The University of Western Australia

UWA Staff Profile

Ipsum Lorem

Dr Maxim Goryachev

Research Associate
Academic Staff (Physics)

Contact details
Address
Academic Staff (Physics)
The University of Western Australia (M013)
35 Stirling Highway
CRAWLEY WA 6009
Australia
Phone
+61 8 6488 3606
Email
maxim.goryachev@uwa.edu.au
Qualifications
PhD Franche-Comte
Key research
Cryogenic Bulk Acoustic Wave devices, low temperature physics, spins in solids, microwave cavities
Publications
1) M. Goryachev,W.G. Farr, N.C. Carvalho, Daniel L. Creedon, J.M. Le Floch, S. Probst, P. Bushev, M.E. Tobar, ”Discovery of iron group impurity ion spin states in single crystal Y2SiO5 with strong coupling to whispering gallery photons”,
Appl. Phys. Lett., 106, 232401, 2015.
2) D.L. Creedon, J.M. Le Floch, M. Goryachev, W.G. Farr, S. Castelletto, M.E. Tobar, ”Strong Coupling Between P1
Diamond Impurity Centres and 3D Lumped Photonic Microwave Cavity”, Phys. Rev. B, 91, 140408(R), 2014.
3) M. Goryachev, M.E. Tobar, ”The 3D split-ring cavity lattice: a new metastructure for engineering arrays of coupled microwave harmonic oscillators,” New J. Phys., 17, 023003, 2015.
4) M. Goryachev, M.E. Tobar, ”Gravitational wave detection with high frequency phonon trapping acoustic cavities,” Phys. Rev. D, 90, 102005, 2014.
5) M. Goryachev, W.G. Farr, D.L. Creedon, Ya. Fan, M. Kostylev and M.E. Tobar, ”High-Cooperativity Cavity QED with Magnons at Microwave Frequencies,” Phys. Rev. Applied, 2, 054002, 2014.
6) M. Goryachev, Eu.N. Ivanov, F. van Kann, S. Galliou and M.E. Tobar, ”Observation of the fundamental Nyquist noise
limit in an ultra-high Q-factor cryogenic bulk acoustic wave cavity,” Appl. Phys. Lett., 105, 153505, 2014.
7) N.R. Nand, M. Goryachev, JM le Floch, D.L. Creedon and M.E. Tobar, ”Hyperparametric effects in a whispering-gallery mode rutile dielectric resonator at liquid helium temperatures,” J. Appl. Phys., 116, 134105, 2014.
8) S. Probst, A. Tkalcec, H. Rotzinger, D. Rieger, J-M. Le Floch, M. Goryachev, M. E. Tobar, A. V. Ustinov, and P.
A. Bushev, ”Three-dimensional cavity quantum electrodynamics with a rare-earth spin ensemble,” Phys. Rev. B, 90, 100404(R), 2014.
9) M. Goryachev, W.G. Farr, S. Galliou and M.E. Tobar, ”Jump Chaotic Behaviour of Ultra Low Loss Bulk Acoustic Wave Cavities,” Appl. Phys. Lett., 105, 063501, 2014.
10) M. Goryachev, M.E. Tobar, ”Effects of Geometry on Near Quantum Ground State Behaviour of Phonon-Trapping Acoustic Cavities,” New J. Phys., 16, 083007, 2014.
11) M. Goryachev, Ph. Abbe, B. Dulmet, R. Bourquin and S. Galliou, ”Measurements of Elastic Properties of Langatate at Liquid Helium Temperatures for design of ultra low loss mechanical systems,” Appl. Phys. Lett., 104, 261904, 2014.
12) W.G. Farr, M. Goryachev, L.D. Creedon and M.E. Tobar, ”Strong coupling between whispering gallery modes and
chromium ions in ruby,” Phys. Rev. B, vol. 90, no. 5, 054409, 2014.
13) M. Goryachev, W.G. Farr, L.D. Creedon and M.E. Tobar, ”Spin-Photon Interaction in a Cavity with Time-Reversal
Symmetry Breaking,” Phys. Rev. B, vol. 89, no. 22, 224407, 2014.
14) R. Bara-Maillet, M. Goryachev, D. Creedon, J-M. Le Floch, M.E. Tobar, ”Metal Bulk Foil Resistor Characterization for BAW Application at Low Cryogenic Temperatures”, IEEE Transactions on Instrumentation & Measurement, Vol. 63,
