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Superconducting THz Transmission Spectrometer Comprising Josephson Oscillator and Cold-Electron Bolometer M.Tarasov, L.Kuzmin, E.Stepantsov, I.Agulo, A.Kalabukhov, T.Claeson Title
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Outline Cold electron bolometer concept Bolometer samples Josephson oscillators Experimental setup Terahertz response Josephson and thermal radiation Conclusion
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CEB chip layout 4 junction structure for cooling/heating Log-periodic antenna for 0.2-2 THz range Double-dipole antenna for 600 GHz Double-dipole antenna for 300 GHz
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Center part of LPA Logperiodic antenna designed for frequency range 0.2- 2THz. Absorber length is 10 m
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LPA SEM image Double dipole antenna designed for 300 GHz central frequency
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SEM view of the LPA center SINIS bolometer inside the double dipole antenna. Absorbel length is 10 m
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AFM picture of CEB
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He3 sorption cooler
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Quasioptical schematics JJ oscillator CEB
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Sample holders Quasioptical sample holders with silicon and sapphire extended hyperhemisphere lenses and pogo- pins for contacts
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Back-to-back configuration
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Sample holder
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YBaCuO film on tilted substrate SPM view of the 250 nm YBaCuO film on 14 o tilted sapphire substrate. Subgrains are elongated in the a-b plane perpendicular to tilt direction
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Bicrystal Josephson junction SPM view of the YBaCuO bridge across the bicrystal grain boundary. Bridge length is 5 m, width below 1 m.
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Josephson chip layout
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IV curve and Shapiro steps IV curve of Josephson junction at 4.2 K without radiation (dashed) and under 300 GHz irradiation when critical current is completely suppressed
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Current and voltage response Response of a 10 k bolometer measured at 260 mK by applying a dc power to external junctions
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Josephson radiation and overheating Radiation from a 55 Josephson junction with I c =10 A and when ctritical current is suppressed to zero by magnetic field
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Overheating of the Josephson junction Temperature of the Josephson microbridge Planck’s radiation law, neglecting Tp For our design frequency 300 GHz and bias range up to 5 mV, it can be roughly fitted with the approximate expression
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Log-periodic and double dipole Response of bolometer with a double-dipole antenna (black) and a log-periodic antenna (blue) under rediation from the same Josephson junction with log-periodic antenna
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Magnetic field influence Signal from a Josephson junction with I c =400 A (black) and suppressed down to 150 A (blue), measured by bolometer with a double-dipole antenna
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Terahertz response Dependence of bolometer response on the frequency of the first harmonic of Josephson oscillations. Last maximum corresponds to 1.7THz.
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Conclusion We demonstrated the response of a normal metal cold electron bolometer at frequencies up to 1.7 THz. A voltage response of the bolometer is 4. 10 8 V/W and an amplifier-limited technical noise equivalent power 1.3. 10 -17 W/Hz 1/2. We were first to use electrically tunable high critical temperature Josephson quasioptical oscillator as a source of radiation in the range 0.2-2 THz. A high critical temperature Josephson junction operated at temperature about 2 K shows a I c R n product over 4.5 mV that enables an oscillation frequency over 2 THz. Combination of a Terahertz-band Josephson junction and a hot electron bolometer brings a possibility to develop a quasioptical cryogenic compact transmission spectrometer with a resolution of about 1 GHz. Such cryogenic spectrometer can be used for low-temperature spectral evaluation of any cryogenic detector, quasioptical submm wave grid filter, neutral density filter, absorber, etc. Cold electron bolometer detected that a Josephson junction is overheated by a transport current even when it is placed on millikelvin stage.
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Per aspera ad astra
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