|
|
Kinch MA, Wan C-F Beck J. D. 1/f noise in HgCdTe photodiodes. J. Electron. Mater.. 2005;34(6):928–32.
|
|
|
|
Лудков ДН. Терагерцовые смесители на горячих электронах из тонких сверхпроводниковых пленок NbN и NbTiN [Ph.D. thesis].; 2005.
|
|
|
|
Gross R, Marx A. Applied superconductivity: Josephson effect and superconducting electronics. Chapter 7. In: Walther-Meißner-Institut.; 2005.
|
|
|
|
Кошелец ВП, Дмитриев ПН, Ермаков АБ, Филиппенко ЛВ, Корюкин ОВ, Торгашин МЮ, et al. Интегральный сверхпроводниковый спектрометр. Известия вузов. Радиофизика. 2005;48(10-11):947–54.
|
|
|
|
Mygind J, Samuelsen MR, Koshelets VP, Sobolev AS. Simple theory for the spectral. linewidth of the mm-wave Josephson flux flow oscillator [abstract]. In: Pi-shift Workshop “Physics of superconducting phase-shift devices”. Ischia, Italy; 2005. p. 22.
|
|
|
|
Koshelets VP, Dmitriev PN, Ermakov AB, Filippenko LV, Sobolev AS, Torgashin MY, et al. Superconducting flux-flow oscillators for THz integrated receiver [abstract]. In: Presented at the second Franco-Russian Seminar on Nanotechnologies. Lille, France; 2005.
|
|
|
|
Vaks VL, Kurin VV, Pankratov AL, Koshelets VP. Investigation of spectral properties of phase-focked flux flow oscillator [abstract]. In: ISEC. Netherlands; 2005. PD-04.
|
|
|
|
Hoogeveen RWM, Yagoubov PA, de Lange A, Selig AM, Koshelets VP, Ellison B. N., et al. Superconducting integrated receiver development for TELIS. In: Proc. 12th International Symposium on Remote Sensing. Bruges, Belgium; 2005.
|
|
|
|
Тарасов М, Кузьмин Л. Концепция смесителя на основе болометра на холодных электронах. Письма в ЖЭТФ. 2005;81(10):661–4.
|
|
|
|
Tol J van, Brunel L-C, Wylde RJ. A quasioptical transient electron spin resonance spectrometer operating at 120 and 240 GHz. Rev Sci Instrum. 2005;76(7):074101 (1 to 8).
Abstract: A new multifrequency quasioptical electron paramagnetic resonance (EPR) spectrometer is described. The superheterodyne design with Schottky diode mixer/detectors enables fast detection with subnanosecond time resolution. Optical access makes it suitable for transient EPR (TR-EPR) at 120 and 240 GHz. These high frequencies allow for an accurate determination of small g-tensor anisotropies as are encountered in excited triplet states of organic molecules like porphyrins and fullerenes. The measured concentration sensitivity for continuous-wave (cw) EPR at 240 GHz and at room temperature without cavity is 1013 spins/cm3 (15 nM) for a 1 mT linewidth and a 1 Hz bandwidth. With a Fabry-Perot cavity and a sample volume of 30 nl, the sensitivity at 240 GHz corresponds to [approximate]3×109 spins for a 1 mT linewidth. The spectrometer's performance is illustrated with applications of transient EPR of excited triplet states of organic molecules, as well as cw EPR of nitroxide reference systems and a thin film of a colossal magnetoresistance material.
|
|
