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1. Design and acoustic tests of the ATHENA WFI filter wheel assembly development model towards TRL5

Author

Szymon Polak, Jacek Musiał, Robert Pietrzak, Adam Sikorski, Mateusz Dumin, Adam Dacko, Mirosiław Rataj, Tomasz Barciński, Tadeusz Kamisiński, Adam Pilch, Wojciech Binek, Grzegorz Woźniak, Monika Zuchniak, Agata Różańska, Norbert Meidinger, Marcus Plattner, Jintin Frank, Rafael Strecker, Andreas von Kienlin, Marco Barbera, Fabio D’Anca, Daniele Gulli, Ugo Lo Cicero, Nicola Montinaro, Giancarlo Parodi, Enrico Bozzo, and Stephane Paltani

Subjects
Space and Planetary Science, Control and Systems Engineering, Mechanical Engineering, Astronomy and Astrophysics, Instrumentation, Electronic, Optical and Magnetic Materials
Published
2023

2. BEaTriX, an expanded and parallel X-ray beam to measure the modular X-ray optic of the ATHENA telescope

Author

Bianca Salmaso, Stefano Basso, Daniele Spiga, Mauro Ghigo, Gabriele Vecchi, Giorgia Sironi, Vincenzo Cotroneo, Giovanni Pareschi, Gianpiero Tagliaferri, Davide Sisana, Mauro Fiorini, Michela Uslenghi, Claudio Ferrari, Manuel Sanchez del Rio, Giancarlo Parodi, Vadim Bruwitz, Desiree della Monica Ferreira, Sonny Massahi, Finn Christensen, Marcos Bavdaz, Ivo Ferreira, Max Collon, Giuseppe Vacanti, and Nicolas M. Barriere

Subjects
BEaTriX, ATHENA, X-ray testing, X-ray microfocus source, beam expander, asymmetric diffraction, crystals
Abstract

BEaTriX is a unique facility developed at the INAF-Osservatorio Astronomico Brera (Merate, Italy) to test ATHENA’s X-ray mirror. It can perform the X-ray acceptance tests (PSF and Aeff) of the ATHENA Silicon Pore Optics Mirror Modules (MM) at their production rate (2 MM/day), at 4.51 and 1.49 keV. The X-ray beam approximates the one created by an astronomical source (collimated and large), re-created in a small lab (about 9 m x 18 m) thanks to an innovative design. A microfocus X-ray source produces a divergent beam which is conditioned (collimated, monochromatic, and expanded) by a parabolic mirror and a set of silicon crystals, one of which is asymmetrically cut with respect to the lattice planes. The first beam line, at the energy of 4.51 keV, has already been developed. The large monochromatic beam is collimated to < 3 arcsec, with a flux of 60 photons/s/cm2. Its size (170 mm x 60 mm) is sufficiently large to cover the entrance pupil of the MMs. The PSF and Aeff of the first optically representative MM were successfully measured., Grants: ESA contract # 4000123152/18/NL/BW, AHEAD grant #654215 and #871158, ASI accordo attuativo # 2019-27-HH.0, Internal INAF funds

Published
2022
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4. The expanded, parallel, and monochromatic x-ray beam of BEaTriX: alignment and characterization

Author

Stefano Basso, Bianca Salmaso, 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, Sara Beretta, Andrea Zappettini, Manuel S. del Rio, Giancarlo Parodi, Vadim Burwitz, Surangkhana Rukdee, Gisela Hartner, Thomas Müller, Thomas Schmidt, Andreas Langmeier, Desiree D. M. Ferreira, Sonny Massahi, Nis C. Gellert, Finn E. Christensen, Marcos Bavdaz, and Ivo Ferreira

Published
2022

6. Laurentthomasite, Mg2K(Be2Al)Si12O30: a new milarite-group-type member from the Ihorombe region, Fianarantsoa Province, Madagascar

Author

Giancarlo Parodi, Martin Schreyer, Cristiano Ferraris, Isabella Pignatelli, Sylvain Courrech du Pont, Fengxia Wei, and Fernando Cámara

Subjects
Materials science, 05 social sciences, Electron microprobe, Crystal structure, Crystallography, Octahedron, Formula unit, 0502 economics and business, Mössbauer spectroscopy, 050211 marketing, Mohs scale of mineral hardness, 050203 business & management, Powder diffraction, Diffractometer
Abstract

Laurentthomasite, ideally Mg2 K( Be2 Al) Si12 O30 , is a new milarite-group member found within quartz-syenite pegmatites from the Ihorombe region, Fianarantsoa Province, Madagascar. It occurs as euhedral {0001} hexagonal crystals, maximum 15 mm large and 5 mm thick. The crystals show a very strong dichroism with cobalt blue and green-yellow colours when observed along [0001] and [1000], respectively. The mineral is transparent, uniaxial ( + ) and its lustre is vitreous. The hardness is about 6 (Mohs scale), showing a poor {0001} cleavage, irregular to conchoidal fracture, and a measured density of 2.67(8) g cm −3 . Laurentthomasite is hexagonal, space group P 6/mcc (no. 192), with a=9.95343(6) A, c=14.15583(8) A, V=1214.54(1) A 3 and Z=2 . The strongest nine lines in the X-ray powder diffraction pattern [ d in A – (I) – hkl] are 3.171 – (10) – 211, 4.064 – (8) – 112, 2.732 – (8) – 204, 4.965 – (6) – 110, 2.732 – (4) – 204, 3.533 – (3) – 004, 7.055 – (2) – 002, 4.302 – (2) – 200 and 3.675 – (2) – 202. Chemical analyses by electron microprobe and several spectroscopies (inductively coupled plasma, ICP; optical emission, OES; mass, MS; and Mossbauer) give the following empirical formula based on 30 anions per formula unit: ( Mg0.86 Sc0.54 Fe 0.35 2 + Mn 0.26 ) ∑ = 2.01 ( K0.89 Na0.05 Y0.02 Ca0.01 Ba 0.01 ) ∑ = 0.98 [( Be2.35 Al0.50 Mg0.11 Fe 0.03 3 + ) ∑ = 2.99 ( Si11.90 Al0.10 ) O30 ]; the simplified formula is (Mg, Sc) 2 (K, Na)[(Be, Al, Mg) 3 (Si, Al) 12 O30 ]. The crystal structure was refined to an R index of 1.89 % based on 430 reflections with I o > 2 σ(I) collected on a four-circle diffractometer with Cu Kα radiation. By comparison with the general formula of the milarite group, A2B2C [ T (2) 3T (1) 12 O30 ]( H2O ) x ( 0 x n , with n pfu, per formula unit), the laurentthomasite structure consists of a beryllo-alumino-silicate framework in which the T (1) site is occupied by Si and minor Al and forms [ Si12 O30 ] cages linked by the T (2) site mainly occupied by (Be + Al). The A and C sites occur in the interstices of the framework while the B site is vacant. The origin of the strong dichroism is related to a charge transfer process between Fe2+ and Fe3+ in octahedral A sites and tetrahedral T (2) sites, respectively.

