Your search keyword '"Carlo Pelliciari"' showing total 23 results

1. Large-format X-Ray Reflection Grating Operated in an Echelle-like Mounting

Author

Casey T. DeRoo, Randall L. McEntaffer, Benjamin D. Donovan, Fabien Grisé, Chad Eichfeld, Vadim Burwitz, Gisela Hartner, Carlo Pelliciari, and Marlis-Madeleine La Caria

Published

2020

2. X-ray tests of the ATHENA mirror modules in BEaTriX:from design to reality

Author

Bianca Salmaso, Stefano Basso, Mauro Ghigo, Daniele Spiga, Gabriele Vecchi, Giorgia Sironi, Vincenzo Cotroneo, Paolo Conconi, Edoardo Redaelli, Andrea Bianco, Giovanni Pareschi, Gianpiero Tagliaferri, Davide Sisana, Carlo Pelliciari, Mauro Fiorini, Salvatore Incorvaia, Michela Uslenghi, Lorenzo Paoletti, Claudio Ferrari, Andrea Zappettini, Riccardo Lolli, Manuel Sanchez del Rio, Giancarlo Parodi, Vadim Burwitz, Surangkhana Rukdee, Gisela Hartner, Thomas Müller, Thomas Schmidt, Andreas Langmeier, Desiree Della Monica Ferreira, Sonny Massahi, Nis Christian Gellert, Finn Christensen, Marcos Bavdaz, Ivo Ferreira, Max Collon, Giuseppe Vacanti, Nicolas M. Barriere, den Herder, Jan-Willem A., Nikzad, Shouleh, Nakazawa, Kazuhiro, ITA, FRA, DEU, and NLD

Subjects

Silicon Pore Optics, BEaTriX, X-ray microfocus source, Asymmetric diffraction, Beam expander, Crystals, ATHENA, X-ray testing

Abstract

The BEaTriX (Beam Expander Testing X-ray) facility is now operative at the INAF-Osservatorio Astronomico Brera (Merate, Italy). This facility has been specifically designed and built for the X-ray acceptance tests (PSF and Effective Area) of the ATHENA Silicon Pore Optics (SPO) Mirror Modules (MM). The unique setup creates a parallel, monochromatic, large X-ray beam, that fully illuminates the aperture of the MMs, generating an image at the ATHENA focal length of 12 m. This is made possible by a microfocus X-ray source followed by a chain of optical components (a paraboloidal mirror, 2 channel cut monochromators, and an asymmetric silicon crystal) able to expand the X-ray beam to a 6 cm × 17 cm size with a residual divergence of 1.5 arcsec (vertical) × 2.5 arcsec (horizontal). This paper reports the commissioning of the 4.5 keV beam line, and the first light obtained with a Mirror Module.

Published

2022

3. Optical simulations for the laboratory-based expanded and collimated x-ray beam facility BEaTriX

Author

Daniele Spiga, Marcos Bavdaz, Mauro Ghigo, M. Sanchez del Rio, Bianca Salmaso, G. Vecchi, Enrico Giro, Ivo Ferreira, G. Pareschi, Vadim Burwitz, Stefano Basso, Eric Wille, Carlo Pelliciari, G. Tagliaferri, ITA, FRA, DEU, and NLD

Subjects

Physics, business.industry, Polishing, Modular design, X ray beam, Collimated light, law.invention, Telescope, Optics, law, Homogeneity (physics), Beam expander, Tomography, business

Abstract

The construction of BEaTriX, the Beam Expander Testing X-ray facility, is underway at INAF-OAB (Osservatorio Astronomico di Brera). This laboratory-based X-ray source was designed to generate a broad (170 mm x 60 mm), uniform, and collimated X-ray beam, with a residual divergence of 1.5 arcsec HEW at either 1.49 keV and 4.51 keV. The main scientific driver for BEaTriX is represented by the opportunity to routinely calibrate the modular elements of the ATHENA (ESA) X-ray telescope, based on the silicon pore optics (SPO) technology. Nevertheless, the application domain of BEaTriX is potentially much wider (e.g., X-ray tomography). BEaTriX comprises a microfocus source of X-rays, followed by an optical chain including a collimating mirror, crystal monochromators, and an asymmetric beam expander. The final beam collimation and homogeneity relies on the optical quality of the optical components (X-ray source dimension, mirror polishing, crystal lattice regularity) and on their mutual alignment. In order to determine the most critical parameters, focus the development efforts, and establish specifications, a set of optical simulations has been built. Our paper describes the simulation tool we developed to this specific aim, and discusses the results achieved in terms of manufacturing and alignment tolerances.

Published

2019

4. BEaTriX (Beam Expander Testing X-ray facility) for testing ATHENA's SPO modules: advancement status

Author

Claudio Ferrari, Bianca Salmaso, Daniele Spiga, Vadim Burwitz, M. Sanchez del Rio, Enrico Giro, G. Pareschi, Mauro Ghigo, Eric Wille, Ivo Ferreira, G. Vecchi, Marcos Bavdaz, G. Tagliaferri, Andrea Zappettini, M. Fiorini, Stefano Basso, Mark Ayre, Michela Uslenghi, Carlo Pelliciari, Giancarlo Parodi, ITA, USA, FRA, DEU, and NLD

Subjects

Physics, business.industry, micro-focus source, X-ray, BEaTriX, X-ray optics, Modular design, beam expander, X-ray test facility, Synchrotron, law.invention, asymmetric diffraction, Optics, law, Observatory, Beam expander, business, Beam (structure), Production rate

