Dr. Ferran Martin
Dr. Ferran Martin
Congratulations to New ICFO PhD graduate
Dr Ferran Martín graduated with a thesis on “Coherent Sensing of Magnetic Waveforms with Spin-squeezed Atoms”
December 14, 2017
Dr. Ferran Martín did his undergraduate studies in Physics at the Universitat Autònoma de Barcelona. He later completed the Master in Photonics program offered by ICFO, the Universitat Politèccnia de Catalunya, the Universitat Autònoma de Barcelona, and the Universitat de Barcelona before joining the Quantum Information With Cold Atoms And Non-classical Light research group led by ICREA Professor at ICFO Morgan Mitchell. His work at ICFO has focused on the study of Quantum metrology strategies to increase the sensitivity beyond the SQL by means of quantum engineering the atomic states. ABSTRACT: Optical magnetometers use magnetically-sensitive atomic ensembles and optical read-out to detect the amplitude of magnetic fields. They have become the most sensitive instruments for measuring low-frequency magnetic fields surpassing competing technologies like superconducting quantum interface devices (SQUIDs), and find applications in a variety of fields ranging from medicine, biology and geophysics, as well as tests of fundamental physics. However, their fundamental sensitivity is bounded by quantum mechanical behavior of the atoms, which gives rise to the standard quantum limit (SQL). As many instruments are approaching this fundamental limit, it becomes necessary to explore ways to overcome the SQL. Quantum metrology studies strategies to increase the sensitivity beyond the SQL by means of quantum engineering the atomic states.
In this thesis, we investigate the quantum enhanced detection of time varying radio-frequency magnetic fields using a cold atomic ensemble of 87Rb atoms held in an optical dipole trap. We first theoretically develop a new measurement technique based on stroboscopic back-action evading measurements that takes advantage of the atomic coherence. This measurement scheme is suitable for the detection of arbitrarily-chosen components of radio-frequency waveforms and includes radio-frequency magnetometry as a special case.
Experimentally, we demonstrate the capabilities of this technique using a linearly chirped waveform as a test case. As a first experiment, we demonstrate the selective response of the method in the coherently accumulated signal by the atoms. For this, we dispersively probe the atoms via Faraday rotation and non-destructively measure the induced magnetization. .
In the last part of the thesis we demonstrate quantum enhanced magnetic field detection. In a measure-evolve-measure (MEM) sequence, a first stroboscopic quantum non-demolition (QND) measurement produces a state with reduced projection noise, followed by a period of free evolution where the atoms accumulate signal. A second QND measurement detects the change relative to thefirst measurement. We demonstrate entanglement-enhanced sensing of sinusoidal and linearly chirped waveforms, with metrologically-relevant noise reduction of xi_m^2 =0.84(8) and xi_m^2=0.80(3), respectively. We achieve volume-adjusted sensitivity delta Bsqrt{V}=3.96 fT(cm3/Hz)^{1/2}, comparable to the best radio-frequency magnetometers.
THESIS COMMITTEE:
Prof Philipp Treutlein, University Of Basel
Darrick Chang, ICFO
Georgios Vasilakis, IESL- FORTH
In this thesis, we investigate the quantum enhanced detection of time varying radio-frequency magnetic fields using a cold atomic ensemble of 87Rb atoms held in an optical dipole trap. We first theoretically develop a new measurement technique based on stroboscopic back-action evading measurements that takes advantage of the atomic coherence. This measurement scheme is suitable for the detection of arbitrarily-chosen components of radio-frequency waveforms and includes radio-frequency magnetometry as a special case.
Experimentally, we demonstrate the capabilities of this technique using a linearly chirped waveform as a test case. As a first experiment, we demonstrate the selective response of the method in the coherently accumulated signal by the atoms. For this, we dispersively probe the atoms via Faraday rotation and non-destructively measure the induced magnetization. .
In the last part of the thesis we demonstrate quantum enhanced magnetic field detection. In a measure-evolve-measure (MEM) sequence, a first stroboscopic quantum non-demolition (QND) measurement produces a state with reduced projection noise, followed by a period of free evolution where the atoms accumulate signal. A second QND measurement detects the change relative to thefirst measurement. We demonstrate entanglement-enhanced sensing of sinusoidal and linearly chirped waveforms, with metrologically-relevant noise reduction of xi_m^2 =0.84(8) and xi_m^2=0.80(3), respectively. We achieve volume-adjusted sensitivity delta Bsqrt{V}=3.96 fT(cm3/Hz)^{1/2}, comparable to the best radio-frequency magnetometers.
THESIS COMMITTEE:
Prof Philipp Treutlein, University Of Basel
Darrick Chang, ICFO
Georgios Vasilakis, IESL- FORTH
Thesis Committee