Published
2020

7. 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

12. Aluminum-based segmented mirrors for gamma-ray Cherenkov Telescopes via replication: status and perspectives

Author

Giuseppe Valsecchi, Giorgia Sironi, Giancarlo Parodi, Primo Attina, Robert Banham, Daniele Spiga, Vincenzo Cotroneo, Giovanni Pareschi, Luigi Lessio, Matteo Redaelli, and Rachele Millul

Subjects
Figuring, Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Replica, Astrophysics::Instrumentation and Methods for Astrophysics, Polishing, Diamond turning, Cherenkov Telescope Array, Optics, Observatory, MAGIC (telescope), business, Cherenkov radiation
Abstract

Current generation Imaging Atmospheric Cherenkov Telescopes (IACTs) like HESS, MAGIC and VERITAS, operated in array-mode, have opened a new astronomical window in high energy gamma-ray band from a few tens GeV to a hundred TeV, allowing to observe the most energetic phenomena on going in our Universe. New generation arrays like ASTRI, with its 9 small-class telescopes operated at Tenerife, Canary Islands, and the very ambitious Cherenkov Telescope Array Observatory (CTAO - with its two sites at the northern and southern hemispheres and about 70 telescopes of different classes) will need to fabricate a few thousand square meters of reflective segments of about 1 m2 area and different shapes for making the primary mirrors. Different low-cost technologies have been used so far, like the direct figuring and polishing of glass slabs, the diamond turning of pre-formed aluminum sandwiched panels and the replica of thin glass foils for making composite sandwiched mirrors. In this paper we will present a further alternative solution, based on the replica of aluminum foils - precoated with a high reflectivity and durability multilayer film - for making sandwiched mirrors. This approach will simplify a lot the production chain, allowing us to make low-cost panels entirely made of aluminum. The method of production of the aluminum replicated panels is discussed and the preliminary performance results obtained with a prototype mirror presented.

Published
2021

18. The VERT-X calibration facility: development of the most critical parts

Author

G. Parissenti, Marta Civitani, Marcos Bavdaz, Daniele Spiga, Michela Uslenghi, F. Amisano, Fabio Zocchi, M. Tordi, Stefano Basso, S. Delorenzi, Giuseppe Valsecchi, Alberto Moretti, Fabio Marioni, Mauro Ghigo, Dervis Vernani, P. Corradi, M. Ottolini, N. La Palombara, G. Tagliaferri, G. Pareschi, Vincenzo Cotroneo, Giorgia Sironi, Giancarlo Parodi, and Ivo Ferreira

Subjects
business.industry, Computer science, X-ray optics, Field of view, Collimator, law.invention, Telescope, law, Calibration, Focal length, Aerospace engineering, Raster scan, business, Focus (optics)
Abstract

The ATHENA X-ray telescope will be the largest X-ray optics ever built. The ground calibration of this mirror assembly raises significant difficulties due to its unprecedented size, mass and focal length. The VERT-X project aims at developing an innovative calibration system which will be able to accomplish to this extremely challenging task.The design is based on an X-ray parallel beam produced by an X-ray source positioned in the focus of a highly performing X-ray collimator; the beam will be accurately moved by a raster-scan mechanism covering all the ATHENA optics at different off-axis angles. The main driving factor in the VERT-X design is the ATHENA calibration requirement on the accuracy in the HEW measure which is 0.1”, all over the field of view. The VERT-X project, started in January 2019, is financed by ESA and conducted by a consortium that includes INAF together with EIE, Media Lario, BCV Progetti and GPAP.

Published
2021

19. Progress on high-resolution thin full monolithic shells made of glass for Lynx

Author

Mauro Ghigo, Daniele Spiga, Marta Civitani, G. Vecchi, Giorgio Toso, Stefano Basso, Giancarlo Parodi, Luigi Lessio, Giovanni Pareschi, Edoardo Maria Alberto Redaelli, and S. Incorvaia

Subjects
Computer science, Observatory, Process (computing), Shell (structure), Mechanical engineering, High resolution, Technology development, Throughput (business), Realization (systems), Mass budget
Abstract

The Lynx X-ray Observatory, with superb imaging capabilities and with large throughput, is one of the four large strategic missions considered in the Astro2020 decadal survey. The realization of the mirror assembly within the desired tolerances is quite challenging and different mirror module concepts are proposed. The simplest mirror module design corresponds to less than a few hundred monolithic shells made of fused silica. The complete optomechanical design, compliant with the mass budget, foresees that the shell thickness ranges between 2 and 4 mm (for mirror shells between 0.4 and 3 m diameter). A technology development roadmap for this approach is funded in Italy by ASI and pursued out by INAF-OAB. In this paper, we present the advancements obtained in the procurement of new raw glass shells, in the development of the different phases of the process, and in the realization of a new single-reflection shell, representative of the final optical configuration suitable to validate the

Published
2021

24. Development of a new normal-incidence cold-shaped mirror technology

Author

Oberto Citterio, Giorgia Sironi, Giancarlo Parodi, Robert Banham, Giuseppe Valsecchi, and Giovanni Pareschi

Subjects
Figuring, Mandrel, Machining, Computer science, Process capability, Polishing, Mechanical engineering, Active optics, Blank, Grinding
Abstract

The conventional state-of-the-art manufacturing processes of aspheric reflective optics normally consists of the following steps: • Production of the glass blank; • Machining and grinding of the blank to approximate shape, inclusive of backside lightening; • Deterministic figuring and polishing. Deterministic figuring and polishing are iterative processes performed by IRP (Intelligent Robot Polishing) or MRF (Magneto-Rheological Figuring) or IBF (Ion-Beam Figuring), which iteratively converge to the targeted performance with guidance from accurate metrology information. The process capability of these one-off methods is well established, but hardly cost-effective for any small/large series production because of the need to repeat the entire process for each product unit. Differently from the conventional methods, the Cold Shaping Optics manufacturing technology consists of precisely shaping an inexpensive thin glass sheet (g 1 mm) over a high precision mandrel and freezing its shape over a low-cost substrate by means of an epoxy adhesive layer. The mandrel must have the same surface shape accuracy specified for the desired optics. However, in a mini production series, the Cold Shaping Optics technique can reduce the recurrent production costs by amortizing the cost of the re-usable shaping mandrel over multiple product units allowing the manufacture of high-performance reflective optics at a fraction of the cost of traditional grinding and polishing methods. In addition to that, the possibility of actively changing the shape of the mandrel allows the series production of optics with different shapes from the same mandrel, hence further reducing the cost paradigm. In this paper we report the results obtained during the development of first prototype mirrors of 380 mm diameter.

Published
2019

25. ATHENA Telescope: alignment and integration of SPO mirror modules

Author

Giancarlo Parodi, Daniele Gallieni, C. Pelliciari, M. Ottolini, Gisela Hartner, Fabio Marioni, Vadim Burwitz, Eric Wille, G. Pareschi, Marcos Bavdaz, Giuseppe Valsecchi, Daniele Spiga, M. Collon, Giovanni Bianucci, and Fabio Zocchi

Subjects
Point spread function, Cosmic Vision, Computer science, business.industry, Process (computing), Centroid, X-ray telescope, Collimated light, law.invention, Telescope, Optics, law, Focal length, business
Abstract

ATHENA (Advanced Telescope for High-ENergy Astrophysics) is the next high-energy astrophysical mission of the European Space Agency currently planned to be launched in the early 2030s, as part of its Cosmic Vision program, on the scientific topic of “Hot and Energetic Universe”. The optics technology is based on the Silicon Pore Optics (SPO). About 678 SPO mirror modules will have to be integrated and co-aligned onto the optical bench of the Mirror Assembly Module (MAM) of ATHENA. This activity will have to be completed in about two years. Media Lario leads an industrial and scientific team that has developed the process to align and integrate the SPO Mirror module with an accuracy better than 1 arcsec. The process is based on position of the centroid of the point spread function produced by each mirror module when illuminated by a collimated planewave at 218 nm taken at 12 m focal length. Experimental tests, using two SPO mirror modules, and correlation with X-ray measurement at the PANTER test facility in Munich have demonstrated that this process meets the accuracy requirement. It was also demonstrated, that a mirror module can be removed again from the MAM, and re-installed, without compromising the adjacent mirror modules. This technique allows arbitrary integration sequence and integration of two Mirror Modules per day. Moreover, it enables monitoring the telescope point spread function during the whole integration phase.

