Design and microfabrication of novel x-ray optics II

5-6 August 2004, Denver, Colorado, USA

Publisher: SPIE in Bellingham, WA

Written in English
Published: Pages: 266 Downloads: 196
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‪cosine BV‬ - ‪Cited by 1,‬ - ‪Optics‬ - ‪X-ray‬ - ‪Silicon‬ - ‪Sensors‬ - ‪Hyperspectral‬.   DESY researchers have designed innovative lenses with the potential to perform X-ray microscopy with nanometer-scale resolution. The team headed by Saša Bajt, DESY scientist from the Center for Free-Electron Laser Science (CFEL), used innovative materials to perfect the design of exclusive X-ray optics and accomplished a focus spot size that had a diameter of less than 10 nm, . Scientists at DESY have developed novel lenses that enable X-ray microscopy with record resolution in the nanometer regime. Using new materials, the research team has perfected the design of. Sizable single crystals of a nonlinear optical (NLO) material, Bi2ZnOB2O6, were grown by the Kyropoulos method from stoichiometric ratio compound melt. It is a congruent melting compound and crystallizes in the orthorhombic system, space group Pba2. The morphologies and habits of Bi2ZnOB2O6 crystals grown using [], [], and [] seeds were studied. The SHG efficiency of Bi2ZnOB2O6 is 3.

and micro optics were presented in the following areas: 1) design, analysis, and molding fabrication of biodegradable PLGA microstructures for implanted drug delivery application; 2) design, fabrication, and test of a novel three-dimensional micro mixer/reactor based on arrays of. Implantable devices such as pacemakers, cochlear implants, and deep brain stimulation devices enhance the quality of life for many people. Improving the integration of such devices with the body could enable the next generation of brain-machine interfaces (such as, implantable devices that can record and modulate neurological function in vivo) to monitor physiology, detect disease, and deploy. We report on a developed micromachined silicon platform for the precise assembly of 2D multilayer Laue lenses (MLLs) for high-resolution X-ray microscopy. The platform is 10 × 10 mm2 and is fabricated on ~ µm thick silicon wafers through multiple steps of photolithography and deep reactive-ion etching. The platform accommodates two linear MLLs in a pre-defined configuration with precise.   Developments of X-ray optics for full utilization of diffraction-limited storage rings (DLSRs) are presented. The expected performance of DLSRs is introduced using the design parameters of SPring-8 II. To develop optical elements applicable to manipulation of coherent X-rays, advanced technologies on precise processing and metrology were.

  Novel x-ray optics improve imaging at US beamline facility. 6 September Share this on social media: Tweet × NSLS-II scientist Hande Öztürk stands next to the Hard X-ray Nanoprobe (HXN) beamline, where her research team developed the new x-ray imaging technique. Credit. Complete turn-key design, fabrication, assembly and testing of X-Ray camera systems. Sensors, ASICs, electronics boards, firmware, software, mechanical/thermal assembly. Examples: Time-of-flight spectroscopy for electrons and ions, down to 30 ps resolution; Multiple types of Imaging cameras with low noise and high dynamic range at 50um and. /Photonics Microfabrication Engineer in the Microfabrication Processes Group, the candidate will play a critical leadership role in novel concept generation as well as the development of advanced Qualifications A Ph.D. or M.S. in physics, applied physics, mechanical engineering, chemical engineering, electrical engineering, material science. Purdue's top-ranked online graduate programs in Engineering offer a wide array of Master's of Science degrees. Click here or call to learn more.

Design and microfabrication of novel x-ray optics II Download PDF EPUB FB2

Get this from a library. Design and microfabrication of novel x-ray optics II: August,Denver, Colorado, USA. [Anatoly A Snigirev; Derrick C Mancini; Society of Photo-optical Instrumentation Engineers.; Boeing Company.;]. adshelp[at] The ADS is operated by the Smithsonian Astrophysical Observatory under NASA Cooperative Agreement NNX16AC86ACited by: 8.

