He, Xing-Fei
Description
This thesis describes the Raman heterodyne detection of magnetic resonance in the ³A
ground state of the nitrogen-vacancy C'-1· V) centre in diamond. The recently developed theory of
Raman heterodyne spectroscopy was tested and compared with the spectra measured on the N-V
centre. Among those results, the electron-nuclear double resonance (ENDOR), nuclear-nuclear
double resonance (double NMR), Autler-Townes effect, coherence transfer and Zeeman quantum
beat were observed for the first time...[Show more] using such techniques. Raman heterodyne techniques were
also used to investigate the level anticrossing, hyperfine and nuclear quadrupole interactions, and
spin relaxations of the N-V centre with high sensitivity and precision.
This thesis is comprised of three parts. Part one includes Chapters 1 to 3, providing
introductory accounts. Chapter l is an introduction to the N-V colour centre, which describes
the defect configuration, the spin Hamiltonian and the calculations of energy levels and wave
functions of the ³A ground state. Chapter 2 briefly describes the theory of Raman heterodyne
spectroscopy - a coherent optical radio-frequency (RF) double resonance technique, in particular
the Raman heterodyne signals at weak and intense RF fields. Chapter 3 deals with experimental
details and techniques utilized in the studies.
Part two consists of Chapters 4 and 5, where the Raman heterodyne theory is compared
with experimental results. Chapter 4 presents the Raman heterodyne detected nuclear magnetic
resonance (NMR) and electron paramagnetic resonance (EPR) lineshapes compared with
theoretical results at various RF power levels, laser intensities and laser frequencies within the
6380A zero-phonon line. The double resonance spectra obtained by Raman heterodyne
techniques are discussed in Chapter 5, where attention is paid to the analysis of their spectral profiles depending on the detection scheme.
The application of Raman heterodyne techniques to the studies of magnetic resonance of the
N-V centre is described in part three, consisting of Chapters 6 to 9. The EPR measurements are
described in Chapter 6, which were used to study various interactions near the level anticrossing,
in particular the spin alignment. The hyperfine and nuclear quadrupole interactions probed by the
NMR, ENDOR and hole burning measurements are described in Chapter 7. From these
measurements, the hyperfine and quadrupole parameters in the spin Hamiltonian were fully
determined. Chapter 8 deals with the Autler-Townes effect in the NMR and EPR transitions. By
measuring the Autler-Townes spittings, the magnitudes of matrix elements of the NMR
transitions were examined and compared. Chapter 9 presents the coherent spin transient
properties, including nutations, echoes, Zeeman beating and coherence transfer. The dephasing
time and homogeneous linewidths of the NMR and EPR transitions were then determined from
the echo measurements.
Finally, the thesis is summarized in Chapter 10.
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