Published
2019

26. 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

27. Lynx optics based on full monolithic shells: design and development

Author

G. Vecchi, Marta Civitani, Mauro Ghigo, K. Kiranmayee, R. Elsner, Stefano Basso, J. Davis, J. Hołyszko, G. Pareschi, Giorgio Toso, Giancarlo Parodi, D. Swartz, ITA, and USA

Subjects
Figuring, Fabrication, Materials science, Antenna aperture, Shell (structure), Mechanical engineering, Polishing, 01 natural sciences, law.invention, Stiffening, 010309 optics, Telescope, law, 0103 physical sciences, 010303 astronomy & astrophysics, Throughput (business)
Abstract

Lynx is an X-ray mission concept with superb imaging capabilities (< 1arcsec Half Energy Width, HEW) and large throughput (2 m2 effective area @1keV). Several approaches are being considered to meet the challenging technological task of the mirror fabrication. Thin and light substrates are necessary to meet mass constraints. Monolithic fused silica shells are a possible solution if their thickness can be maintained to below 4 mm for mirror shells up to 3 m diameter. In this paper we present the opto-mechanical design of the mirror assembly, the technological processes, and the results achieved so far on a prototypal shells under development. In particular, emphasis is placed on the figuring process that is based on direct polishing and on ion beam figuring and on a temporary stiffening structure designed to support the shell during the figuring and polishing operations and to manage the handling of the shell through all phases up to integration into the telescope supporting structure.

Published
2018

28. Structural modelling and mechanical tests supporting the design of the ATHENA X-IFU thermal filters and WFI optical blocking filter

Author

Ugo Lo Cicero, Johannes Hartwig, Giancarlo Parodi, Alfonso Collura, Norbert Meidinger, Salvatore Ferruggia Bonura, Adam Pilch, Antonino Buttacavoli, Luisa Sciortino, Szymon Polak, Kurt Dittrich, Valérie Samain, Marco Barbera, Miroslaw Rataj, Fabio D'Anca, Parodi, Giancarlo, D'Anca, Fabio, Lo Cicero, Ugo, Sciortino, Luisa, Rataj, Miroslaw, Polak, Szymon, Pilch, Adam, Meidinger, Norbert, Dittrich, Kurt, Hartwig, Johanne, Samain, Valérie, Collura, Alfonso, Ferruggia Bonura, Salvatore, Buttacavoli, Antonino, and Barbera, Marco

Subjects
Cosmic Vision, Computer science, Condensed Matter Physic, Blocking (statistics), 01 natural sciences, Settore FIS/05 - Astronomia E Astrofisica, WFI, 0103 physical sciences, Sensitivity (control systems), Aerospace engineering, Electrical and Electronic Engineering, 010306 general physics, FEA, X-IFU, 010308 nuclear & particles physics, business.industry, Filter, Electronic, Optical and Magnetic Material, Detector, Computer Science Applications1707 Computer Vision and Pattern Recognition, Transparency (human–computer interaction), ATHENA, Vibration, Applied Mathematic, Cardinal point, Filter (video), X-Ray, business
Abstract

Copyright 2018 Society of Photo-Optical Instrumentation Engineers (SPIE). One print or electronic copy may be made for personal use only. Systematic reproduction and distribution, duplication of any material in this paper for a fee or for commercial purposes, or modification of the content of the paper are prohibited. ATHENA is a Large high energy astrophysics space mission selected by ESA in the Cosmic Vision 2015-2025 Science Program. It will be equipped with two interchangeable focal plane detectors: the X-Ray Integral Field Unit (X-IFU) and the Wide Field Imager (WFI). Both detectors require x-ray transparent filters to fully exploit their sensitivity. In order to maximize the X-ray transparency, filters must be very thin, from a few tens to few hundreds of nm, on the other hand, they must be strong enough to survive the severe launch stresses. In particular, the WFI OBF, being launched in atmospheric pressure, shall also survive acoustic loads. In this paper, we present a review of the structural modeling performed to assist the ATHENA filters design, the preliminary results from vibration and acoustic tests, and we discuss future activities necessary to consolidate the filters design, before the preliminary requirement review of the ATHENA instruments, scheduled before the end of 2018.

Published
2018

29. ATHENA X-IFU thermal filters development status toward the end of the instrument phase-A

Author

Luisa Sciortino, Jan-Willem den Herder, Marco Barbera, Giuseppe Lo Cicero, F. Cuttaia, Gaspare Di Cicca, Salvatore Ferruggia Bonura, Roberto Candia, Salvatore Sciortino, Salvatore Varisco, Philippe Peille, Luigi Piro, Antonino Buttacavoli, Gregor Rauw, Giancarlo Parodi, Fabio D'Anca, Massimo Cappi, Roland H. den Hartog, Fabrizio Villa, Ugo Lo Cicero, Alfonso Collura, Graziella Branduardi-Raymont, Thien Lam Trong, Brian Jackson, Paolo Giglio, Jean-Michel Mesnager, Didier Barret, Barbera, Marco, Lo Cicero, Ugo, Sciortino, Luisa, D'Anca, Fabio, Lo Cicero, Giuseppe, Parodi, Giancarlo, Sciortino, Salvatore, Rauw, Gregor, Branduardi-Raymont, Graziella, Varisco, Salvatore, Ferruggia Bonura, Salvatore, Collura, Alfonso, Candia, Roberto, Di Cicca, Gaspare, Giglio, Paolo, Buttacavoli, Antonino, Cuttaia, Francesco, Villa, Fabrizio, Cappi, Massimo, Lam Trong, Thien, Mesnager, Jean-Michel, Peille, Philippe, den Hartog, Roland, den Herder, Jan Willem, Jackson, Brian, Barret, Didier, and Piro, Luigi

Subjects
X-ray detector, Cryostat, Cosmic Vision, Photon, Computer science, Shields, Condensed Matter Physic, microcalorimeter, 01 natural sciences, 7. Clean energy, Settore FIS/05 - Astronomia E Astrofisica, X-ray Integral Field Unit (X-IFU), 0103 physical sciences, thermal thin-film filter, Electrical and Electronic Engineering, Aerospace engineering, 010306 general physics, 010303 astronomy & astrophysics, business.industry, Electronic, Optical and Magnetic Material, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Shot noise, Computer Science Applications1707 Computer Vision and Pattern Recognition, Transition Edge Sensor, Applied Mathematic, ATHENA X-ray observatory, Radio frequency, Transition edge sensor, business
Abstract

