软X射线CCD相机

软x射线、极紫外真空相机 ALEXi 4096 4096 系列

公司介绍:成立于2007年的greateyes,是以德国柏林洪堡大学的技术为基础,迅速发展成为国际知名的先进探测器生产企业。如今,其科研与工业客户群体已遍布多个国家。greateyes开发、生产并销售高性能科学相机。其作为精确探测器,被广泛应用于成像与谱学应用领域。同时,greateyes公司也生产用于太阳能产业的电致荧光与光致荧光检测系统。 产品介绍:16.8M像素背照式传感器的gre

  • 产地: 德国
  • 型号: ALEX 4096 4096( VUV,EUV,X-ray)
  • 品牌: Greateyes

公司介绍:

成立于2007年的greateyes,是以德国柏林洪堡大学的技术为基础,迅速发展成为国际知名的先进探测器生产企业。如今,其科研与工业客户群体已遍布多个国家。

greateyes开发、生产并销售高性能科学相机。其作为精确探测器,被广泛应用于成像与谱学应用领域。同时,greateyes公司也生产用于太阳能产业的电致荧光与光致荧光检测系统。

 

产品介绍:

16.8M像素背照式传感器的greateyes CCD相机,以其优异的性能满足科研与工业领域中高要求的应用。得益于15µm的大像素尺寸,该款相机具有高达350Ke-的最高满井容量和最小仅2.5e- rms的读出噪声,提供了极高的动态范围。采用4个输出放大器的读出方案来适应不同像素联用的设置。这款相机配置了一个具有TCP/IP功能的千兆以太网卡设置,允许其灵活集成到大型科学设施中。该款相机的传感器设置在法兰盘前面,使可检测角度最大化。在有气氛或者真空环境下,可接入单独的泵的接口。多级的半导体制冷方式可以为相机的传感器提供制冷,无需使用低温冷却器或 者液氮。该款相机为传感器和相机摄像头配置了非常精确的温度控制模块,适合于控制烘烤温度以达到UHV真空环境。


主要特点:

  • 科学级低噪声e2V传感器

  • 晶圆级16.8M CCD

  • 量子化效率高达98%

  • 满井容量高达350K eˉ

  • 深度制冷温度低至-90°C

  • 读出噪声低至2.5 eˉrms

  • 18 bit 动态范围

  • 灵活的4端口输出和像素联用




性能参数:

image.png

其他参数:

image.png

量子效率曲线

1581386728676265.jpg1581386728595035.jpg

The mean energy of a photon to generate

an electron-hole pair in silicon is 3.66 eV.




典型应用:

  • x射线断层扫描

  • 傅里叶变换全息术

  • X光透射

  • 相干衍射成像

  • 叠层衍射显微光谱成像

  • 掠入射小角度x射线散射

典型客户

Institute / company:

Web

ARCNL – Advanced Research Center for Nanolithography

http://www.arcnl.nl

CLPU – Centro de Láseres Pulsados

http://www.clpu.es

DESY – Deutsches Elektronen-Synchrotron

http://www.desy.de

Berlin Laboratory for innovative X-ray technologies (BLiX), Technische Universität Berlin

http://www.blix.tu-berlin.de

Helmholtz-Zentrum Berlin

http://www.helmholtz-berlin.de

Humboldt-Universität zu Berlin

https://www-pbp.physik.hu-berlin.de

IfG-Institute for Scientific

Instruments GmbH

http://www.ifg-adlershof.de

Indian Institute of Technology Bombay

http://www.iitb.ac.in

Institut Ruđer Bošković

http://www.irb.hr

ISAS – Institute for Analytical Sciences

http://www.isas.de

MBI – Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy

http://www.mbi-berlin.de

Max Planck Institute for the Structure and Dynamics of Matter

http://mpsd-cmd.cfel.de/xts

Max Planck Institute of Quantum Optics

http://www.mpq.mpg.de

Optigraph GmbH

http://www.optigraph.eu

Princeton University

http://www.princeton.edu

PTB – Physikalisch-Technische Bundesanstalt

http://www.ptb.de

Universität Hamburg – working at DESY

http://beschleunigerphysik.desy.de



北京众星联恒科技有限公司德国GE-EUV-soft X-ray相机 ALEX 4096 4096 系列.pdf


参考文献/Selected references: 