Abstract

ATHENA Silicon Pore Optics (SPO) Mirror Modules (MM) have to be tested and accepted prior to integration in the full ATHENA Mirror Assembly (MA). X-ray tests of the MMs are currently performed at the PTB laboratory of the BESSY synchrotron facility in pencil beam configuration, but they require a PSF reconstruction. Full illumination X-ray tests could be performed using a broad, low-divergent X-ray beam like the one in use at PANTER (MPE, Neuried, Germany), but the large volume to be evacuated makes it impossible to perform the functional tests at the MMs production rate (3 MM/day). To overcome these limitations, we started in 2012 to design a facility aimed at generating a broad (170 x 60 mm2), uniform and low-divergent (1.5 arcsec HEW) X-ray beam within a small lab (∼ 9 x 18 m2), to characterize the ATHENA MM. BEaTriX (the Beam Expander Testing X-ray facility) makes use of an X-ray microfocus source, a paraboloidal mirror, a crystal monochromation system, and an asymmetrically-cut diffracting crystal for the beam expansion. These optical components, in addition to a modular low-vacuum level (10-3 mbar), enable to match the ATHENA SPO acceptance requirements. The realization of this facility at INAF-OAB in Merate (Italy) is now on going. Once completed, BEaTriX can be used to test the Silicon Pore Optics modules of the ATHENA X-ray observatory, as well as other optics, like the ones of the Arcus mission. In this paper we report the advancement status of the facility.

Published

2019

5. X-ray testing at PANTER of optics for the ATHENA and Arcus Missions

Author

Marcos Bavdaz, M. Collon, Andreas Langmeier, Stefan Felix Hartl, Ed Hertz, Marlis-Madeleine La Caria, Carlo Pelliciari, Richard Willingale, Giuseppe Valsecchi, Fabio Marioni, Dervis Vernani, Eric Wille, Gisela Hartner, Vadim Burwitz, Giuseppe Vacanti, Casey de Roo, Steffen Blum, Randall K. Smith, Nicolas M. Barrière, and Thibault Seure

Subjects

Point spread function, Physics, Vignetting, business.industry, X-ray, X-ray detector, X-ray optics, Synchrotron, law.invention, Optics, Beamline, law, Focal length, business

Abstract

Currently for the European Space Agency (ESA) ATHENA [1,2] mission Silicon Pore Optic (SPO) [3-8] Mirror Modules (MM) with a focal length of f = 12 m, are being developed and tested. The SPO MMs are also the baseline optic for the NASA medium explorer high-resolution spectroscopy mission Arcus [9-10] with f = 12 m that is currently undergoing a phase A study. SPOs are currently being tested at both the PTB laboratory of the BESSY synchrotron facility in Berlin using an X-ray pencil beam and the PANTER X-ray test facility in Neuried of the Max-Planck-Institut fur extraterrestrische Physik, Garching using a long vacuum beamline (distance source to optic ~120 m). The different types of measurements performed at PANTER to characterise the ATHENA and Arcus optics will be discussed. This will be done on the level of an X-ray optical unit (XOU) composed of both a primary and secondary High Performance Optic (HPO) stack, a mirror module (MM) composed of two XOUs, small (

Published

2019

6. Characterization of ammonium dihydrogen phosphate crystals for soft X-ray optics of the Beam Expander Testing X-ray facility (BEaTriX)

Author

Daniele Spiga, Claudio Ferrari, Bianca Salmaso, Sara Beretta, Stefano Basso, Enrico Giro, Carlo Pelliciari, Gianpiero Tagliaferri, Giovanni Pareschi, ITA, and DEU

Subjects

Diffraction, ADP, crystalline perfection, Materials science, Silicon, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, law.invention, 010309 optics, Crystal, Telescope, X-ray astronomy, lattice plane curvature measurement, chemistry.chemical_compound, Optics, law, 0103 physical sciences, ammonium dihydrogen phosphate, business.industry, X-ray, 021001 nanoscience & nanotechnology, Ammonium dihydrogen phosphate, Planarity testing, chemistry, Beam expander, residual strain measurement, 0210 nano-technology, business, X-ray topography

Abstract

A new type of X-ray facility, the Beam Expander Testing X-ray facility (BEaTriX), has been designed and is now under construction at INAF–Osservatorio Astronomico di Brera (Merate, Italy) to perform the acceptance tests of the silicon pore optics modules of the ATHENA X-ray telescope. Crystals of high perfection and large dimensions are needed in order to obtain a wide beam (20 × 6 cm) with an X-ray divergence of E/E < 10−5. To generate X-ray diffracted beams at an X-ray energy of 1.49 keV, ammonium dihydrogen phosphate (ADP) crystals have been considered among other possible choices, because of their reported crystal quality and because they can be grown at sufficiently large size at a reasonable price. In the present paper, the results of the characterization of crystalline quality and lattice planarity of a 20 × 20 × 2 mm ADP sample are reported.

