐shaped CCMs for the next generation of high‐performance microfocus laboratory X‐ray sources.

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