P. Wachulak, M. Duda, A. Bartnik, A. Sarzyński, Ł. Węgrzyński and H. Fiedorowicz, 2-D elemental mapping of an extreme ultraviolet-irradiated PET with a compact near edge X-ray fine structure spectromicroscopy, Spectrochimica Acta Part B: Atomic Spectroscopy, Volume 145, July 2018, Pages 107-114

P. Wachulak, A. Bartnik and H. Fiedorowicz, Optical coherence tomography (OCT) with 2 nm axial resolution using a compact laser plasma soft X-ray source, Nature Scientific Reports, volume 8, Article number: 8494 (2018)

P. Wachulak, M. Duda, A. Bartnik, A. Sarzyński, Ł. Węgrzyński, M. Nowak, A. Jancarek and H. Fiedorowicz, Compact system for near edge X-ray fine structure (NEXAFS) spectroscopy using a laser-plasma light source, Opt. Express 26, 8260-8274 (2018)

A. Jonas, T. Meurer, B. Kanngießer and I. Mantouvalou, Reflection zone plates as highly resolving broadband optics for soft X-ray laboratory spectrometers, Review of Scientific Instruments 89, 026108 (2018)

T. Pflug, J. Wang, M. Olbrich et al., Case study on the dynamics of ultrafast laser heating and ablation of gold thin films by ultrafast pump-probe reflectometry and ellipsometry, Appl. Phys. A (2018) 124: 116

C. Buerhop, S. Wirsching, A. Bemm et al. Evolution of cell cracks in PV modules under field and laboratory conditions. Prog Photovolt Res Appl. 2018;26:261–272

H. Stiel, J. Braenzel, A. Dehlinger, R. Jung, A. Luebcke, M. Regehly, S. Ritter, J. Tuemmler, M. Schnuerer and C. Seim, Soft x-ray nanoscale imaging using highly brilliant laboratory sources and new detector concepts, Proc. SPIE 10243, X-ray Lasers and Coherent X-ray Sources: Development and Applications, 1024309 (17 May 2017)

M. F. Nawaz, M. Nevrkla, A. Jancarek, A. Torrisi, T. Parkman, J. Turnova, L. Stolcova, M. Vrbova, J. Limpouch, L. Pina and P. Wachulak, Table-top water-window soft X-ray microscope using a Z-pinching capillary discharge source, JINST, 2016, Vol. 11 PO7002

I. Mantouvalou, K. Witte, W. Martyanov, A. Jonas, D. Grötzsch, C. Streeck, H. Löchel, I. Rudolph, A. Erko, H. Stiel and B. Kanngießer, Single shot near edge x-ray absorption fine structure spectroscopy in the laboratory, Appl. Phys. Lett. 108, 201106 (2016)

S. Fazinić, I. Božičević Mihalić, T. Tadić, D. Cosic, M. Jakšić, D. Mudronja, Wavelength dispersive µPIXE setup for the ion microprobe, Nucl. Instr. Meth. Phys. Res. Sec. B, 2015, Vol. 363, pages 61-65   

A. Hafner, L. Anklamm, A. Firsov, A. Firsov, H. Löchel, A. Sokolov, R. Gubzhokov, and A. Erko, Reflection zone plate wavelength-dispersive spectrometer for ultra-light elements measurements, Opt. Express, 2015, Vol. 23, No. 23:29476-29483

P. W. Wachulak, A. Torrisi, A. Bartnik, D. Adjei, J. Kostecki, L. Wegrzynski, R. Jarocki, M. Szczurek, H. Fiedorowicz, Desktop water window microscope using a double‑stream gas puff target source, Applied Physics B, 2015, 118:573–578

I. Mantouvalou, K. Witte, D. Grötzsch, M. Neitzel, S. Günther, J. Baumann, R. Jung, H. Stiehl, B. Kanngießer, W. Sandner, High average power, highly brilliant laser-produced laser plasma source for soft X-ray spectroscopy, Review of Scientific Instruments, Vol. 86, Issue 3, 2015 

T. Krähling, A. Michels,S. Geisler, S. Florek, J. Franzke, Investigations into Modeling and Further Estimation of Detection Limits of the Liquid Electrode Dielectric Barrier Discharge, Analytical Chemistry, 2014, 86(12), 5822-8

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