Published

2019

7. Large-format X-Ray Reflection Grating Operated in an Echelle-like Mounting

Author

Carlo Pelliciari, Gisela Hartner, Benjamin D. Donovan, Fabien Grisé, Marlis Madeleine La Caria, Casey T. DeRoo, Chad Eichfeld, Vadim Burwitz, and Randall L. McEntaffer

Subjects

Physics, Optics, Space and Planetary Science, business.industry, X-ray, Astronomy and Astrophysics, Large format, Grating, business, Reflection (computer graphics)

Published

2020

8. Calibration of X-ray telescope prototypes at PANTER

Author

Xiaoqiang Wang, Carlo Pelliciari, Qiushi Huang, Zhanshan Wang, Marlis-Madeleine La Caria, Vadim Burwitz, Bin Ma, Gisela Hartner, Zhengxiang Shen, Kun Wang, Chun Xie, Zhong Zhang, Jun Yu, and Yingyu Liao

Subjects

Physics, Test facility, 010308 nuclear & particles physics, business.industry, Optical engineering, Antenna aperture, FOS: Physical sciences, Astronomy and Astrophysics, X-ray telescope, Astrophysics, 01 natural sciences, law.invention, Telescope, Optics, Space and Planetary Science, law, 0103 physical sciences, Calibration, Angular resolution, Astrophysics - Instrumentation and Methods for Astrophysics, business, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics

Abstract

We report a ground X-ray calibration of two X-ray telescope prototypes at the PANTER X-ray Test Facility, of the Max-Planck-Institute for Extraterrestrial Physics, in Neuried, Germany. The X-ray telescope prototypes were developed by the Institute of Precision Optical Engineering (IPOE) of Tongji University, in a conical Wolter-I configuration, using thermal glass slumping technology. Prototype #1 with 3 layers and Prototype #2 with 21 layers were tested to assess the prototypes' on-axis imaging performance. The measurement of Prototype #1 indicates a Half Power Diameter (HPD) of 82" at 1.49 keV. As for Prototype #2, we performed more comprehensive measurements of on-axis angular resolution and effective area at several energies ranging from 0.5-10 keV. The HPD and effective area are 111" and 39 cm^2 at 1.49 keV, respectively, at which energy the on-axis performance of the prototypes is our greatest concern., 11 pages, 9 figures

Published

2019

9. AHEAD joint research activity on x-ray optics

Author

René Hudec, Richard Willingale, Carlo Pelliciari, Vladimir Tichy, Bianca Salmaso, Giovanni Pareschi, Daniele Spiga, Vadim Burwitz, ITA, GBR, DEU, and CZE

Subjects

Parallel beam, Test facility, business.industry, Computer science, X-ray optics, 02 engineering and technology, Zone plate, 021001 nanoscience & nanotechnology, 01 natural sciences, Collimated light, law.invention, 010309 optics, Joint research, Optics, law, 0103 physical sciences, Calibration, media_common.cataloged_instance, European union, 0210 nano-technology, business, media_common

Abstract

The progress of X-ray Optics joint research activity of the European Union Horizon 2020 AHEAD project is presented here covering the X-ray optic technologies that are currently being worked on in Europe. These are the Kirkpatrick Baez, lobster eye micropore (SVOM, SMILE), slumped glass, and silicon pore (ATHENA, ARCUS) optics technologies. In this activity detailed comparisons of the measurements, of the different optics produced by the participating optics groups, obtained mainly at the MPEs PANTER X-ray test facility, are compared with simulations. In preparation for the ATHENA mission a study has been made to design the BEaTRiX X-ray test facility for testing individual silicon pore optics mirror modules, and the realization of the facility is now on going. A zone plate collimating optics developed for PANTER is being studied, optimized, and tested at PANTER. This zone plate will be used for characterising a high quality optics module in a parallel beam to verify the BEaTriX performance. Several of the measurements and selected results are presented here.

Published

2018

10. Analysis of the NGXO telescope x-ray Hartmann data

Author

Peter M. Solly, Kai-Wing Chan, Marlis-Madeleine La Caria, William W. Zhang, Vadim Burwitz, Carlo Pelliciari, Ryan S. McClelland, Timo T. Saha, James R. Mazzarella, and Gisela Hartner

Subjects

Physics, business.industry, Aperture, X-ray optics, Centroid, X-ray telescope, 01 natural sciences, law.invention, 010309 optics, Telescope, Cardinal point, Optics, Beamline, law, 0103 physical sciences, Focus (optics), business, 010303 astronomy & astrophysics

Abstract

Next Generation X-Ray Optics (NGXO) team at the Goddard Space Flight Center (GSFC) has been developing a new silicon-based grazing incidence mirror technology for future high resolution x-ray astronomical missions. Recently, the GSFC team completed the construction of first few mirror modules that contain one pair of mirrors. One of the mirror pairs was tested in GSFC 600-m long beamline facility and Panter (Neuried, Germay) 120-m long x-ray beamline facility. Both full aperture x-ray tests, Hartmann tests, and focal plane sweeps were completed. In this paper we present the data analysis process and compare the results from our models to measured x-ray centroid data, x-ray performance data, and out of focus images of the mirror pair.

Published

2018

11. Realization and drive tests of active thin glass x-ray mirrors

Author

Bianca Salmaso, Marco Barbera, Marta Civitani, Salvatore Varisco, Daniele Spiga, Carlo Pelliciari, Luisa Sciortino, Roberto Candia, Giuseppe Lullo, Stefano Basso, U. Lo Cicero, G. Di Cicca, Alfonso Collura, Spiga, D., Barbera, M., Collura, A., Basso, S., Candia, R., Civitani, M., Di Cicca, G., Lo Cicero, U., Lullo, G., Pelliciari, C., Salmaso, B., Sciortino, L., Varisco, S., and ITA

Subjects

Materials science, business.industry, Antenna aperture, Active optics, X-ray telescope, Piezoelectricity, Settore ING-INF/01 - Elettronica, law.invention, Telescope, Optics, Settore FIS/05 - Astronomia E Astrofisica, law, Angular resolution, Focus (optics), Actuator, business, X-ray mirrors, active optics, thin glass mirrors, piezoelectric actuators

