Zero bias terahertz and subterahertz detector operating at room temperature

Zero bias terahertz and subterahertz detector operating at room temperature

In this paper, the experimental study of the terahertz and subterahertz hot electron bolometer based on narrow-gap semiconductor compound Hg₁₋xCdxTe is presented. The measurements were performed in the temperature range from 77 to 300 K at various operating mode and frequency. The estimated value...

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Дата:2010
Автори: Momot, N., Zabudsky, V., Tsybrii, Z., Apats’ka, M., Smoliy, M., Dmytruk, N.
Формат: Стаття
Мова:English
Опубліковано: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 2010
Назва видання:Semiconductor Physics Quantum Electronics & Optoelectronics
Онлайн доступ:http://dspace.nbuv.gov.ua/handle/123456789/118225
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Назва журналу:Digital Library of Periodicals of National Academy of Sciences of Ukraine
Цитувати:Zero bias terahertz and subterahertz detector operating/ N. Momot, V. Zabudsky, Z. Tsybrii, M. Apats'ka, M. Smoliy, N. Dmytruk // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2010. — Т. 13, № 2. — С. 166-169. — Бібліогр.: 11 назв. — англ. at room temperature

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Digital Library of Periodicals of National Academy of Sciences of Ukraine
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spelling irk-123456789-1182252017-05-30T03:04:39Z Zero bias terahertz and subterahertz detector operating at room temperature Momot, N. Zabudsky, V. Tsybrii, Z. Apats’ka, M. Smoliy, M. Dmytruk, N. In this paper, the experimental study of the terahertz and subterahertz hot electron bolometer based on narrow-gap semiconductor compound Hg₁₋xCdxTe is presented. The measurements were performed in the temperature range from 77 to 300 K at various operating mode and frequency. The estimated value of the noise equivalent power at room temperature for detector proposed was 1.3·10⁻⁸ W/Hz¹/² and 5.4·10⁻⁹ W/Hz¹/² at bias current I = 1 mA and I = 0, respectively. 2010 Article Zero bias terahertz and subterahertz detector operating/ N. Momot, V. Zabudsky, Z. Tsybrii, M. Apats'ka, M. Smoliy, N. Dmytruk // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2010. — Т. 13, № 2. — С. 166-169. — Бібліогр.: 11 назв. — англ. at room temperature 1560-8034 PACS 07.57.Kp, 72.20.Ht http://dspace.nbuv.gov.ua/handle/123456789/118225 en Semiconductor Physics Quantum Electronics & Optoelectronics Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description In this paper, the experimental study of the terahertz and subterahertz hot electron bolometer based on narrow-gap semiconductor compound Hg₁₋xCdxTe is presented. The measurements were performed in the temperature range from 77 to 300 K at various operating mode and frequency. The estimated value of the noise equivalent power at room temperature for detector proposed was 1.3·10⁻⁸ W/Hz¹/² and 5.4·10⁻⁹ W/Hz¹/² at bias current I = 1 mA and I = 0, respectively.
format Article
author Momot, N.
Zabudsky, V.
Tsybrii, Z.
Apats’ka, M.
Smoliy, M.
Dmytruk, N.
spellingShingle Momot, N.
Zabudsky, V.
Tsybrii, Z.
Apats’ka, M.
Smoliy, M.
Dmytruk, N.
Zero bias terahertz and subterahertz detector operating at room temperature
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Momot, N.
Zabudsky, V.
Tsybrii, Z.
Apats’ka, M.
Smoliy, M.
Dmytruk, N.
author_sort Momot, N.