Copyright 2018 Society of Photo-Optical Instrumentation Engineers (SPIE). One print or electronic copy may be made for personal use only. Systematic reproduction and distribution, duplication of any material in this paper for a fee or for commercial purposes, or modification of the content of the paper are prohibited. The X-ray Integral Field Unit (X-IFU) is one of the two instruments of the Athena astrophysics space mission approved by ESA in the Cosmic Vision 2015-2025 Science Programme. The X-IFU consists of a large array of transition edge sensor micro-calorimeters that will operate at 100 mK inside a sophisticated cryostat. A set of thin filters, highly transparent to X-rays, will be mounted on the opening windows of the cryostat thermal shields in order to attenuate the IR radiative load, to attenuate radio frequency electromagnetic interferences, and to protect the detector from contamination. Thermal filters are critical items in the proper operation of the X-IFU detector in space. They need to be strong enough to survive the launch stresses but very thin to be highly transparent to X-rays. They essentially define the detector quantum efficiency at low energies and are fundamental to make the photon shot noise a negligible contribution to the energy resolution budget. In this paper, we review the main results of modeling and characterization tests of the thermal filters performed during the phase A study to identify the suitable materials, optimize the design, and demonstrate that the chosen technology can reach the proper readiness before mission adoption.

Published
2018

30. A Virtual Laboratory for Remote Electronic Engineering Education

Author

Andrea Sappia, Giancarlo Parodi, Andrea Bagnasco, Marco Chirico, and Anna Marina Scapolla

Subjects
Open education, Industrial equipment, Software, Multimedia, Computer science, business.industry, Control (management), Virtual Laboratory, Electronic engineering education, computer.software_genre, business, Interactive learning environment, computer
Abstract

New open education and training systems can offer a possible solution to the increasing demand for new models of learning. In this chapter, an interactive learning environment for practice in electronic measurement methodologies is presented, providing remote access to real and simulated laboratories. The software model used to implement the environment can be also applied to industrial equipment for remote monitoring end control of devices and remote training of personnel.

Published
2018

31. Preliminary Mechanical Characterization of Thermal Filters for the X-IFU Instrument on Athena

Author

Antonio Jimenez Escobar, Flavio Nuzzo, Salvatore Ferruggia Bonura, Valérie Samain, Paolo Giglio, Ugo Lo Cicero, Marco Barbera, Angela Ciaravella, Alfonso Collura, Fabio D'Anca, Giancarlo Parodi, Luisa Sciortino, Salvatore Varisco, Barbera, Marco, Lo Cicero, Ugo, Sciortino, Luisa, Parodi, Giancarlo, D'Anca, Fabio, Giglio, Paolo, Ferruggia Bonura, Salvatore, Nuzzo, Flavio, Jimenez Escobar, Antonio, Ciaravella, Angela, Collura, Alfonso, Varisco, Salvatore, and Samain, Valerie

Subjects
Physics, Cryostat, X-IFU, Cosmic Vision, Atomic and Molecular Physics, and Optic, business.industry, Detector, Shields, X-ray microcalorimeter, Thermal filter, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, Characterization (materials science), Optics, Filter (video), 0103 physical sciences, Thermal, Radiative transfer, General Materials Science, Athena, Materials Science (all), 010306 general physics, business, 010303 astronomy & astrophysics
Abstract

The X-ray Integral Field Unit (X-IFU) is one of the two instruments of the Athena astrophysics space mission approved by ESA in the Cosmic Vision Science Program. The X-IFU consists of a large array of TES microcalorimeters that will operate at ~ 50 mK inside a sophisticated cryostat. A set of thin filters, highly transparent to X-rays, will be mounted on the cryostat thermal shields in order to attenuate the IR radiative load, to attenuate RF electromagnetic interferences, and to protect the detector from contamination. In this paper, we present the current thermal filters design, describe the filter samples developed/procured so far, and present preliminary results from the ongoing characterization tests.

Published
2018

32. ATHENA WFI optical blocking filters development status toward the end of the instrument phase-A

Author

Ugo Lo Cicero, Adam Pilch, Szymon Polak, Marco Barbera, Norbert Meidinger, Gregor Rauw, Emanuele Perinati, Teresa Mineo, Paolo Giglio, Miroslaw Rataj, Fabio D'Anca, Salvatore Sciortino, Graziella Branduardi Raymont, Giancarlo Parodi, Luisa Sciortino, Salvatore Varisco, Roberto Candia, Alfonso Collura, Barbera, Marco, Lo Cicero, Ugo, Sciortino, Luisa, D'Anca, Fabio, Parodi, Giancarlo, Rataj, Miroslaw, Polak, Szymon, Pilch, Adam, Meidinger, Norbert, Sciortino, Salvatore, Rauw, Gregor, Branduardi Raymont, Graziella, Mineo, Teresa, Perinati, Emanuele, Giglio, Paolo, Collura, Alfonso, Varisco, Salvatore, and Candia, Roberto

Subjects
X-ray detector, Cosmic Vision, Photon, Wide Field Imager, Field of view, Condensed Matter Physic, 7. Clean energy, 01 natural sciences, 010309 optics, X-ray astronomy, Optics, Settore FIS/05 - Astronomia E Astrofisica, 0103 physical sciences, Athena, Spectral resolution, Electrical and Electronic Engineering, Optical blocking filter, 010303 astronomy & astrophysics, Physics, CMOS sensor, business.industry, Electronic, Optical and Magnetic Material, Detector, Computer Science Applications1707 Computer Vision and Pattern Recognition, Photon counting, Applied Mathematic, Active pixel sensor, 13. Climate action, business, DEPFET
Abstract

Copyright 2018 Society of Photo-Optical Instrumentation Engineers (SPIE). One print or electronic copy may be made for personal use only. Systematic reproduction and distribution, duplication of any material in this paper for a fee or for commercial purposes, or modification of the content of the paper are prohibited. The Wide Field Imager (WFI) is one of the two instruments of the ATHENA astrophysics space mission approved by ESA as the second large mission in the Cosmic Vision 2015-2025 Science Programme. The WFI, based on a large array of depleted field effect transistors (DEPFET), will provide imaging in the 0.2-15 keV band over a 40'x40' field of view, simultaneously with spectrally and time resolved photon counting. The WFI detector is also sensitive to UV/Vis photons, with an electron-hole pair production efficiency in the UV/VIS larger than that for X-ray photons. Optically generated photo-electrons may degrade the spectral resolution as well as change the energy scale by introducing a signal offset. For this reason, the use of X-ray transparent optical blocking filters (OBFs) are needed to allow the observation of X-ray sources that present a UV/Vis bright counterpart. The OBFs design is challenging since one of the two required filters is quite large ( 160 mm × 160 mm), very thin (< 200 nm), and shall survive the mechanical load during the launch. In this paper, we review the main results of modeling and characterization tests of OBF partially representative samples, performed during the phase A study, to identify the suitable materials, optimize the design, prove that the filters can be launched in atmospheric pressure, and thus demonstrate that the chosen technology can reach the proper technical readiness before mission adoption.

