Your search keyword '"focal plane camera"' showing total 4 results

1. Simultaneous multichannel mass-specific detention for high-performance liquid chromatography using an array detector sector-field mass spectrometer

Author

Hieftje, Gary

Published

2004

2. Simultaneous multichannel mass-specific detection for high-performance liquid chromatography using an array detector sector-field mass spectrometer.

Author

Barnes IV, James H., Schilling, Gregory D., Stone, Steven F., Sperline, Roger P., Denton, M. Bonner, Young, Erick T., Barinaga, Charles J., Koppenaal, David W., and Hieftje, Gary M.

Subjects

*LIQUID chromatography, *INDUCTIVELY coupled plasma mass spectrometry, *DETECTORS, *MASS spectrometry, *FOCAL planes, *ANALYTICAL chemistry

Abstract

The use of a separation step, such as liquid chromatography, prior to inductively coupled plasma mass spectrometry (ICP-MS) has become a common tool for highly selective and sensitive analyses. This type of coupling has several benefits including the ability to perform speciation analysis or to remove isobaric interferences. Several limitations of conventional instruments result from the necessity to scan or pulse the mass spectrometer to obtain a complete mass spectrum. When the instrument is operated in such a non-continuous manner, duty cycle is reduced, resulting in poorer absolute limits of detection. Additionally, with scanning instruments, spectral skew can be introduced into the measurement, limiting quantitation accuracy. To address these shortcomings, a high-performance liquid chromatograph has been coupled to an ICP-MS capable of continuous sample introduction and simultaneous multimass detection. These features have been realized with a novel detector array, the focal plane camera. Instrument performance has been tested for both speciation analysis and for the elimination of isobaric interferences. Absolute limits of detection in the sub picogram to tens of picograms regime are obtainable, while the added mass dimension introduced by simultaneous detection dramatically increases chromatographic peak capacity. [ABSTRACT FROM AUTHOR]

Published

2004

3. Development of the wide field imager for Athena

Author

Marco Barbera, Rafael Strecker, Josef Eder, Markus Plattner, Arne Rau, Kirpal Nandra, Jörn Wilms, Norbert Meidinger, Daniel Pietschner, T. Brand, Maria Fürmetz, Jonas Reiffers, Meidinger, N., Eder, J., Fürmetz, M., Nandra, K., Pietschner, D., Plattner, M., Rau, A., Reiffers, J., Strecker, R., Barbera, M., Brand, T., and Wilms, J.

Subjects

Physics, X-ray detector, CMOS sensor, Hot and Energetic Universe, Pixel, business.industry, Electronic, Optical and Magnetic Material, Applied Mathematics, Computer Science Applications1707 Computer Vision and Pattern Recognition, focal plane camera, Condensed Matter Physic, X-ray astronomy, Full width at half maximum, Cardinal point, Optics, Active pixel sensor, Observatory, WFI, Angular resolution, Athena, Electrical and Electronic Engineering, business, Image resolution, DEPFET

Abstract

The WFI (Wide Field Imager) instrument is planned to be one of two complementary focal plane cameras on ESA's next X-ray observatory Athena. It combines unprecedented survey power through its large field of view of 40 arcmin x 40 arcmin together with excellent count-rate capability (>= 1 Crab). The energy resolution of the silicon sensor is state-of-the-art in the energy band of interest from 0.2 keV to 15 keV, e.g. the full width at half maximum of a line at 6 keV will be

Published

2015

4. The wide field imager instrument for Athena

Author

Jörn Wilms, Markus Plattner, Andrea Santangelo, Norbert Meidinger, Matteo Porro, Chris Tenzer, Arne Rau, and Kirpal Nandra

Subjects

X-ray detector, Physics, CMOS sensor, Pixel, Spectrometer, business.industry, Stray light, Detector, focal plane camera, hot and energetic universe, Settore ING-INF/01 - Elettronica, Active pixel sensor, Optics, Analog signal, Athena, DEPFET, WFI, Focal length, business, Image resolution

Abstract

The "Hot and Energetic Universe" has been selected as the science theme for ESA's L2 mission, scheduled for launch in 2028. The proposed Athena X-ray observatory provides the necessary capabilities to achieve the ambitious goals of the science theme. The X-ray mirrors are based on silicon pore optics technology and will have a 12 m focal length. Two complementary camera systems are foreseen which can be moved in and out of the focal plane by an interchange mechanism. These instruments are the actively shielded micro-calorimeter spectrometer X-IFU and the Wide Field Imager (WFI). The WFI will combine an unprecedented survey power through its large field of view of 40 arcmin with a high countrate capability (approx. 1 Crab). It permits a state-of-the-art energy resolution in the energy band of 0.1 keV to 15 keV during the entire mission lifetime (e.g. FWHM ≤ 150 eV at 6 keV). This performance is accomplished by a set of DEPFET active pixel sensor matrices with a pixel size matching the angular resolution of 5 arcsec (on-axis) of the mirror system. Each DEPFET pixel is a combined detector-amplifier structure with a MOSFET integrated onto a fully depleted 450 micron thick silicon bulk. The signal electrons generated by an X-ray photon are collected in a so-called internal gate below the transistor channel. The resulting change of the conductivity of the transistor channel is proportional to the number of electrons and thus a measure for the photon energy. DEPFETs have already been developed for the "Mercury Imaging X-ray Spectrometer" on-board of ESA’s BepiColombo mission. For Athena we develop enhanced sensors with integrated electronic shutter and an additional analog storage area in each pixel. These features improve the peak-to-background ratio of the spectra and minimize dead time. The sensor will be read out with a new, fast, low-noise multi-channel analog signal processor with integrated sequencer and serial analog output. The architecture of sensor and readout ASIC allows readout in full frame mode and window mode as well by addressing selectively arbitrary sub-areas of the sensor allowing time resolution in the order of 10 μs. The further detector electronics has mainly the following tasks: digitization, pre-processing and telemetry of event data as well as supply and control of the detector system. Although the sensor will already be equipped with an on-chip light blocking filter, a filter wheel is necessary to provide an additional external filter, an on-board calibration source, an open position for outgassing, and a closed position for protection of the sensor. The sensor concept provides high quantum efficiency over the entire energy band and we intend to keep the instrumental background as low as possible by designing a graded Z-shield around the sensor. All these properties make the WFI a very powerful survey instrument, significantly surpassing currently existing observatories and in addition allow high-time resolution of the brightest X-ray sources with low pile-up and high efficiency. This manuscript will summarize the current instrument concept and design, the status of the technology development, and the envisaged baseline performance.

Published

2014