Abstract

A technique to obtain lightweight and high-resolution focusing mirror segments for large aperture X-ray telescopes is the hot slumping of thin glass foils. In this approach, already successfully experimented to manufacture the optics of the NuSTAR X-ray telescope, thin glasses are formed at high temperature onto a precisely figured mould. The formed glass foils are subsequently stacked onto a stiff backplane with a common axis and focus to form an XOU (X-ray Optical Unit), to be later integrated in the telescope optic structure. In this process, the low thickness of the glass foils guarantees a low specific mass and a very low obstruction of the effective area. However, thin glasses are subject to deformations that may arise at any stage of the production process, thereby degrading the angular resolution. To solve this problem, several groups are working on the possibility to correct the mirror profile post-manufacturing, using piezoelectric elements exerting a tangential strain on the non-optical side of the glass mirrors. In this paper we show the results of the approach we have adopted, based on the application of piezoceramic patches on the backside of thin glass foils, previously formed by hot slumping. The voltage signals are supplied to the piezoelectric elements by a system of electrodes deposited on the same side of the mirror via a photolithographic process. Finally, the matrix of voltages to be used to correct the mirror shape can be determined in X-rays illumination by detection of the intra-focal image and consequent reconstruction of the longitudinal profile. We describe the production of some active mirrors with different arrangements of piezoelectric elements and the X-ray tests performed at the XACT X-ray facility to determine the optimal actuator geometry.

Published

2016

12. BEaTriX, expanded X-ray beam facility for testing modular elements of telescope optics: an update

Author

Carlo Pelliciari, Daniele Spiga, C. Ferrari, Giovanni Pareschi, E. Bonnini, Elisa Buffagni, Gianpiero Tagliaferri, and ITA

Subjects

Physics, Aperture, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Vacuum tube, FOS: Physical sciences, BEaTriX, Modular design, beam expander, X-ray test facility, law.invention, ATHENA, Telescope, Optics, asymmetric diffraction, Observatory, law, Beam expander, Angular resolution, business, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Beam (structure)

Abstract

We present in this paper an update on the design of BEaTriX (Beam Expander Testing X-ray facility), an X-ray apparatus to be realized at INAF/OAB and that will generate an expanded, uniform and parallel beam of soft X-rays. BEaTriX will be used to perform the functional tests of X-ray focusing modules of large X-ray optics such as those for the ATHENA X-ray observatory, using the Silicon Pore Optics (SPO) as a baseline technology, and Slumped Glass Optics (SGO) as a possible alternative. Performing the tests in X-rays provides the advantage of an in-situ, at-wavelength quality control of the optical modules produced in series by the industry, performing a selection of the modules with the best angular resolution, and, in the case of SPOs, there is also the interesting possibility to align the parabolic and the hyperbolic stacks directly under X-rays, to minimize the aberrations. However, a parallel beam with divergence below 2 arcsec is necessary in order to measure mirror elements that are expected to reach an angular resolution of about 4 arcsec, since the ATHENA requirement for the entire telescope is 5 arcsec. Such a low divergence over the typical aperture of modular optics would require an X-ray source to be located in a several kilometers long vacuum tube. In contrast, BEaTriX will be compact enough (5 m x 14 m) to be housed in a small laboratory, will produce an expanded X-ray beam 60 mm x 200 mm broad, characterized by a very low divergence (1.5 arcsec HEW), strong polarization, high uniformity, and X-ray energy selectable between 1.5 keV and 4.5 keV. In this work we describe the BEaTriX layout and show a performance simulation for the X-ray energy of 4.5 keV., Preprint version: the fully published paper can be downloaded at http://dx.doi.org/10.1117/12.2188607

Published

2016

13. Slumped glass foils as substrate for adjustable x-ray optics

Author

Carlo Pelliciari, G. Vecchi, Bianca Salmaso, M. Civitani, Giovanni Pareschi, Daniele Spiga, J. Hołyszko, Mauro Ghigo, S. Basso, and ITA

Subjects

Physics, business.industry, X-ray optics, Active optics, X-ray telescope, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, 010309 optics, Optics, Coating, Observatory, 0103 physical sciences, engineering, Angular resolution, 0210 nano-technology, business, Image resolution, Slumping

Abstract

Thin glass modular mirrors are a viable solution to build future X-ray telescopes with high angular resolution and large collecting area. In our laboratories, we shape thin glass foils by hot slumping and we apply pressure to assist the replication of a cylindrical mould figure; this technology is coupled with an integration process able to damp low frequency errors and produces optics in the Wolter I configuration, typical for the X-ray telescopes. From the point of view of the hot slumping process, the efforts were focused in reducing low-, mid- and high- frequency errors of the formed Eagle glass foils. Some of our slumped glass foils were used for the development of active X-ray optics, where piezoelectric actuators are used to correct the slumped glass foil deviations from the ideal shape. In particular, they were used for the Adjustable X-raY optics for astrOnoMy project (AXYOM) developed in Italy, and the X-ray Surveyor mission, as developed at the Smithsonian Astrophysical Observatory / Center for Astrophysics (SAO/CfA) in USA. In this paper we describe the optimisation of the hot slumping process, comparing the results with the requirements of the considered active optics projects. Finally, since the present configuration of the Pennsylvania State University (PSU) coating equipment is limited to 100 x 100 mm2, the slumped glass foils used for the SAO project were cut from 200 x 200 mm2 to 100 x 100 mm2, and a low-frequency change was observed. A characterisation of the profile change upon cutting is presented.

