Your search keyword '"Rostem, K."' showing total 4 results

1. Precision Control of Thermal Transport in Cryogenic Single-Crystal Silicon Devices

Author

Rostem, K, Chuss, D. T, Colazo, F. A, Crowe, E. J, Denis, K. L, Lourie, N. P, Moseley, S. H, Stevenson, T. R, and Wollack, E. J

Subjects

Astrophysics

Abstract

We report on the diffusive-ballistic thermal conductance of multi-moded single-crystal silicon beams measured below 1 K. It is shown that the phonon mean-free-path is a strong function of the surface roughness characteristics of the beams. This effect is enhanced in diffuse beams with lengths much larger than, even when the surface is fairly smooth, 510 nm rms, and the peak thermal wavelength is 0.6 microns. Resonant phonon scattering has been observed in beams with a pitted surface morphology and characteristic pit depth of 30 nm. Hence, if the surface roughness is not adequately controlled, the thermal conductance can vary significantly for diffuse beams fabricated across a wafer. In contrast, when the beam length is of order, the conductance is dominated by ballistic transport and is effectively set by the beam cross-sectional area. We have demonstrated a uniformity of +/-8% in fractional deviation for ballistic beams, and this deviation is largely set by the thermal conductance of diffuse beams that support the micro-electro-mechanical device and electrical leads. In addition, we have found no evidence for excess specific heat in single-crystal silicon membranes. This allows for the precise control of the device heat capacity with normal metal films. We discuss the results in the context of the design and fabrication of large-format arrays of far-infrared and millimeter wavelength cryogenic detectors.

Published

2014

2. Multitone harmonic-balance simulations of an x-ray transition-edge sensor characterized at BESSY II.

Author

Rostem, K., Goldie, D. J., Withington, S., Hoevers, H. F. C., Gottardi, L., and Van der Kuur, J.

Subjects

*SIMULATION methods & models, *X-rays, *DETECTORS, *SYNCHROTRON radiation

Abstract

We present multitone harmonic-balance (MTHB) simulations of a Ti–Au x-ray transition-edge sensor (TES) microcalorimeter in a 5×5 pixel spectrometer array. The dynamic response of the TES microcalorimeter under simulation has been extremely well characterized at the BESSY II Synchrotron Radiation Facility in Berlin. We compare our simulated results directly with these measurements, and show that the MTHB algorithm is able to simulate to great accuracy the dynamic behavior of the TES, even when saturated by 6 keV photons. In this paper, we provide a detailed account of the MTHB simulations, and discuss the impact of this work on future missions such as the International X-ray Observatory. [ABSTRACT FROM AUTHOR]

Published

2010

3. High resolution on-chip thermometry using a microstrip-coupled transition edge sensor.

Author

Goldie, D. J., Rostem, K., and Withington, S.

Subjects

*TEMPERATURE measurements, *STRIP transmission lines, *INTEGRATED circuits, *DETECTORS, *PHOTONS

Abstract

Our recent work demonstrated highly efficient coupling of broadband thermal photon radiation between the termination resistors of a superconducting microstrip transmission line measured using a transition edge sensor (TES). A simple modification of this scheme is presented that permits rapid thermometry of micron-scale objects at temperatures below 3 K. Broadband photon noise gives a limiting temperature sensitivity of 3.8 μK for a 1 s integration time for measurements at 0.5 K. In practice, phonon noise in the thermal link between the TES and the heat bath limits the achievable temperature resolution to about 30 μK for a typical TES with noise equivalent power of 2×10-17 W/Hz with the same integration time. [ABSTRACT FROM AUTHOR]

Published

2010

4. Multitone large-signal analysis of superconducting transition-edge sensors for astronomy.

Author

Rostem, K., Withington, S., and Goldie, D. J.

Subjects

*PHYSICS research, *ENGINEERING instruments, *PHYSICAL sciences, *DETECTORS, *ALGORITHMS, *COMPUTER-aided design

Abstract

A simple transition-edge sensor (TES) is governed by two coupled, nonlinear equations, which when solved give the behavior of the device given the initial conditions. The two equations describe the full electrical and thermal characteristics of the device and the way in which the device interacts with the external electrical and thermal circuits. To date these coupled nonlinear equations have been solved analytically in the small-signal limit, by linearizing the equations about some operating point. The resulting coupled linear equations contain a wealth of interesting physics, and form the principal tool by which all detectors are currently designed and modeled. In this article we describe a numerical technique for solving the coupled nonlinear equations rigorously, without any assumptions about the magnitudes of the various signals and parameters that determine the behavior of a device. The technique is based on a harmonic balance algorithm that searches, in the frequency domain, for voltage, current, and temperature wave forms that are consistent with the solid-state physics of the device. Indeed, both the small and large signal limits can be simulated, and the full harmonic content of the system retrieved. In this article, we will outline the principal features of the algorithm, and show various results such as I-V curves, saturation when signal power is modulated, impedance response when the bias current is modulated and signal power kept constant, and pulsed signal power analysis that shows the dynamics of a device. Numerous extensions of this fundamental technique are now possible including multitone nonharmonic analysis, large-signal impedance calculation, modeling of complicated thermal circuits, noise models, and frequency-domain multiplexing. We believe that our algorithm will become the principle technique for analyzing the large-signal behavior of all TES detectors and on that basis we are developing computer aided design software. [ABSTRACT FROM AUTHOR]

Published

2007