论文信息 - The theory of oscillator-coupled magnetic resonance with potential applications to molecular imaging

The theory of oscillator-coupled magnetic resonance with potential applications to molecular imaging

This article describes systems in which the precession of a single particle spin is magnetically coupled to the excitation of an oscillator. The behavior of such systems resembles that of a ‘‘folded’’ Stern–Gerlach experiment, in which the linear spatial trajectory of the original Stern–Gerlach experiment is folded into the cyclic trajectory of an oscillator. Both quantum and semiclassical solutions to the equations of motion are derived. The results encompass any kind of oscillator which couples to a magnetic field. Examples include mechanical cantilevers with a magnetic source affixed to them, as well as inductor‐capacitor resonant circuits. One potential application of oscillator‐coupled magnetic resonance is the imaging of biological molecules. Some design issues relevant to molecular imaging are discussed.

[1] Mitchel Weissbluth,et al. Photon-Atom Interactions , 1989 .

[2] S. Iijima. Helical microtubules of graphitic carbon , 1991, Nature.

[3] Sandberg,et al. Shelved optical electron amplifier: Observation of quantum jumps. , 1986, Physical review letters.

[4] H. Carr,et al. The Principles of Nuclear Magnetism , 1961 .

[5] D. Rugar,et al. Mechanical parametric amplification and thermomechanical noise squeezing. , 1991, Physical review letters.

[6] V. E. Bottom. Introduction to Quartz Crystal Unit Design , 1982 .

[7] A. Messiah. Quantum Mechanics , 1961 .

[8] W. Zurek. The Environment, Decoherence and the Transition from Quantum to Classical , 1991 .

[9] Peter D. Kwong,et al. Crystal structure of an HIV-binding recombinant fragment of human CD4 , 1990, Nature.

[10] Myer Bloom,et al. THE TRANSVERSE STERN–GERLACH EXPERIMENT , 1962 .

[11] Sidles Ja,et al. Folded Stern-Gerlach experiment as a means for detecting nuclear magnetic resonance in individual nuclei. , 1992 .

[12] W. P. Mason. Electromechanical transducers and wave filters , 1942 .

[13] D. Rugar,et al. Frequency modulation detection using high‐Q cantilevers for enhanced force microscope sensitivity , 1991 .

[14] Frederick J. Milford,et al. Foundations of Electromagnetic Theory , 1961 .

[15] J. Sidles,et al. Noninductive detection of single‐proton magnetic resonance , 1991 .

[16] Paul Horowitz,et al. The Art of Electronics , 1980 .