Published
2018

33. Results of silicon pore optics mirror modules optical integration in the ATHENA telescope

Author

G. Pareschi, Daniele Gallieni, Giuseppe Valsecchi, M. Ottolini, Giovanni Bianucci, Marcos Bavdaz, D. Spiga, Vadim Burwitz, Fabio Marioni, Fabio Zocchi, Giancarlo Parodi, Eric Wille, M. Collon, ITA, DEU, and NLD

Subjects
Physics, Point spread function, Integration testing, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Centroid, X-ray optics, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Collimated light, law.invention, 010309 optics, Telescope, Cardinal point, Optics, law, 0103 physical sciences, Focal length, 0210 nano-technology, business
Abstract

ATHENA (Advanced Telescope for High-ENergy Astrophysics) is the next high-energy astrophysical mission of the European Space Agency. Media Lario leads an industrial and scientific team that has developed a process to align and integrate more than 700 silicon pore optics mirror modules into the ATHENA X-ray telescope. The process is based on the ultra-violet imaging at 218 nm of each mirror module on the focal plane of a 12 m focal length optical bench. Specifically, the position of the centroid of the point spread function produced by each mirror module when illuminated by a collimated plane is used to align each mirror module. Experimental integration tests and correlation with X-ray measurement at the PANTER test facility in Munich have demonstrated that this process meets the accuracy requirement. This technique allows arbitrary integration sequence and mirror module exchangeability. Moreover, it enables monitoring the telescope point spread function during the integration phase.

Published
2018
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34. Design and development of the multilayer optics for the new hard x-ray mission

Author

A. Orlandi, G. Tagliaferri, Marta Civitani, Giorgia Sironi, Giancarlo Parodi, Francesco Martelli, Daniele Spiga, Barbara Negri, Dervis Vernani, Primo Attinà, R. Binda, Paul Gorenstein, Vincenzo Cotroneo, Stefano Basso, Giuseppe Valsecchi, G. Borghi, G. Pareschi, Oberto Citterio, Lorenzo Raimondi, and Suzanne Romaine

Subjects
Physics, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, X-ray optics, Context (language use), Polarimeter, law.invention, Telescope, Optics, Cardinal point, law, Focal length, Angular resolution, business
Abstract

The New Hard X-ray Mission (NHXM) project will be operated by 2017 and is currently undergoing a Phase B study, under the coordination of the Italian Space Agency (ASI). The project is being proposed by an international team in the context of the ESA Call CV M3 as a Small Mission program, with a large Italian participation. It is based on 4 hard X-ray optics modules, each formed by 60 evenly spaced multilayer coated Wolter I mirror shells. An extensible bench is used to reach the 10 m focal length. The Wolter I monolithic substrates with multilayer coating are produced in NiCo by electroforming replication. Three of the mirror modules will host in the focal plane a hybrid a detector system (a soft X-ray Si DEPFET array plus a high energy CdTe detector). The detector of the fourth telescope will be a photoelectric polarimeter with imaging capabilities, operating from 2 up to 35 keV. The total on axis effective area of the three telescopes at 1 keV and 30 kev is of 1500 cm2 and 350 cm2 respectively, with an angular resolution of 20 arcsec HEW at 30 keV. In this paper we report on the design and development of the multilayer coated X-ray mirrors based on NiCo shells.

Published
2017

35. A hybrid concept (segmented plus monolithic fused silica shells) for a high-throughput and high-angular resolution x-ray mission (Lynx/X-Ray Surveyor like)

Author

Marta Civitani, Giancarlo Parodi, Stefano Basso, and Giovanni Pareschi

Subjects
Engineering, Vignetting, business.industry, Antenna aperture, Polishing, Field of view, X-ray telescope, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, 010309 optics, Telescope, Optics, Interfacing, law, 0103 physical sciences, Angular resolution, 0210 nano-technology, business
Abstract

Lynx is a large area and high angular resolution X-ray mission being studied by NASA to be presented to the next Decadal Survey for the implementation in the next decade. It aims to realize an X-ray telescope with the effective area similar to Athena (2 m2 at 1 keV) but with the same angular resolution of Chandra and a much larger Field Of View (up 20 arcmin x 20 arcmin). The science of X-ray Surveyor requires a large-throughput mirror assembly with sub-arcsec angular resolution. These future X-ray mirrors have a set of requirements which, collectively, represents very substantial advances over any currently in operation or planned for missions other than X-ray Surveyor. Of particular importance is achieving low mass per unit collecting area, while maintaining Chandra like angular resolution. Among the possible solutions under study, the direct polishing of both thin monolithic pseudo-cylindrical shells and segments made of fused silica are being considered as viable solutions for the implementation of the mirrors. Fused silica has very good thermomechanical parameters (including a very low CTE), making the material particularly well suited for for the production of the Lynx mirrors. It should be noted that the use of close shells is also very attractive, since the operations for the integration of the shells will be greatly simplified and the area lost due to the vignetting from the interfacing structures minimized even if the management of such big (diameter of 3 m) and thin shells have to be demonstrated. In this paper we will discuss a possible basic layout for a full shell mirror and a hybrid concept (segmented plus monolithic shells made of fused silica) as a second solution, for the Lynx/XRS telescope, discussing preliminary results in terms of optical and mechanical performance.

Published
2017

36. Optical integration of SPO mirror modules in the ATHENA telescope

Author

M. Collon, Giuseppe Valsecchi, Eric Wille, Marcos Bavdaz, Giovanni Bianucci, Daniele Spiga, Marta Civitani, M. Ottolini, Fabio Marioni, Daniele Gallieni, Giancarlo Parodi, G. Pareschi, and Fabio Zocchi

Subjects
Physics, Point spread function, business.industry, Process (computing), Phase (waves), Astrophysics::Instrumentation and Methods for Astrophysics, X-ray optics, X-ray telescope, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, 010309 optics, Telescope, Optics, Cardinal point, law, 0103 physical sciences, Angular resolution, 0210 nano-technology, business
Abstract

ATHENA (Advanced Telescope for High-ENergy Astrophysics) is the next high-energy astrophysical mission selected by the European Space Agency for launch in 2028. The X-ray telescope consists of 1062 silicon pore optics mirror modules with a target angular resolution of 5 arcsec. Each module must be integrated on a 3 m structure with an accuracy of 1.5 arcsec for alignment and assembly. This industrial and scientific team is developing the alignment and integration process of the SPO mirror modules based on ultra-violet imaging at the 12 m focal plane. This technique promises to meet the accuracy requirement while, at the same time, allowing arbitrary integration sequence and mirror module exchangeability. Moreover, it enables monitoring the telescope point spread function during the planned 3-year integration phase.

Published
2017

38. 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

39. The filter and calibration wheel for the ATHENA wide field imager

Author

Marco Barbera, M. Rataj, Tadeusz Kamisiński, T. Palgan, Szymon Polak, Giancarlo Parodi, Norbert Meidinger, Fabio D'Anca, Adam Pilch, Josef Eder, Markus Plattner, Rataj, M., Polak, S., Palgan, T., Kamisiński, T., Pilch, A., Eder, J., Meidinger, N., Plattner, M., Barbera, M., Parodi, G., and D'Anca, F.