Get this from a library. Design and microfabrication of novel x-ray optics: 9 July,Seattle, Washington, USA. [Derrick C Mancini; Society of Photo-optical Instrumentation Engineers.; Boeing Company.;].

The concept of the design and fabrication of X-ray diffraction focusing elements is discussed. This concept includes both reflection and transmission types of optics Cited by: 5. Design and Microfabrication of Novel X-Ray Optics II, edited by Anatoly A.

Snigirev, Derrick C. Mancini, Proceedings of SPIE Vol. (SPIE, Bellingham, WA, ) X/04/$15 doi: /   Maser J, Stephenson G, Vogt S, Yun W, Macrander A, Kang H, Liu C and Conley R Design and Microfabrication of Novel X-ray Optics II vol ed Snigirev A and Mancini D (SPIE) p Crossref [14].

given the acronym MOXI, standing for micro-opto-X-ray Imaging. The design and microfabrication of a one dimen-sional (1-D MOXI) focusing MOEMS system with micro slots for use in X-ray analysis of biological cells was reported in [3]. A 2-D MOXI adaptive optics system for X-ray focusing was suggested in [4].

The present paper. Lengeler B, Schroer C G, Kuhlmann M, Benner B, Günzler T F, Kurapova O, Zontone F, Snigirev A and Snigireva I Design and Microfabrication of Novel X-Ray Optics II Proc. SPIE ed A S Snigirev and D C Mancini. Crossref Google Scholar. X‐ray optics stands on the threshold of realizing its early promise: precision analysis of microstructure on the scale of the x‐ray wavelength.

The achievement of this exciting goal will depend in large part on advances in microfabrication technology making possible the precision fabrication of periodic microstructures.

A review of recent advances in, as well as future prospects for: x. attention at the Center for X-Ray Optics,Lawrence Berkeley National Laboratory, Berkeley, Californiaor by e-mail at [email protected] Corrections will be posted on the web and incorporated in subsequent printings.

Albert C. Thompson Douglas Vaughan 31 January Fabrication of high-aspect-ratio silicon micro- and nano-structures is a key process in many applications, such as microelectronics [], microelectromechanical systems [2,3], sensors [], thermoelectric materials [], battery anodes [], solar cells [], photonic devices [], and X-ray optics [].Microfabrication is usually achieved by reactive ion etching [], which requires high investment in tools.

Producing the next generation of X-ray optics, both for large astrophysics missions and smaller missions such as planetary exploration, requires much lower mass and therefore much thinner mirrors. The use of pore structures allows very thin mirrors in a stiff structure.

Over the last few years we have been developing ultra-low mass pore optics based on microchannel plate technology in glass. “Pathways to sub nm X–ray Imaging Using Zone Plate Lens,”, Design and Microfabrication of Novel X-Ray Optics II, edited by Anatoly A.

Snigirev, Derrick C. Mancini, Proceedings of SPIE Vol. (SPIE, Bellingham, WA, ) 3. “Advanced X-Ray integrated. Abstract. Due to the weak interaction of hard X rays with matter it is generally difficult to manipulate X rays by optical components.

As a result, there have been many complementary approaches to making X-ray optics, exploiting refraction, reflection, and diffraction of X-rays by matter. Abstract. Due to the weak interaction of hard x-rays with matter it is generally difficult to manipulate x-rays by optical components.

As a result, there have been many complementary approaches to making x-ray optics, exploiting refraction, reflection, and diffraction of x-rays by matter. As far as the thin lens approximation is not valid we developed and used accurate theory of long parabolic compound lens for ray-tracing analysis.

The experimental measurements were performed for the X-ray energies E = keV. The measured focus distance and effective aperture correlate with the theory. The advanced techniques include LIGA, which is an X-ray lithography process, and deep reactive ion etching (DRIE), a novel dry etching technology.

Ceramics have been investigated as a potential material, since they have desirable physical properties—for instance they could be used in the human body because of their bio-inertness. These fabrication techniques were found to be promising for a wide range of applications, such as integrated optics, microfluidics, and microelectromechanical systems [15].

