Kawal Sawhney scite author profile

Recently, solid state photovoltaic Schottky diodes, able to detect ionizing radiation, in particular, x-ray and ultraviolet radiation, have been developed at the University of Rome “Tor Vergata.” We report on a physical and electrical properties analysis of the device and a detailed study of its detection capabilities as determined by its electrical properties. The design of the device is based on a metal/nominally intrinsic/p-type diamond layered structure obtained by microwave plasma chemical vapor deposition of homoepitaxial single crystal diamond followed by thermal evaporation of a metallic contact. The device can operate in an unbiased mode by using the built-in potential arising from the electrode-diamond junction. We compare the expected response of the device to photons of various energies calculated through Monte Carlo simulation with experimental data collected in a well controlled experimental setup i.e., monochromatic high flux x-ray beams from 6 to 20 keV, available at the Diamond Light Source synchrotron in Harwell (U.K.).

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The Diamond-NOM: A non-contact profiler capable of characterizing optical figure error with sub-nanometre repeatability

Alcock

Sawhney

Scott

et al. 2010

Nuclear Instruments and Methods in Physics Research Section A:

152

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A novel undulator-based PGM beamline for circularly polarised synchrotron radiation at BESSY II

Sawhney

Senf

Scheer

et al. 1997

Nuclear Instruments and Methods in Physics Research Section A:

115

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From synchrotron radiation to lab source: advanced speckle-based X-ray imaging using abrasive paper

Wang

Kashyap

Sawhney

2016

Sci Rep

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X-ray phase and dark-field imaging techniques provide complementary and inaccessible information compared to conventional X-ray absorption or visible light imaging. However, such methods typically require sophisticated experimental apparatus or X-ray beams with specific properties. Recently, an X-ray speckle-based technique has shown great potential for X-ray phase and dark-field imaging using a simple experimental arrangement. However, it still suffers from either poor resolution or the time consuming process of collecting a large number of images. To overcome these limitations, in this report we demonstrate that absorption, dark-field, phase contrast, and two orthogonal differential phase contrast images can simultaneously be generated by scanning a piece of abrasive paper in only one direction. We propose a novel theoretical approach to quantitatively extract the above five images by utilising the remarkable properties of speckles. Importantly, the technique has been extended from a synchrotron light source to utilise a lab-based microfocus X-ray source and flat panel detector. Removing the need to raster the optics in two directions significantly reduces the acquisition time and absorbed dose, which can be of vital importance for many biological samples. This new imaging method could potentially provide a breakthrough for numerous practical imaging applications in biomedical research and materials science.

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The elliptically polarized undulator beamlines at BESSY II

Weiß¹,

Follath²,

Sawhney

et al. 2001

Nuclear Instruments and Methods in Physics Research Section A:

100

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A Test Beamline on Diamond Light Source

Sawhney¹,

Dolbnya²,

Tiwari³

et al. 2010

111

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The penetrating power of X-rays coupled with the high flux of 3rd generation synchrotron sources makes X-ray tomography to excel among fast imaging methods. To exploit this asset of synchrotron sources is the motivation for setting up an ultra-fast tomography endstation at the TOMCAT beamline. The state of the art instruments at synchrotron sources offer routinely a temporal resolution of tens of seconds in tomography. For a number of applications, for example biomedical studies, the relevant time scales (breathing, heartbeat) are rather in the range of 0.5-2 seconds. To overcome motion artifacts when imaging such systems a new ultra-fast tomographic data acquisition scheme is being developed at the TOMCAT beamline. We can acquire a full set of projections at sub-second timescale in monochromatic or white-beam configuration. We present a feasibility study with the ultimate aim to achieve sub-second temporal resolution in 3D without significant deterioration of the spatial resolution. For the first time, the 3D dynamics of the very early stages of a quickly aging liquid foam can be visualised with high quality and sufficiently large field of view. Abstract. The penetrating power of X-rays coupled with the high flux of 3rd generation synchrotron sources makes X-ray tomography to excel among fast imaging methods. To exploit this asset of synchrotron sources is the motivation for setting up an ultra-fast tomography endstation at the TOMCAT beamline. The state of the art instruments at synchrotron sources offer routinely a temporal resolution of tens of seconds in tomography. For a number of applications, for example biomedical studies, the relevant time scales (breathing, heartbeat) are rather in the range of 0.5-2 seconds. To overcome motion artifacts when imaging such systems a new ultra-fast tomographic data acquisition scheme is being developed at the TOMCAT beamline. We can acquire a full set of projections at sub-second timescale in monochromatic or white-beam configuration. We present a feasibility study with the ultimate aim to achieve sub-second temporal resolution in 3D without significant deterioration of the spatial resolution. For the first time, the 3D dynamics of the very early stages of a quickly aging liquid foam can be visualised with high quality and sufficiently large field of view.

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Characterization of Medipix3 With Synchrotron Radiation

Gimenez

Ballabriga

Campbell

et al. 2011

IEEE Trans. Nucl. Sci.

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showed that when Medipix3 is operated in CSM mode, it generates a single count per detected event and consequently the charge sharing effect between adjacent pixels is eliminated. However in CSM mode, it was also observed that an incorrect allocation of X-rays counts in the pixels occurred due to an unexpectedly high pixel-to-pixel threshold variation. The present experiment helped to better understand the CSM operating mode and to redesign the Medipix3 to overcome this pixel-to-pixel mismatch.Index Terms-Medipix3, synchrotron radiation, X-ray detectors, X-ray imaging.

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Kawal Sawhney

X-ray multimodal imaging using a random-phase object

Chemical vapor deposition diamond based multilayered radiation detector: Physical analysis of detection properties

The Diamond-NOM: A non-contact profiler capable of characterizing optical figure error with sub-nanometre repeatability

A novel undulator-based PGM beamline for circularly polarised synchrotron radiation at BESSY II

From synchrotron radiation to lab source: advanced speckle-based X-ray imaging using abrasive paper

The elliptically polarized undulator beamlines at BESSY II

A Test Beamline on Diamond Light Source

Characterization of Medipix3 With Synchrotron Radiation

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