Subjects
010302 applied physics, Computer science, Detector, Filter wheel mechanism, FEM structural and acoustic analysis, ATHENA, WFI, Volume (computing), Blocking (statistics), 01 natural sciences, Square (algebra), Settore FIS/05 - Astronomia E Astrofisica, Position (vector), Filter (video), 0103 physical sciences, Electronic engineering, Calibration, 010303 astronomy & astrophysics, Simulation
Abstract

The planned filter and calibration wheel for the Wide Field Imager (WFI) instrument on Athena is presented. With four selectable positions it provides the necessary functions, in particular an UV/VIS blocking filter for the WFI detectors and a calibration source. Challenges for the filter wheel design are the large volume and mass of the subsystem, the implementation of a robust mechanism and the protection of the ultra-thin filter with an area of 160 mm square. This paper describes performed trade-offs based on simulation results and describes the baseline design in detail. Reliable solutions are envisaged for the conceptual design of the filter and calibration wheel. Four different variant with different position of the filter are presented. Risk mitigation and the compliance to design requirements are demonstrated.

Published
2016

40. Thermal Filters for the ATHENA X-IFU: Ongoing Activities Toward the Conceptual Design

Author

Salvatore Sciortino, Giancarlo Parodi, E. Bozzo, A. Argan, A. Jimenez Escobar, Flavio Nuzzo, Grégor Rauw, Claudio Macculi, S. Paltani, Luigi Piro, Marco Barbera, F. Cuttaia, Flavio Gatti, Luisa Sciortino, Angela Ciaravella, U. Lo Cicero, Fabrizio Villa, Alfonso Collura, Teresa Mineo, Simone Lotti, Graziella Branduardi-Raymont, Barbera, M., Argan, A., Bozzo, E., Branduardi Raymont, G., Ciaravella, A., Collura, A., Cuttaia, F., Gatti, F., Jimenez Escobar, A., Lo Cicero, U., Lotti, S., Macculi, C., Mineo, T., Nuzzo, F., Paltani, S., Parodi, G., Piro, L., Rauw, G., Sciortino, L., Sciortino, S., and Villa, F.

Subjects
Cryostat, X-ray Astronomy, Atomic and Molecular Physics, and Optic, ATHENA, Thermal Filters, X-IFU, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Materials Science (all), Shields, Condensed Matter Physic, 01 natural sciences, Thermal Filter, law.invention, 010309 optics, Telescope, Optics, Settore FIS/05 - Astronomia E Astrofisica, Conceptual design, law, Atomic and Molecular Physics, 0103 physical sciences, General Materials Science, Electronics, 010303 astronomy & astrophysics, Physics, X-ray astronomy, business.industry, Detector, Cardinal point, and Optics, business
Abstract

ATHENA is the L2 mission selected by ESA to pursue the science theme “Hot and Energetic Universe.” One of the two focal plane instruments is the X-ray Integral Field Unit, an array of TES microcalorimeters operated at T $$

Published
2016

41. The optical blocking filter for the ATHENA wide field imager: Ongoing activities towards the conceptual design

Author

Luisa Sciortino, Andrea Comastri, P. Wawer, U. Lo Cicero, Marco Barbera, Adam Pilch, Teresa Mineo, Salvatore Sciortino, S. Molendi, Giancarlo Parodi, Graziella Branduardi-Raymont, Gregor Rauw, Luigi Piro, Norbert Meidinger, Tadeusz Kamisiński, Josef Eder, M. Rataj, Alfonso Collura, Barbera, M., Branduardi Raymont, G., Collura, A., Comastri, A., Eder, J., Kamisiński, T., Lo Cicero, U., Meidinger, N., Mineo, T., Molendi, S., Parodi, G., Pilch, A., Piro, L., Rataj, M., Rauw, G., Sciortino, L., Sciortino, S., Wawer, P., ITA, GBR, DEU, BEL, and POL

Subjects
Physics, filter, Offset (computer science), Photon, Pixel, business.industry, Electronic, Optical and Magnetic Material, Applied Mathematics, Astrophysics::Instrumentation and Methods for Astrophysics, Computer Science Applications1707 Computer Vision and Pattern Recognition, Condensed Matter Physic, Photon counting, ATHENA, Vibration, Instrumentation for Astrophysic, X-ray, Optics, Conceptual design, WFI, Field-effect transistor, Spectral resolution, Electrical and Electronic Engineering, business
Abstract

ATHENA is the L2 mission selected by ESA to pursue the science theme "Hot and Energetic Universe" (launch scheduled in 2028). One of the key instruments of ATHENA is the Wide Field Imager (WFI) which will provide imaging in the 0.1-15 keV band over a 40'x40' large field of view, together with spectrally and time-resolved photon counting. The WFI camera, based on arrays of DEPFET active pixel sensors, is also sensitive to UV/Vis photons. Optically generated electron-hole pairs may degrade the spectral resolution as well as change the energy scale by introducing a signal offset. For this reason, the use of an X-ray transparent optical blocking filter is needed to allow the observation of all type of X-ray sources that present a UV/Visible bright counterpart. In this paper, we describe the main activities that we are carrying on for the conceptual design of the optical blocking filter, that will be mounted on the filter wheel, in order to satisfy the scientific requirements on optical load from bright UV/Vis astrophysical source, to maximize the X-ray transmission, and to withstand the severe acoustic and vibration loads foreseen during launch.

Published
2015

42. Large light X-ray optics: basic ideas and concepts

Author

Giancarlo Parodi, Peter Friedrich, Oberto Citterio, Bernd Aschenbach, Mauro Ghigo, Günther Hasinger, G. Pareschi, Heinrich W. Braeuninger, and Francesco Mazzoleni

Subjects
Physics, Atmospheric Science, business.industry, Aerospace Engineering, X-ray optics, Astronomy and Astrophysics, Active optics, X-ray telescope, Finite element method, Geophysics, Optics, Space and Planetary Science, Thermal, Orbit (dynamics), General Earth and Planetary Sciences, Angular resolution, business, Order of magnitude
Abstract

One of the main guidelines for future X-ray astronomy projects like, e.g., XEUS (ESA) and Generation-X (NASA) is to utilize grazing-incidence focusing optics with extremely large telescopes (several tens of m2 at 1 keV), with a dramatic increase in collecting area of about two order of magnitude compared to the current X-ray telescopes. In order to avoid the problem of the source's confusion limit at low fluxes, the angular resolution required for these optics should be superb (a few arcsec at most). The enormous mirror dimensions together with the high imaging performances give rise to a number of manufacturing problems. It is basically impossible to realize so large mirrors from closed Wolter I shells which benefit from high mechanical stiffness. Instead the mirrors need to be formed as rectangular segments and a series of them will be assembled in a petal. Taking into account the realistic load capabilities of space launchers, to be able to put in orbit so large mirror modules the mass/geometric-area ratio of the optics should be very small. Finally, with a so large optics mass it would be very difficult to provide the electric power for an optics thermal active control, able to maintain the mirrors at the usual temperature of 20 °C. Therefore, very likely, the optics will instead operate in extreme thermal conditions, with the mirror temperature oscillating between −30 and −40 °C, that tends to exclude the epoxy replication approach (the mismatch between the CTE of the substrate and that of the resin would cause prohibitively large deformations of the mirror surface profiles). From these considerations light weight materials with high thermal–mechanical properties such as glass or ceramics become attractive to realize the mirrors of future Xray telescopes. In this paper, we will discuss a segments manufacturing method based on BorofloatTM glass. A series of finite element analysis concerning different aspects of the production, testing and integration of the optics are also presented as well.