No. 3, pp. 628-632, 2014.
15) M. Goryachev, W.G. Farr, L.D. Creedon and M.E. Tobar, ”Controlling a whispering-gallery-doublet-mode avoided
frequency crossing: Strong coupling between photon bosonic and spin degrees of freedom,” Phys. Rev. A, vol. 89, no. 1, 013810, 2014.
16) W.G. Farr, L.D. Creedon, M. Goryachev, K. Benmessai and M.E. Tobar, ”Ultrasensitive microwave spectroscopy of
paramagnetic impurities in sapphire crystals at millikelvin temperatures,” Phys. Rev. B, vol. 88, no. 22, 224426, 2013.
17) M. Goryachev, W.G. Farr and M. E. Tobar, ”Giant g-factors of natural impurities in synthetic quartz,” Appl. Phys. Lett., vol. 103, no. 26, 262404, 2013.
18) J. Bourhill, K. Benmessai, M. Goryachev, D. L. Creedon, W. Farr, and M. E. Tobar, ”Spin bath maser in a cryogenically cooled sapphire whispering gallery mode resonator”, Phys. Rev. B, vol. 88, no. 23, 235104, 2013.
19) M. Goryachev, D.L. Creedon, S. Galliou, and M.E. Tobar, ”Observation of Rayleigh Phonon Scattering through Excitation of Extremely High Overtones in Low-Loss Cryogenic Acoustic Cavities for Hybrid Quantum Systems”, Phys. Rev. Lett., 111, 085502, 2013.
20) M. Goryachev, W.G. Farr, E.N. Ivanov and M.E. Tobar, ”Anomalously strong nonlinearity of unswept quartz acoustic cavities at liquid helium temperatures”, J. Appl. Phys., 114, 094506, 2013.
21) S. Galliou,M. Goryachev, R. Bourquin, P. Abb´e, J. Aubry, and M. Tobar, “Extremely low loss phonon-trapping cryogenic acoustic cavities for future physical experiments,” Nature: Scientific Reports, vol. 3, No. 2132, 2013.
22) M. Goryachev, S. Galliou, Ph. Abb´e, “Advances in development of quartz crystal oscillators at liquid helium temperatures,” Cryogenics, vol. 57, 104-112, June 2013.
23) M. Goryachev, D.L. Creedon, E.N. Ivanov, S. Galliou, R. Bourquin, M.E. Tobar, “Extremely high Q-factors in milligram
scale bulk acoustic wave quartz resonators at milli-kelvin temperature,” Appl. Phys. Lett., vol. 100, no. 24, 243504, 2012.
24) M. Goryachev, S. Galliou, J. Imbaud, and P. Abb´e, P.-Y. Bourgeois, S. Grop, and B. Dubois, “Quartz Resonator
Instabilities Under Cryogenic Conditions,” IEEE Trans. Ultrason., Ferroelect., Freq. Contr., vol. 59, no. 1, pp. 21-29, 2012.
25) M. Goryachev, S. Galliou, Ph. Abb´e, “Oscillator Frequency Stability Improvement by Means of Negative Feedback,” IEEE Trans. Ultrason., Ferroelect., Freq. Contr., vol. 58, no. 11, 2297-2304, Nov. 2011.
26) M. Goryachev, S. Galliou, “Parametric Model of the BAW Resonator Phase Noise,” Ultrasonics, vol. 51, no. 8, pp. 966-973, Dec. 2011.
27) S. Galliou, J. Imbaud, M. Goryachev, R. Bourquin, Ph. Abb´e, “Losses in High Quality Quartz Crystal Resonators at Cryogenic Temperatures,” Applied Physics Letters, vol. 98., no. 9, 091911, 2011.
28) M. Goryachev, S. Galliou, “Precision Close-to-Carrier Phase Noise Simulation of BAW Oscillators,” IEEE Trans.
Ultrason., Ferroelect., Freq. Contr., vol. 58, no. 1, pp. 6-9, Jan. 2010.
29) M. Goryachev, S. Galliou, Ph. Abb´e, “Cryogenic Transistor Measurement and Modeling for Engineering Applications,” Cryogenics, vol. 50, no. 1, pp. 381-389, 2010.
Research profile
Research profile and publications
 

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