Read-out and coherent manipulation of an isolated nuclear spin : using a single-molecule magnet spin-transistor /: using a single-molecule magnet spin-transistor. ([2016])
- Record Type:
- Book
- Title:
- Read-out and coherent manipulation of an isolated nuclear spin : using a single-molecule magnet spin-transistor /: using a single-molecule magnet spin-transistor. ([2016])
- Main Title:
- Read-out and coherent manipulation of an isolated nuclear spin : using a single-molecule magnet spin-transistor
- Further Information:
- Note: Stefan Thiele.
- Authors:
- Thiele, Stefan
- Contents:
- Supervisor's Foreword; Abstract; Acknowledgements; Contents; 1 Introduction; 1.1 Molecular Spintronics; 1.2 Quantum Information Processing; 1.3 Thesis Outline; References; 2 Single Electron Transistor; 2.1 Equivalent Circuit; 2.2 Coulomb Blockade; 2.3 Cotunneling Effect; 2.4 Kondo Effect; References; 3 Magnetic Properties of TbPc2; 3.1 Structure of TbPc2; 3.2 Electronic Configuration of Tb3+; 3.3 Zeeman Effect; 3.4 Electron-Electron Interaction; 3.5 Spin-Orbit Interaction; 3.6 Ligand-Field Interaction; 3.7 Hyperfine Interaction; 3.8 Magnetization Reversal. 3.8.1 Quantum Tunneling of Magnetization3.8.2 Direct Transtions; References; 4 Experimental Details; 4.1 Overview Setup; 4.2 Dilution Refrigerator; 4.3 3D Vector Magnet; 4.4 Current Leads; 4.5 Sample Holder; 4.6 Filter; 4.6.1 Low Frequency Filters; 4.6.2 High Frequency Filters; 4.7 Signal Transducer; 4.8 Real-Time Data Acquisition; 4.9 Sample Fabrication; 4.9.1 Nanowire Fabrication; 4.9.2 Electromigration; 4.9.3 Fabrication of a Molecular Spin Transistor; References; 5 Single-Molecule Magnet Spin-Transistor; 5.1 Mode of Operation; 5.2 Read-Out Quantum Dot. 5.3 Magneto-Conductance and Anisotropy5.4 Exchange Coupling; 5.5 2D Magneto-Conductance of the Read-Out Dot; 5.6 Electronic Spin Relaxation; 5.7 Quantum Tunneling of Magnetization; 5.8 Summary; References; 6 Nuclear Spin Dynamics -- T1; 6.1 Signal Analysis; 6.2 Relaxation Time T1 and Read-Out Fidelity F; 6.3 Quantum Monte Carlo Simulations; 6.3.1 Algorithm; 6.3.2Supervisor's Foreword; Abstract; Acknowledgements; Contents; 1 Introduction; 1.1 Molecular Spintronics; 1.2 Quantum Information Processing; 1.3 Thesis Outline; References; 2 Single Electron Transistor; 2.1 Equivalent Circuit; 2.2 Coulomb Blockade; 2.3 Cotunneling Effect; 2.4 Kondo Effect; References; 3 Magnetic Properties of TbPc2; 3.1 Structure of TbPc2; 3.2 Electronic Configuration of Tb3+; 3.3 Zeeman Effect; 3.4 Electron-Electron Interaction; 3.5 Spin-Orbit Interaction; 3.6 Ligand-Field Interaction; 3.7 Hyperfine Interaction; 3.8 Magnetization Reversal. 3.8.1 Quantum Tunneling of Magnetization3.8.2 Direct Transtions; References; 4 Experimental Details; 4.1 Overview Setup; 4.2 Dilution Refrigerator; 4.3 3D Vector Magnet; 4.4 Current Leads; 4.5 Sample Holder; 4.6 Filter; 4.6.1 Low Frequency Filters; 4.6.2 High Frequency Filters; 4.7 Signal Transducer; 4.8 Real-Time Data Acquisition; 4.9 Sample Fabrication; 4.9.1 Nanowire Fabrication; 4.9.2 Electromigration; 4.9.3 Fabrication of a Molecular Spin Transistor; References; 5 Single-Molecule Magnet Spin-Transistor; 5.1 Mode of Operation; 5.2 Read-Out Quantum Dot. 5.3 Magneto-Conductance and Anisotropy5.4 Exchange Coupling; 5.5 2D Magneto-Conductance of the Read-Out Dot; 5.6 Electronic Spin Relaxation; 5.7 Quantum Tunneling of Magnetization; 5.8 Summary; References; 6 Nuclear Spin Dynamics -- T1; 6.1 Signal Analysis; 6.2 Relaxation Time T1 and Read-Out Fidelity F; 6.3 Quantum Monte Carlo Simulations; 6.3.1 Algorithm; 6.3.2 Including the Experimental Boundaries; 6.4 Comparison Experiment -- Simulation; 6.4.1 Relaxation Mechanism; 6.4.2 Dynamical Equilibrium; 6.4.3 Selection Rules; 6.5 Summary; References; 7 Nuclear Spin Dynamics -- Tast2; 7.1 Introduction. 7.1.1 Rabi Oscillations7.1.2 Hyperfine Stark Effect; 7.2 Coherent Nuclear Spin Rotations; 7.2.1 Frequency Calibration; 7.2.2 Rabi Oscillations; 7.3 Experimental Discussion of the Hyperfine Stark Effect; 7.3.1 DC Gate Voltage Induced Hyperfine Stark Effect; 7.3.2 AC Induced Hyperfine Stark Effect; 7.4 Theoretical Discussion of the Hyperfine Stark Effect; 7.5 Dephasing Time T*2; 7.5.1 Introduction; 7.5.2 Experimental Results; 7.5.3 Outlook; 7.6 Summary; References; 8 Conclusion and Outlook; References; Appendix ASpin; Appendix BStevens Operators; Appendix CQuantum Monte Carlo Code. … (more)
- Publisher Details:
- Cham : Springer
- Publication Date:
- 2016
- Copyright Date:
- 2016
- Extent:
- 1 online resource
- Subjects:
- 539.725
Physics
Nuclear spin
SCIENCE -- Physics -- Quantum Theory
Nuclear spin
Physics
Quantum Information Technology, Spintronics
Biological and Medical Physics, Biophysics
Nuclear Physics, Heavy Ions, Hadrons
Magnetism, Magnetic Materials
Science -- Life Sciences -- Biophysics
Science -- Nuclear Physics
Science -- Magnetism
Biophysics
Atomic & molecular physics
Electricity, electromagnetism & magnetism
Nuclear physics
Magnetism
Computers -- Information Technology
Quantum physics (quantum mechanics & quantum field theory)
Electronic books - Languages:
- English
- ISBNs:
- 9783319240589
3319240587 - Related ISBNs:
- 9783319240565
3319240560
9783319240565 - Notes:
- Note: Includes bibliographical references.
Note: Online resource; title from PDF title page (EBSCO, viewed December 16, 2015). - Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
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- Physical Locations:
- British Library HMNTS - ELD.DS.362465
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- 01_328.xml