Published
2004

43. A Generalisable Experience of Distance Education in Electronics

Author

Marco Chirico, Giancarlo Parodi, and Anna Marina Scapolla

Subjects
Digital electronics, Engineering, Multimedia, Operations research, business.industry, Distance education, Reuse, computer.software_genre, Education, Upgrade, ComputingMilieux_COMPUTERSANDEDUCATION, The Internet, Electronics, Electrical and Electronic Engineering, business, computer
Abstract

This paper presents the proposal of setting up an environment for a standardized collection of didactic multimedia material that will offer new opportunities for sharing, reusing and distributing courses on the Internet. The proposed approach is based on the EU ARIADNE Project methodology and tools. Starting from an analysis of didactic experiences in analog and digital electronics, we suggest an extension of the approach to the Faculty of Engineering to improve the definition of new courses, the continuous upgrade of documents and the exchange of expertise.

Published
2002

44. Evaluation of the surface strength of glass plates shaped by hot slumping process

Author

Marcos Bavdaz, Gianpiero Tagliaferri, Francesco Martelli, B. Salmaso, Oberto Citterio, Eric Wille, Laura Proserpio, Roberto Dall'igna, Francesco Borsa, Stefano Basso, Mirko Silvestri, M. Civitani, Giorgia Sironi, Giancarlo Parodi, Daniele Spiga, Alberto D'este, Mauro Ghigo, and Giovanni Pareschi

Subjects
High Energy Astrophysical Phenomena (astro-ph.HE), Materials science, Physics - Instrumentation and Detectors, Borosilicate glass, General Engineering, X-ray optics, FOS: Physical sciences, Context (language use), X-ray telescope, Instrumentation and Detectors (physics.ins-det), Atomic and Molecular Physics, and Optics, Finite element method, law.invention, Radius of curvature (optics), Telescope, law, Composite material, Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Instrumentation and Methods for Astrophysics (astro-ph.IM), Slumping
Abstract

The Hot Slumping Technology is under development by several research groups in the world for the realization of grazing-incidence segmented mirrors for X-ray astronomy, based on thin glass plates shaped over a mould at temperatures above the transformation point. The performed thermal cycle and related operations might have effects on the strength characteristics of the glass, with consequences on the structural design of the elemental optical modules and consecutively on the entire X-ray optic for large astronomical missions like IXO and ATHENA. The mechanical strength of glass plates after they underwent the slumping process was tested through destructive double-ring tests in the context of a study performed by the Astronomical Observatory of Brera with the collaboration of Stazione Sperimentale del Vetro and BCV Progetti. The entire study has been realized on more than 200 D263 Schott borosilicate glass specimens of dimension 100 mm x 100 mm and thickness 0.4 mm, either flat or bent at a Radius of Curvature of 1000 mm through the particular pressure assisted hot slumping process developed by INAF-OAB. The collected experimental data have been compared to non-linear FEM analyses and treated with Weibull statistic to assess the current IXO glass X-ray telescope design, in terms of survival probability, when subject to static and acoustic loads characteristic of the launch phase. The paper describes the activities performed and presents the obtained results., Comment: Accepted for publication in Optical Enginnering (Jun 26, 2014)

Published
2014
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45. Crystal chemistry of kimzeyite from Anguillara, Mts. Sabatini, Italy

Author

Flavio Capitanio, David C. Smith, Emanuela Schingaro, Fernando Scordari, Giancarlo Parodi, and Annibale Mottana

Subjects
Crystal, Crystallography, symbols.namesake, Transition metal, Geochemistry and Petrology, Crystal chemistry, Chemistry, Formula unit, symbols, Electron microprobe, Raman spectroscopy, Single crystal, Diffractometer
Abstract

A single garnet crystal of kimzeyite from Anguillara Sabazia, Sabatini Volcanic District (Rome), has been studied by electron probe microanalysis (EPMA), single crystal X-ray diffraction (XRD) and Raman spectroscopy (RS). X-ray intensities for the structure refinement were collected by means of both a conventional four circle diffractometer (CD) and an area detector (AD) diffractometer. Salient crystallographic data from AD measurements are: a = 12.397(4) A, V = 1905.24 A 3 , μ= 25 cm −1 , crystal dimension ∼ 40 μm, D x =3.83 g cm −3 . The chemical analyses allowed to ascertain that Ca, Ba, Fe, Al, Mg, REE, Zr, Si and Ti are present in the structure. The transition element distribution is: Fe 3+ (Y) ≪ Fe 3+ (Z), and Ti as Ti 4+ occurs only at Y. No hydrogen atoms were detected. The problem of the correct distribution of Ba and REE (essentially Eu and Gd) is dealt with, but not fully solved in the present study. Because of the very small amount of sample available and of the strong dilution of Ba and REE (∼0.03 and 0.02 atoms per formula unit respectively) the correct distribution of these atoms over the X and Y sites is problematical. The radius ratio rule and electrostatic requirements suggest Ba at X and REE at Y. From these principles, the following site distribution can be deduced: Ca 2+ and Ba 2+ at X; Mg 2 +, REE 3+ , Zr 4+ , Ti 4+ , Fe 3+ at Y; Si 4+ , Al 3+ , Fe 3+ at Z. On the other hand, structural details and the best fit between EPMA and XRD site populations indicate REE at X and Ba at Y. Bond strength theory arguments support this hypothesis. The main substitution mechanisms can be summed up as follows: 1) Ti 4+ (Y) + Fe 3+ (Z) ↔ Si 4+ (Z) + M 3+ (Y) [schorlomite substitution]; 2) Zr 4+ (Y) + M 3+ (Z) ↔ Si 4+ (Z) + M 3+ (Y) [kimzeyite substitution]; 3) Mg 2+ (Y) + Zr 4+ (Y) ↔ 2M 3+ (Y) [morimotoite-like substitution], where M 3+ = (Al, Fe). In addition, following the bond strength theory indications, another mechanism which possibly involves the X and Y sites is also taken into account: 4) REE 3+ (X) + Ba 2+ (Y) ↔ Ca 2+ (X) + M 3+ (Y).

Published
2001

46. Dynamic Helical CT of Breast Tumors

Author

T. Massa, Massimo Calabrese, E. Melani, F. Zandrino, R. C. Parodi, Giuseppe Canavese, Giancarlo Parodi, Francesco Sardanelli, and A. Imperiale

Subjects
Adult, Time Factors, Mammary gland, Contrast Media, Breast Neoplasms, Malignancy, Sensitivity and Specificity, Fine needle aspiration cytology, Image Processing, Computer-Assisted, medicine, Humans, Neoplasm Invasiveness, Radiology, Nuclear Medicine and imaging, In patient, Aged, Intravenous contrast, business.industry, Contraindications, Lymphoma, Non-Hodgkin, Biopsy, Needle, Carcinoma, Ductal, Breast, Middle Aged, medicine.disease, Magnetic Resonance Imaging, Helical ct, Lymphoma, Radiographic Image Enhancement, medicine.anatomical_structure, Fibroadenoma, Injections, Intravenous, Female, Tomography, X-Ray Computed, Nuclear medicine, business, Follow-Up Studies, Mammography
Abstract

PURPOSE The purpose of our study was to test dynamic helical CT (hCT) in the evaluation of breast tumors. METHOD Thirty-six patients with 39 suspected lesions underwent breast hCT before and 1, 3, and 8 min after intravenous contrast medium administration. A marked enhancement (> or = 100%) at 1 or 3 min without increase at 8 minutes was considered as the primary indicator for malignancy. Twenty carcinomas, one metastatic non-Hodgkin lymphoma, six fibroadenomas, and six other benign findings were histologically assessed. Six cases had negative fine needle aspiration cytology and at least a 2 year negative follow-up. RESULTS hCT showed a 100% sensitivity and 83.3% specificity. Considering carcinomas and fibroadenomas, significant differences were found for the percent enhancement at 1 min (p = 0.002) as well as for the density increase or decrease at 3 versus 1 min (p = 0.0035), at 8 versus 1 min (p = 0.0027), and at 8 versus 3 min (p = 0.0180). CONCLUSION hCT proved to have a high diagnostic efficacy in evaluating breast tumors. Even though it involves some exposure to radiation, it should be considered in patients in whom MR is contraindicated.