title Zero bias terahertz and subterahertz detector operating at room temperature
title_short Zero bias terahertz and subterahertz detector operating at room temperature
title_full Zero bias terahertz and subterahertz detector operating at room temperature
title_fullStr Zero bias terahertz and subterahertz detector operating at room temperature
title_full_unstemmed Zero bias terahertz and subterahertz detector operating at room temperature
title_sort zero bias terahertz and subterahertz detector operating at room temperature
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 2010
url http://dspace.nbuv.gov.ua/handle/123456789/118225
citation_txt Zero bias terahertz and subterahertz detector operating/ N. Momot, V. Zabudsky, Z. Tsybrii, M. Apats'ka, M. Smoliy, N. Dmytruk // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2010. — Т. 13, № 2. — С. 166-169. — Бібліогр.: 11 назв. — англ. at room temperature
series Semiconductor Physics Quantum Electronics & Optoelectronics
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fulltext Semiconductor Physics, Quantum Electronics & Optoelectronics, 2010. V. 13, N 2. P. 166-169. © 2010, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 166 PACS 07.57.Kp, 72.20.Ht Zero bias terahertz and subterahertz detector operating at room temperature N. Momot*, V. Zabudsky, Z. Tsybrii, M. Apats’ka, M. Smoliy, N. Dmytruk V. Lashkaryov Institute of Semiconductor Physics, NAS of Ukraine, 41, prospect Nauky, 03028 Kyiv; e-mail: momotnatasha@isp.kiev.ua Abstract. In this paper, the experimental study of the terahertz and subterahertz hot electron bolometer based on narrow-gap semiconductor compound Hg1-xCdxTe is presented. The measurements were performed in the temperature range from 77 to 300 K at various operating mode and frequency. The estimated value of the noise equivalent power at room temperature for detector proposed was 1.3·10–8 W/Hz1/2 and 5.4·10–9 W/Hz1/2 at bias current I = 1 mA and I = 0, respectively. Keywords: THz radiation, bolometer, hot-carrier effect. Manuscript received 02.02.10; accepted for publication 25.03.10; published online 30.04.10. 1. Introduction Currently, there is a substantial interest in a part of the spectrum located between microwave and optical ranges. Commonly this frequency band is defined as 0.1-10 THz and called “the terahertz region”. The attention to terahertz radiation is caused by its unique properties because of which it finds a wide use for science and technology [1]. Particularly, it is of great interest to create the detection array for terahertz imaging. Heterodyne detectors are the most sensitive in the terahertz region [2], but creating terahertz heterodyne arrays is associated with some difficulties: i) because of all array elements require a common local oscillator, the number of elements is limited of its power; ii) heterodyne terahertz detectors are mainly based on superconductors now (semiconductor-insulator- semiconductor structures or hot electron bolometers) [3] that are in need of cooling to the superconducting transition temperature. Since open-cycle cooling systems are awkward and expensive while closed-cycle cooling systems are low-power, the cryogenic cooling limits the expansion of the number of array elements, too. Therefore, heterodyne terahertz detector arrays are constructed now with a small number of elements (a few tens) [4]. The direct-detection matrix receivers are better in comparison with heterodyne detectors concerning the number of elements expansion. In this paper, a direct-detection terahertz and subterahertz receiver based on narrow-gap semiconductor compound Hg1-xCdxTe (MCT) is investigated. This detector can operate at room temperature, zero bias and have several micrometers area. Therefore, compact terahertz detector array can be created as based on this material. 