Published

2016

14. Beyond Chandra (towards the X-ray Surveyor mission): possible solutions for the implementation of very high angular resolution X-ray telescopes in the new millennium based on fused silica segments

Author

Mauro Ghigo, Marta Civitani, G. Vecchi, Stefano Basso, Carlo Pelliciari, G. Pareschi, Bianca Salmaso, Giancarlo Parodi, Daniele Spiga, and ITA

Subjects

Figuring, Physics, X-ray astronomy, business.industry, Polishing, X-ray telescope, Redshift, law.invention, Telescope, Optics, law, Angular resolution, business, Image resolution

Abstract

An important challenge for the X-ray astronomy of the new millennium is represented by the implementation of an X-ray telescope able to maintain the exquisite angular resolution of Chandra (with a sub-arcsec HEW, on-axis) but, at the same time, being characterized by a much larger throughput and grasp. A mission with similar characteristics is represented by the X-ray Surveyor Mission. The project has been recently proposed in USA and is being currently studied by NASA. It will host an X-ray telescope with an effective area of more than 2 square meters at 1 keV (i.e. 30 times greater than Chandra) and a 15-arcminutes field-of-view, with 1-arcsecond or better half-power diameter (versus the 4 arcmin diameter of Chandra). While the scientific reasons for implementing a similar mission are clear, being related to compelling problems like e.g. the formation and subsequent growth of black hole seeds at very high redshift or the identification of the first galaxy groups and proto-clusters, the realization of a grazing-angle optics system able to fulfil these specs remain highly challenging. Different technologies are being envisaged, like e.g. the use of adjustable segmented mirrors (with use of piezoelectric or magneto-restrictive film actuators on the back surface) or the direct polishing of a variety of thin substrates or the use of innovative correction methods like e.g. differential deposition, ionfiguring or the correction of the profile via controlled stress films. In this paper we present a possible approach based on the direct polishing (with final ion figuring correction of the profile) of thin SiO2 segmented substrates (typically 2 mm thick), discussing different aspects of the technology under implementation and presenting some preliminary results.

Published

2016

15. Design and advancement status of the Beam Expander Testing X-ray facility (BEaTriX)

Author

Gianpiero Tagliaferri, Mauro Ghigo, G. Vecchi, Carlo Pelliciari, Giovanni Bianucci, Andrea Zappettini, C. Ferrari, Daniele Spiga, Massimiliano Rossi, B. Salmaso, Luigina Arcangeli, Giuseppe Valsecchi, Giovanni Pareschi, and ITA

Subjects

FOS: Physical sciences, 02 engineering and technology, 010403 inorganic & nuclear chemistry, beam expander, 01 natural sciences, X-ray test facility, Optics, Quality (physics), asymmetric diffraction, Observatory, Angular resolution, modular optics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Physics, business.industry, Antenna aperture, X-ray, BEaTriX, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Beam expander, Astrophysics - Instrumentation and Methods for Astrophysics, 0210 nano-technology, business, Focus (optics), Beam (structure)

Abstract

The BEaTriX (Beam Expander Testing X-ray facility) project is an X-ray apparatus under construction at INAF/OAB to generate a broad (200 x 60 mm2), uniform and low-divergent X-ray beam within a small lab (6 x 15 m2). BEaTriX will consist of an X-ray source in the focus a grazing incidence paraboloidal mirror to obtain a parallel beam, followed by a crystal monochromation system and by an asymmetrically-cut diffracting crystal to perform the beam expansion to the desired size. Once completed, BEaTriX will be used to directly perform the quality control of focusing modules of large X-ray optics such as those for the ATHENA X-ray observatory, based on either Silicon Pore Optics (baseline) or Slumped Glass Optics (alternative), and will thereby enable a direct quality control of angular resolution and effective area on a number of mirror modules in a short time, in full X-ray illumination and without being affected by the finite distance of the X-ray source. However, since the individual mirror modules for ATHENA will have an optical quality of 3-4 arcsec HEW or better, BEaTriX is required to produce a broad beam with divergence below 1-2 arcsec, and sufficient flux to quickly characterize the PSF of the module without being significantly affected by statistical uncertainties. Therefore, the optical components of BEaTriX have to be selected and/or manufactured with excellent optical properties in order to guarantee the final performance of the system. In this paper we report the final design of the facility and a detailed performance simulation., Comment: Accepted paper, pre-print version. The finally published manuscript can be downloaded from http://dx.doi.org/10.1117/12.2238952

Published

2016

16. Electrical connections and driving electronics for piezo-actuated x-ray thin glass optics

Author

Alfonso Collura, Carlo Pelliciari, Bianca Salmaso, Marta Civitani, Stefano Basso, Daniele Spiga, Ugo Lo Cicero, Maurizio Salvatore Di Bella, Roberto Candia, Giuseppe Lullo, Luisa Sciortino, Marco Barbera, Lo Cicero, U., Sciortino, L., Lullo, G., Di Bella, M., Barbera, M., Collura, A., Candia, R., Spiga, D., Basso, S., Civitani, M., Pelliciari, C., and Salmaso, B.

