Torgashin, M. Y., Koshelets, V. P., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., & Yagoubov, P. A. (2007). Superconducting integrated receivers based on Nb-AlN-NbN circuits. IEEE Trans. Appl. Supercond., 17(2), 379–382.
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Koshelets, V. P., Shitov, S. V., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., Koryukin, O. V., Sobolev, A. S., et al. (2004). Integrated submillimeter and terahertz receivers with superconducting local oscillator. In Presanted at 8th International Workshop “From Andreev Reflection to the International Space Station”.
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Koshelets, V. P., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., Sobolev, A. S., Torgashin, M. Y., et al. (2005). Superconducting flux-flow oscillators for THz integrated receiver. In Presented at the second Franco-Russian Seminar on Nanotechnologies. Lille, France.
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Koshelets, V. P., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., Koryukin, O. V., Torgashin, M. Y., et al. (2005). Integrated superconducting spectrometer for atmosphere monitoring. Radiophys. Quant. Electron., 48(10-11), 844–850.
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Koshelets, V. P., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., Khudchenko, A. V., Koryukin, O. V., et al. (2004). SIR for TELIS (post-critical) review.
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Koshelets, V. P., Borisov, V. B., Dmitriev, P. N., Ermakov, A. B., Filippenko, L. V., Khudchenko, A. V., et al. (2006). Integrated submillimeter receiver for TELIS. Joint International Workshop “Nanosensors and Arrays of Quantum Dots and Josephson Junctions for space applications”, 10th International Workshop “From Andreev Reflection to the Earliest Universe”, .
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Feofanov, A. K., Oboznov, V. A., Bol'Ginov, V. V., Lisenfeld, J., Poletto, S., Ryazanov, V. V., et al. (2010). Implementation of superconductor/ferromagnet/ superconductor. Nat. Phys., 6(8), 593–597.
Abstract: High operation speed and low energy consumption may allow the superconducting digital single-flux-quantum circuits to outperform traditional complementary metal-oxide-semiconductor logic. The remaining major obstacle towards high element densities on-chip is a relatively large cell size necessary to hold a magnetic flux quantum Φ0. Inserting a π-type Josephson junction in the cell is equivalent to applying flux Φ0/2 and thus makes it possible to solve this problem. Moreover, using π-junctions in superconducting qubits may help to protect them from noise. Here we demonstrate the operation of three superconducting circuits-two of them are classical and one quantum-that all utilize such π-phase shifters realized using superconductor/ferromagnet/superconductor sandwich technology. The classical circuits are based on single-flux-quantum cells, which are shown to be scalable and compatible with conventional niobium-based superconducting electronics. The quantum circuit is a π-biased phase qubit, for which we observe coherent Rabi oscillations. We find no degradation of the measured coherence time compared to that of a reference qubit without a π-junction.
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