2. Design of detector and experimental results As basic material for manufacturing the THz detector, p- type conductivity epitaxial films CdxHg1-xTe/CdZnTe (x = 0.22-0.23) were used. These were grown using liquid phase epitaxy technique providing carrier concentration 3.61015 to 21016 cm–3 and thicknesses of layers within the range 2-20 µm. Taking into account the mechanical and electro-physical properties of CdHgTe, the design and technological route of a multi-element detector was developed. The technological route of manufacturing this structure consists of the following stages:  control of MCT layers quality by using optical microscopy and IR-Fourier spectroscopy methods;  preliminary chemical preparation of MCT surface;  formation of CdTe passivation layer;  photolithography processes;  metallization through lift-off photolithography method. The surface of a detector active element has been protected by CdTe thin film formed using the hot wall epitaxy method. Metallic contacts to the active element, which serve as antenna, have been placed on the passivation layer. Etching the mesa-structures was used (up to the high-resistance substrate) with the purpose of short-circuit prevention between matrix elements. The Semiconductor Physics, Quantum Electronics & Optoelectronics, 2010. V. 13, N 2. P. 166-169. © 2010, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 167 Fig. 1. Scheme of THz antenna and microphoto of its central part that were made using high resolution optical microscopy. The area 1 is the active element, 2 and 3 – metallic contacts. electrical contacts between sensitive element and antenna have been realized by chemical etching the contact windows into the passivation layer. Special bromic etchant has been picked up for etching these passivation thin layers. The detector matrix consists of 4×11 elements (each of it has 10×50 µm2 active area and was connected to the bow-tie like antenna with 568750 µm2 area). The scheme and microphoto of the detector with antenna are shown in Fig. 1. The theory of the photoresponse mechanism of such detector has been proposed in [5]. In this device, the radiation heats electrons in the semiconductor, whereas semiconductor lattice heating is absent. The heating changes generation-recombination processes that produce changes of the carrier number and of the semiconductor resistance. A value of the semiconductor hot electron bolometer response time is determined by the carrier lifetime. The response of Hg1-xCdxTe bolometer was measured in the range of frequencies 0.037-1.58 THz and in the temperature range from 77 to 300 K at various detector bias currents. The experimental results indicating that the detector is sensitive in the mentioned range are presented in [6]. In addition, these results show that the photoresponse of p-type Hg1-xCdxTe at zero bias is higher than that of the n-type Hg1-xCdxTe. In Fig. 2, the response of p-type MCT bolometer is shown as the function of temperature for the acceptor concentration Np = 7·1015 cm–3, mole fraction of CdTe x = 0.2 and dimensions of the sensitive element 10×50×17 μm. At T = 77 K the value of photoresponse at non-zero bias is several times higher than at I = 0 for that sample. At the same time, at room temperature the value of photoresponse is of the same order of magnitude for I = 1 mA and I = 0. Fig. 3 demonstrates the photoresponse of this bolometer as the function of the detector current. The deviation from linearity at close to zero biases is probably caused by rectifying effect between semiconductor and metallization. For example, in Fig. 4 the experimental results for another sample response as the function of detector current at T = 77 K and its I – V characteristic are presented. For this sample, the detector sensitivity at zero bias current even higher as compared to the non-zero bias. As a rule, to characterize THz detectors, the noise equivalent power (NEP) is used. NEP is the radiant power needed to generate signal equivalent to noise. The NEP can be calculated as: 2/1)( NEP fS U V N   , (1) where UN is the noise voltage, SV – detector voltage sensitivity, Δf – pass bandwidth. Semiconductor Physics, Quantum Electronics & Optoelectronics, 2010. V. 13, N 2. P. 166-169. © 2010, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 168 100 150 200 250 -10 0 10 20 P ho to re sp on se , V T, K I=1 mA I=-1 mA I=0 Fig. 2. The bolometer response as a function of temperature. The frequency of incident radiation is ν = 78 GHz. The frequency of modulation is Δf = 360 Hz. The radiation flux density is ~4.5 mW/cm2 in the place of sample location. CdxHg1-xTe photoresistors are typically characterized with the Johnson noise, generation- recombination noise, and photon noise. The mean-square power for Johnson’s noise is [7]: fTkRU BJ  4 2 , (2) where R is the sample resistance, kB is the Boltzmann constant, T is sample temperature, Δf is a bandwidth for the central frequency. The spectral density of generation-recombination noise current caused by interband transitions is of the form [8]: )1)(()( )1(4 )( 22 00 2 00 00 22    pnpbn pnbI fS c I , (3) where pnb  / is