Published
1998

47. Parallel Computing Architectures for Video-Coding and Multimedia Applications

Author

Giancarlo Parodi, A. De Gloria, and F. Passaggio

Subjects
Computational Theory and Mathematics, Computer architecture, Artificial Intelligence, Computer science, Data-intensive computing, Parallel computing, Unconventional computing, Software, Computer Science Applications, Theoretical Computer Science, Coding (social sciences)
Published
1997

48. Thin fused silica optics for a few arcsec angular resolution and large collecting area x-ray telescope

Author

Alberto Moretti, E. Mattaini, Mauro Ghigo, Marta Civitani, G. Tagliaferri, G. Pareschi, Stefano Basso, Giancarlo Parodi, Paolo Conconi, Oberto Citterio, and Sergio Campana

Subjects
Physics, Figuring, business.industry, Antenna aperture, Polishing, X-ray optics, X-ray telescope, law.invention, Telescope, Optics, law, Angular resolution, business, Image resolution
Abstract

The implementation of a X-ray mission with high imaging capabilities, similar to those achieved with Chandra (< 1 arcsec Half Energy Width, HEW), but with a much larger throughput is a very attractive perspective, even if challenging. For such a mission the scientific opportunities, in particular for the study of the early Universe, would remain at the state of the art for the next decades. At the beginning of the new millennium the XEUS mission has been proposed, with an effective area of several m2 and an angular resolution better than 2 arcsec HEW. Unfortunately, after the initial study, this mission was not implemented, mainly due to the costs and the low level of technology readiness. Currently the most advanced proposal for such a kind of mission is the SMART-X project, led by CfA and involving several other US Institutes. This project is based on adjustable segments of thin foil mirrors with piezo-electric actuators, aiming to achieve an effective area < 2 m2 at 1 keV and an angular resolution better than 1 arcsec HEW. Another attractive technology to realize an X-ray telescope with similar characteristics is being developed at NASA/Goddard. In this case the mirrors are based on Si substrates that are super-polished and figured starting from a bulky Si ingot, from which they are properly cut. Here we propose an alternative method based on precise direct grinding, figuring and polishing of thin (a few mm) glass shells with innovative deterministic polishing methods. This is followed by a final correction via ion figuring to obtain the desired accuracy in order to achieve the 1 arc sec HEW requirement. For this purpose, a temporary stiffening structure is used to support the shell from the polishing operations up to its integration in the telescope supporting structure. We will present the technological process under development, the results achieved so far and some mission scenarios based on this kind of optics, aiming to achieve an effective area more than 10 times larger than Chandra and an angular resolution of 1 arcsec HEW on axis and of a few arcsec off-axis across a large field of view (1 deg in diameter).

Published
2013

49. The ASTRI SST-2M prototype for the next generation of Cherenkov telescopes: structure and mirrors

Author

Giovanni Pareschi, Luigi Lessio, Francesco Martelli, Enrico Cascone, Giorgio Toso, Giorgia Sironi, Giancarlo Parodi, M. Fiorini, Luca Stringhetti, Paolo Conconi, Raffaele Tomelleri, G. Rodeghiero, Nicola La Palombara, Enrico Giro, Pierfrancesco Rossettini, Rodolfo Canestrari, and Gino Tosti

Subjects
Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, Cherenkov Telescope Array, law.invention, Telescope, Optics, law, Observatory, Astrophysics::Solar and Stellar Astrophysics, Angular resolution, business, Reflection (computer graphics), Focus (optics), Image resolution, Cherenkov radiation
Abstract

The next generation of Imaging Atmospheric Cherenkov Telescope will explore the uppermost end of the Very High Energy domain up to about few hundreds of TeV with unprecedented sensitivity, angular resolution and imaging quality. To this end, the Italian National Institute of Astrophysics (INAF) is currently developing a scientific and technological telescope prototype for the implementation of the Cherenkov Telescope Array (CTA) observatory. The Italian ASTRI program foresees the full design, development, installation and calibration of a Small Size 4-meter class Telescope, adopting an aplanatic, wide-field, double-reflection optical layout in a Schwarzschild-Couder configuration. In this paper we discuss about the technological solutions adopted for the telescope and for the mirrors. In particular we focus on the structural and electro-mechanical design of the telescope, now under fabrication. The results on the optical performance derived from mirror prototypes are here described, too.

Published
2013

50. Evaluation of the surface strength of glass plates shaped by hot slumping process

Author

Bianca Salmaso, Alberto D'este, Francesco Martelli, Laura Proserpio, Giuseppe Crimi, G. Pareschi, Mirko Silvestri, Roberto Dall'igna, Giancarlo Parodi, and Mauro Ghigo

Subjects
Materials science, business.industry, Borosilicate glass, X-ray telescope, Finite element method, law.invention, Telescope, Optics, law, Phase (matter), Composite material, business, FOIL method, Slumping, Weibull distribution
Abstract

The Hot Slumping Technology is under development by several research groups in the world for the realization of X-ray segmented mirrors, based on thin glass plates: during the process of slumping, a glass foil is shaped over a mould at temperatures above its transformation point. The performed thermal cycle and related operations might have effects on the strength characteristics of the glass, with consequences on the structural design of the elemental optical module and consecutively on the whole X-ray telescope. No reference technical literature exists for this particular aspect since the strength of glass depends on several parameters connected to any of the manufacturing and glass history stages, such as the distribution of surface flaws or the residual internal stresses. It is therefore extremely important to test the mechanical strength of the glass plates after they underwent the slumping process. The Astronomical Observatory of Brera (INAFOAB, Merate - Italy) started a deep analysis of this aspect, with the collaboration of Stazione Sperimentale del Vetro (SSV, Murano - Italy) and BCV Progetti (Milano - Italy). The entire study has been realized on borosilicate glass D263 by Schott, largely considered for the realization of next-generation IXO-like X-ray telescope. More than 200 slumped plates of dimension 100 mm x 100 mm and thickness 0.4 mm, both flat and curved, have been produced and tested; the collected experimental data have been compared to non-linear FEM analyses and treated with Weibull statistics, giving the strength data necessary to assess the current IXO glass X-ray telescope design, in terms of survival probability, when subject to static and acoustic load characteristic of the launch phase. The paper describes the activities performed and presents the obtained results.

Published
2013

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