Subjects

Materials science, business.industry, X-ray telescope, Modular design, Settore ING-INF/01 - Elettronica, Active X-ray optics, thin glass optics, piezoelectric actuators, piezoelectric multichannel drivers, interconnections patterning, X-ray telescope mirrors, Settore FIS/05 - Astronomia E Astrofisica, Optics, visual_art, visual_art.visual_art_medium, Optoelectronics, Electronics, Ceramic, Thin film, business, Actuator, Electrical conductor, Voltage

Abstract

Use of thin glass modular optics is a technology currently under study to build light, low cost, large area X-ray telescopes for high energy astrophysics space missions. The angular resolution of such telescopes is limited by local deviations from the ideal shape of the mirrors. One possible strategy to improve it consists in actively correcting the mirror profile by gluing thin ceramic piezo-electric actuators on the back of the glasses. A large number of actuators, however, requires several electrical connections to drive them with the different needed voltages. We have developed a process for depositing conductive paths directly on the back of non-planar thin foil mirrors by means of a photolithographic process, combined with metal thin film evaporation and selective removal. We have also designed and built a modular multichannel electronic driver with each module capable of driving simultaneously up to 16 actuators with a very low power consumption. Here we present our electrical interconnections technology and the solutions adopted in the implementation of the electronics.

Published

2016

17. Manufacturing and testing a thin glass mirror shell with piezoelectric active control

Author

Carlo Pelliciari, Salvatore Varisco, U. Lo Cicero, M. Civitani, Marco Riva, Giuseppe Lullo, B. Salmaso, Daniele Spiga, Stefano Basso, G. Di Cicca, Roberto Candia, Alfonso Collura, M. Di Bella, Luisa Sciortino, Marco Barbera, ITA, Spiga, D., Barbera, M., Collura, A., Basso, S., Candia, R., Civitani, M., Di Bella, M., Di Cicca, G., Lo Cicero, U., Lullo, G., Pelliciari, C., Riva, M., Salmaso, B., Sciortino, L., and Varisco, S.

Subjects

Physics - Instrumentation and Detectors, Materials science, active optic, FOS: Physical sciences, Mechanical engineering, piezoelectric actuator, thin glass mirror, Instrumentation and Detectors (physics.ins-det), Settore ING-INF/01 - Elettronica, Piezoelectricity, Signal, law.invention, Printed circuit board, Settore FIS/05 - Astronomia E Astrofisica, law, Focal length, Angular resolution, Photolithography, X-ray mirrors, Astrophysics - Instrumentation and Methods for Astrophysics, Actuator, Instrumentation and Methods for Astrophysics (astro-ph.IM), Voltage

Abstract

Optics for future X-ray telescopes will be characterized by very large aperture and focal length, and will be made of lightweight materials like glass or silicon in order to keep the total mass within acceptable limits. Optical modules based on thin slumped glass foils are being developed at various institutes, aiming at improving the angular resolution to a few arcsec HEW. Thin mirrors are prone to deform, so they require a careful integration to avoid deformations and even correct forming errors. On the other hand, this offers the opportunity to actively correct the residual deformation: a viable possibility to improve the mirror figure is the application of piezoelectric actuators onto the non-optical side of the mirrors, and several groups are already at work on this approach. The concept we are developing consists of actively integrating thin glass foils with piezoelectric patches, fed by voltages driven by the feedback provided by X-rays. The actuators are commercial components, while the tension signals are carried by a printed circuit obtained by photolithography, and the driving electronic is a multi-channel low power consumption voltage supply developed in-house. Finally, the shape detection and the consequent voltage signal to be provided to the piezoelectric array are determined in X-rays, in intra-focal setup at the XACT facility at INAF/OAPA. In this work, we describe the manufacturing steps to obtain a first active mirror prototype and the very first test performed in X-rays., Comment: Preprint version. The fully published paper is found at https://doi.org/10.1117/12.2189990

Published

2015

18. An expanded X-ray beam facility (BEaTriX) to test the modular elements of the ATHENA optics

Author

Daniele Spiga, Carlo Pelliciari, E. Bonnini, C. Ferrari, Giovanni Pareschi, Elisa Buffagni, and Gianpiero Tagliaferri

Subjects

Physics, segmented X-ray optics, Aperture, Parabolic reflector, business.industry, FOS: Physical sciences, X-ray telescope, X-ray tests, Collimated light, ATHENA, Metrology, expanded beam, Optics, Focal length, Beam expander, Angular resolution, business, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), X-ray telescopes

Abstract

Future large X-ray observatories like ATHENA will be equipped with very large optics, obtained by assembling modular optical elements, named X-ray Optical Units (XOU) based on the technology of either Silicon Pore Optics or Slumped Glass Optics. In both cases, the final quality of the modular optic (a 5 arcsec HEW requirement for ATHENA) is determined by the accuracy alignment of the XOUs within the assembly, but also by the angular resolution of the individual XOU. This is affected by the mirror shape accuracy, its surface roughness, and the mutual alignment of the mirrors within the XOU itself. Because of the large number of XOUs to be produced, quality tests need to be routinely done to select the most performing stacked blocks, to be integrated into the final optic. In addition to the usual metrology based on profile and roughness measurements, a direct measurement with a broad, parallel, collimated and uniform X- ray beam would be the most reliable test, without the need of a focal spot reconstruction as usually done in synchrotron light. To this end, we designed the BEaTriX (Beam Expander Testing X-ray facility) to be realized at INAF-OAB, devoted to the functional tests of the XOUs. A grazing incidence parabolic mirror and an asymmetrically cut crystal will produce a parallel X-ray beam broad enough to illuminate the entire aperture of the focusing elements. An X-ray camera at the focal distance from the mirrors will directly record the image. The selection of different crystals will enable to test the XOUs in the 1 - 5 keV range, included in the X-ray energy band of ATHENA (0.2-12 keV). In this paper we discuss a possible BEaTriX facility implementation. We also show a preliminary performance simulation of the optical system.