the mobility ratio, τ is the dominant lifetime, Ic is the current, n0 and p0 refer to the total numbers of electrons and holes in the sample of thermal equilibrium. The generation-recombination noise voltage is equal -1 0 1 -10 0 10 20 30 P ho to re sp on se ,  V I, mA Fig. 3. The bolometer response as a function of detector current at T = 77 K. The frequency of incident radiation is ν = 78 GHz. The frequency of modulation is Δf = 360 Hz. The radiation flux density is ~4.5 mW/cm2 in the place of sample location. -100 0 100 -1 0 1 I, m A U, mV a) -1 0 1 -10 -5 0 5 10 15 20 P h o to re sp o n se , V I, mA b) Fig. 4. The I-V characteristic and bolometer response as a function of detector current at T = 77 K. The frequency of incident radiation is ν = 130 GHz. fRSU Irg  22 . (4) For photon noise (the dispersion of falling to sample photons number), the next expression can be written [9]   eRNAU phn 21 η2 , (5) where N is the photon flux from the T = 300 K background hemisphere, e is the electron charge, η = 0.5 is the quantum efficiency of detector, and A is the sensitive element area.                 2 1 1 ( 4 d e c TN kT hc . (6) General noise is estimated using the following formula: 222 phnJrg UUUU   . (7) The noise voltages in the sample were estimated from Eqs (2)-(7) at Δf = 1 Hz and the results have been summarized in Table 1. At room temperature, generation-recombination noise is higher than the other ones. Because of the generation-recombination noise is apparent at the current flow through the sample, its contribution can be excluded by a zero bias mode. Semiconductor Physics, Quantum Electronics & Optoelectronics, 2010. V. 13, N 2. P. 166-169. © 2010, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 169 Table 1. Estimated noise voltages. Noise type Т = 77 K Т = 300 K Johnson’s noise 5.1·10–10 V 5.4·10–10 V Generation- recombination noise 2·10–11 V 1.2·10–9 V Photon noise 1.4·10–11 V 1.7·10–12 V Given in Table 2 are the values of estimated noise equivalent power for the detector currents I = 1 mA and I = 0. Table 2. Estimated NEP. Detector current, I Т = 77 K Т = 300 K 1 mA 4·10–10 1.3·10–8NEP, W/Hz1/2 0 8·10–10 5.4·10–9 Thus, because of the smaller noise, the detector threshold sensitivity is higher at zero bias than at an applied current despite a smaller photoresponse. The estimated noise equivalent power of detector is comparable with the NEP of other terahertz uncooled devices [10, 11]. 3. Conclusions The semiconductor hot electron bolometer based on narrow-gap Hg1-xCdxTe can be used for detection of terahertz and subterahertz radiation. The noise equivalent power of such detector that operates at room temperature and zero bias is of the order of 10–9 W/Hz1/2, thus multi-element terahertz detector can be created as being based on it. References 1. F P. Siegel, Terahertz technology // IEEE Trans. Microwave Theory and Techniques 50(3), p. 910- 928 (2002). 2. F. Sizov, THz radiation sensors // Opto-Electron. Rev. 18(1), p. 10-36 (2010). 3. Sheng-Cai Shi, Superconducting THz detectors and their applications in radio astronomy // Terahertz Science and Technology 1(4), p. 199-215 (2008). 4. I.I. Eru, Matrix multibeam reception of submillimeter and infrared electromagnetic waves (the state-of-the-art and trends) // Radio Physics and Radio Astronomy 11(3), p. 298-307 (2006). 5. V. Dobrovolsky, F. Sizov, A room temperature, or moderately cooled, fast THz semiconductor hot electron bolometer // Semicond. Sci. Technol. 22, p. 103-106 (2007). 6. F.F. Sizov, V. Dobrovolsky, V. Zabudsky, Yu. Kamenev, N. Momot, and J. Gumenjuk- Sychevska, mm- and THz-waves detector on the base of narrow-gap semiconductors // Proc. SPIE 7309 (2009). 7. N.B. Lukyanchikova, Noise Research in Semiconductor Physics. Gordon and Breach Science Publishers, Amsterdam, 1999. 8. R.N. Sharma, K.M. van Vliet, Generation-recom- bination fluctuations in mercury-cadmium telluride // Phys. status solidi (a) 1, p. 765-773 (1970). 9. A. van der Ziel, Noise in Measurements. John Wiley & Sons Inc., 1976. 10. El Fatimy, A. Delagnes, J.C. Younus, A. Nguema, E. Teppe, F. Knap, W. Abraham, E. Mounaix, Plasma wave field effect transistor as a resonant detector for 1 terahertz imaging applications // Optics Communs 282(15), p. 3055-3058 (2009). 11. J.L. Hesler, T.W. Crowe, Responsivity and noise measurements of zero-bias Schottky diode detectors // 18th Intern. Symp. Space Terahertz Techn., Pasadena, 2007.

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