Deng and coworkers reported about the novel AFM-based 3D nanofabrication process using ultrasonic vibration-assisted nanomachining.

Two methods namely layer-by-layer. This fascinating text contains a detailed treatise on the use of X-Ray optics in the taxonomy of minerals and gem stones.

An interesting and informative book on the subject, X-Ray Optics - The Diffraction of X-Rays by Finite and Imperfect Crystals is a must-have for anyone with an interest the study of crystals and constitutes a great addition to any gemmological : A.

Wilson. “Fabrication of Collimators for Gamma-ray Imaging,” Olga V. Makarova, Guohua Yang, Cha-Mei Tang, Derrick C. Mancini, Ralu Divan, Judith Yaeger, Proceedings of SPIE Design and Microfabrication of Novel X-Ray Optics II AugustDenver, CO Volume.

Micromachining and Microfabrication Process Technology II Editor(s): Stella W. Pang ; Shih-Chia Chang *This item is only available on the SPIE Digital Library. Design and Microfabrication of Novel X-Ray Optics II, edited by Anatoly A. Snigirev, Derrick C.

Mancini, Proceedings of SPIE Vol. (SPIE, Bellingham, WA, ) X/04/$15 doi: Novel laboratory X-ray sources, e. using micro-patterned anodes [24], and novel focusing optics, e. multilayer Laue lenses [25, 26], will enable spatial resolutions down to µm and 10 nm. Scientists at DESY have developed novel lenses that enable X-ray microscopy with record resolution in the nanometre regime.

Using new materials, the research team led by DESY scientist Saša Bajt from the Center for Free-Electron Laser Science (CFEL) has perfected the design of specialised X-ray optics and achieved a focus spot size with a diameter of less than ten nanometres. Yun, M. Feser, A.F. Lyon, F.

Duewer, Y. Wang, “Pathways to subnm x-ray imaging using zone plate lens,” in “Design and Microfabrication of Novel X-Ray Optics II,” Proc. SPIE– (). Development of x-ray pore optics: novel high-resolution silicon millipore optics for XEUS and ultralow mass glass micropore optics for imaging and timing.

In A. Snigirev and D. Mancini, editors, Design and Microfabrication of Novel X-Ray Optics II. Advances in X-Ray/EUV Optics and Components II, Two-step hard X-ray focusing combining Fresnel zone plate and single-bounce ellipsoidal capillary. Design and Microfabrication of Novel X-Ray Optics II, Howells, MR, Charalambous, P, He, H, Marcesini, S & Spence, JAn off-axis zone-plate monochromator for high-power undulator radiation.

in DC Mancini (ed.), Proceedings of SPIE - The International Society for Optical Engineering. vol.pp.Design and Microfabrication of Novel X-Ray Optics, Seattle, WA, United States, 7/9/ align the microscope optics, but also how to acquire electronic images and perform image processing.

Thus, the focus of the book is on the integrated microscope system, with foundations in optical theory but extensions into electronic imaging. Accordingly, the cover shows the conjugate field and aperture planes of the light microscope under.

`The book is an excellent resource for physicists and engineers in the field. It contains many ideas and practical details for the design and construction of microoptical devices.' Optik, (). "For the optical engineer it is an indispensable work." — Journal, Optical Society of America "As a practical guide this book has no rival." — Transactions, Optical Society "A noteworthy contribution," — Nature (London) Part I covers allordinary ray-tracing methods, together with the complete theory of primary aberrations and as much of higher aberration as is needed for the design Reviews: 7.

A review of research activities on opto-microfluidic sensors carried out by the research groups in Canada is presented. After a brief introduction of this exciting research field, detailed discussion is focused on different techniques for the fabrication of opto-microfluidic sensors, and various applications of these devices for bioanalysis, chemical detection, and optical measurement.

Some specific topics explored include hot embossing of LIGA microstructures, X-ray masks for LIGA microfabrication, design for LIGA and safe manufacturing, polymer optics and optical MEMS, and refractive X-ray lenses produced by X-ray lithography.

B&w photos and images are included.