Published

2015

19. Active shape correction of a thin glass/plastic x-ray mirror

Author

Giuseppe Lullo, M. Civitani, S. Dell'Agostino, Daniele Spiga, Alfonso Collura, Marco Riva, Carlo Pelliciari, Marco Barbera, Stefano Basso, U. Lo Cicero, Luisa Sciortino, B. Salmaso, Spiga, D, Barbera, M, Basso, S, Civitani, M, Collura, A, Dell'Agostino, S, Lo Cicero, U, Lullo, G, Pelliciari, C, Riva, M, Salmaso, B, and Sciortino, L

Subjects

Materials science, FOS: Physical sciences, X-ray telescope, Settore ING-INF/01 - Elettronica, Feedback, law.invention, Telescope, Settore FIS/05 - Astronomia E Astrofisica, Optics, Apertures, law, X-rays, Focal length, Angular resolution, Instrumentation and Methods for Astrophysics (astro-ph.IM), Image resolution, X-ray telescopes, Spatial resolution, business.industry, Glasses, Active optics, Piezoelectricity, Mirrors, Astrophysics - Instrumentation and Methods for Astrophysics, business, Actuator, Actuators, Telescopes

Abstract

Optics for future X-ray telescopes will be characterized by very large aperture and focal length, and will be made of lightweight materials like glass or plastic in order to keep the total mass within acceptable limits. Optics based on thin slumped glass foils are currently in use in the NuSTAR telescope and are being developed at various institutes like INAF/OAB, aiming at improving the angular resolution to a few arcsec HEW. Another possibility would be the use of thin plastic foils, being developed at SAO and the Palermo University. Even if relevant progresses in the achieved angular resolution were recently made, a viable possibility to further improve the mirror figure would be the application of piezoelectric actuators onto the non-optical side of the mirrors. In fact, thin mirrors are prone to deform, so they require a careful integration to avoid deformations and even correct forming errors. This however offers the possibility to actively correct the residual deformation. Even if other groups are already at work on this idea, we are pursuing the concept of active integration of thin glass or plastic foils with piezoelectric patches, fed by voltages driven by the feedback provided by X-rays, in intra-focal setup at the XACT facility at INAF/OAPA. In this work, we show the preliminary simulations and the first steps taken in this project.

Published

2014

20. The glass cold-shaping technology for the mirrors of the Cherenkov Telescope Array

Author

Luca Stringhetti, L. M. Perri, Giovanni Pareschi, Giuseppe Crimi, M. Fiorini, Carlo Pelliciari, G. Rodeghiero, Nicola La Palombara, Giorgio Toso, Giorgia Sironi, Rodolfo Canestrari, Enrico Giro, and Giacomo Bonnoli

Subjects

Bending (metalworking), Rigidity (electromagnetism), Optics, Lightweight mirrors, Observatory, Electronic, Wide field aplanatic telescope, ASTRI, Angular resolution, Optical and Magnetic Materials, Electrical and Electronic Engineering, Segmented optics, Image resolution, Cherenkov radiation, Physics, CTA, business.industry, Applied Mathematics, Astrophysics::Instrumentation and Methods for Astrophysics, Computer Science Applications1707 Computer Vision and Pattern Recognition, Active optics, Condensed Matter Physics, Cherenkov Telescope Array, Imaging Atmospheric Cherenkov Telescope, Gamma-rays, Electronic, Optical and Magnetic Materials, business

Abstract

The next generation of imaging atmospheric Cherenkov telescopes will require the production of thousands of mirror segments; an unprecedented amount of optical surface. To accomplish this, the Italian Istituto Nazionale di AstroFisica (INAF) has recently developed a successful technique. This method, called glass cold-shaping, is mainly intended for the manufacturing of mirrors for optical systems with an angular resolution of a few arcminutes, intended to operate in extreme environments. Its principal mechanical features are very low weight and high rigidity of the resulting segments, and its cost and production time turn out to be very competitive as well. The process is based on the shaping of thin glass foils by means of forced bending at room temperature; a sandwich structure is then assembled for retaining the imposed shape. These mirrors are composted of commercial, off-the-shelf materials. In this contribution we give an overview of the latest results achieved in the manufacturing of the pre-production series of mirrors for the Medium Size and Small Size Telescopes of the Cherenkov Telescope Array observatory.

Published

2014

21. The ASTRI SST-2M prototype for the Cherenkov Telescope Array: Manufacturing of the structure and the mirrors

Author

Giorgio Toso, Giorgia Sironi, Carlo Pelliciari, Paolo Conconi, G. Rodeghiero, Nicola La Palombara, M. Fiorini, Enrico Cascone, L. M. Perri, Giovanni Pareschi, Rodolfo Canestrari, Enrico Giro, Giuseppe Crimi, Giacomo Bonnoli, Gino Tosti, and Luca Stringhetti

Subjects

segmented optics, Astrophysics::High Energy Astrophysical Phenomena, ASTRI, CTA, gamma-rays, Imaging Atmospheric Cherenkov Telescope, lightweight mirrors, wide field aplanatic telescope, Applied Mathematics, Computer Science Applications1707 Computer Vision and Pattern Recognition, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials, Condensed Matter Physics, law.invention, Telescope, Optics, Observatory, law, Electronic, Angular resolution, Optical and Magnetic Materials, Aerospace engineering, Image resolution, Cherenkov radiation, Physics, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Cherenkov Telescope Array, Early results, business, Focus (optics)

Abstract

The Cherenkov Telescope Array (CTA) observatory will represent the next generation of Imaging Atmospheric Cherenkov Telescopes. Using a combination of large-, medium-, and small-scale telescopes (LST, MST, SST, respectively), it will explore the Very High Energy domain from a few tens of GeV up to few hundreds of TeV with unprecedented sensitivity, angular resolution and imaging quality. In this framework, the Italian ASTRI program, led by the Italian National Institute of Astrophysics (INAF), is currently developing a scientific and technological SST prototype named ASTRI SST-2M; a 4-meter class telescope, it will adopt an aplanatic, wide-field, double-reflection optical layout in a Schwarzschild-Couder configuration. In this contribution we give an overview of the technological solutions adopted for the ASTRI SST-2M prototype. In particular we focus on the manufacturing of the telescope structure and mirrors. We will also describe early results from tests.

Published

2014

22. JEM-X: the x-ray monitor on INTEGRAL

Author

Marco Feroci, Josef Polny, A. A. Zdziarski, P. B. Mogensen, V. Collado, I. L. Rasmussen, Jose-Luis Requena, G. Loffredo, Fernando Cerdeira Pérez, Roland Svensson, Herbert W. Schnopper, Osmi Vilhu, J. Peris, K. Omoe, J. M. Rodrigo, Niels J. Westergaard, S. M. Pedersen, A. J. Castro-Tirado, K. Harpo Andersen, Carl Budtz-Jørgensen, C. A. Oxborrow, Veikko J. Kamarainen, Filippo Frontera, Carlo Pelliciari, S. Laursen, Jérôme Chenevez, Rene Engel Kristansen, Allan Hornstrup, V. Carassiti, Alda Rubini, S. Larsson, M. Morawski, Guido Zavattini, P. A. Jensen, E. Morelli, Victor Reglero, T. Andersson, Niels Lund, Enrico Costa, S. Brandt, Juhani Huovelin, G. Juchnikowski, and Alfredo Morbidini

Subjects

Physics::Instrumentation and Detectors, micro strip detector, Astrophysics::High Energy Astrophysical Phenomena, Field of view, X-ray telescope, 01 natural sciences, law.invention, Jem-X, INTEGRAL, X-ray astronimy, Telescope, Optics, law, 0103 physical sciences, Angular resolution, Coded aperture, 010303 astronomy & astrophysics, Image resolution, Physics, 010308 nuclear & particles physics, business.industry, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, business

Abstract

The INTEGRAL X-ray monitor, JEM-X, (together with the two gamma ray instruments, SPI and IBIS) provides simultaneous imaging with arcminute angular resolution in the 3-35 keV band. The good angular resolution and low energy response of JEM-X plays an important role in the detection and identification of gamma ray sources as well as in the analysis and scientific interpretation of the combined X-ray and gamma ray data. JEM-X is a coded aperture X-ray telescope consisting of two identical detectors. Each detector has a sensitive area of 500 cm2, and views the sky through its own coded aperture mask. The coded masks are located 3.4 m above the detector windows. The detector field of view is constrained by X-ray collimators (6.6° FOV, FWHM).

Published

2004

23. Progress in the realization of the beam expander testing x-ray facility (BEaTriX) for testing ATHENA's SPO modules

Author

Michela Uslenghi, G. Tagliaferri, Bianca Salmaso, G. Vecchi, Stefano Basso, Carlo Pelliciari, Vadim Burwitz, Giancarlo Parodi, Andrea Zappettini, G. Pareschi, M. Fiorini, Marcos Bavdaz, M. Sanchez del Rio, Ivo Ferreira, Daniele Spiga, Enrico Giro, Claudio Ferrari, Mauro Ghigo, ITA, FRA, DEU, and NLD

Subjects

Physics, 0303 health sciences, business.industry, 030303 biophysics, micro-focus source, Bragg's law, BEaTriX, 02 engineering and technology, Modular design, beam expander, 7. Clean energy, X-ray test facility, 03 medical and health sciences, 020210 optoelectronics & photonics, Tilt (optics), Optics, asymmetric diffraction, Beamline, Observatory, 0202 electrical engineering, electronic engineering, information engineering, Beam expander, business, Beam (structure), Energy (signal processing)

Abstract

The construction of the BEaTriX (Beam Expander Testing X-ray) facility is ongoing at INAF/Osservatorio astronomico di Brera. The facility will generate a broad (170 x 60 mm(2)), uniform and low-divergent (1.5 arcsec HEW) X-ray beam within a small lab (similar to 9 x 18 m(2)), using an X-ray microfocus source, a paraboloidal mirror, a monochromation system based on a combination of symmetrically cut and asymmetrically-cut crystals in Bragg diffraction configuration. Once completed, BEaTriX can be used to test the Silicon Pore Optics modules of the ATHENA X-ray observatory, as well as other optics, like the ones of the Arcus mission. The facility is designed to operate at 1.49 keV and 4.51 keV, by using two fixed beam lines, equipped with the necessary optical elements. The first beam line to be completed will be at 4.51 keV and will prove the BEaTriX concept. Silicon crystals are used at this energy and four symmetric diffractions, with appropriate tilt of some crystals, will provide the spectral filtering at the required level to return the desired divergence. Owing to the quite short range necessary to obtain a parallel beam with this setup, a low vacuum level (10(-3) mbar) can be used without a significant beam extinction. In addition to a modular vacuum approach, the low vacuum will allow us to reduce the time required to evacuate the tank, thus enabling to demonstrate a test rate that will match the ATHENA SPO production of 3 MM/day. In this paper, we report the design of the facility and the construction progress.