The ROP and the GLP in the Bethe Lattice
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概要
- 論文の詳細を見る
- 理論物理学刊行会の論文
- 1977-11-25
著者
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MUTO Shunichi
Department of Applied Physics, Hokkaido University
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MUTO Shunichi
Department of Physics, Tokyo Institute of Technology
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Muto Shunichi
Department of Applied Physics, Hokkaido Univercity, Sapporo 060-8628, Japan
関連論文
- Lattice Deformation and Ga Diffusion Concerning InAs Self-Assembled Quantum Dots on GaAs(100) as a Function of Growth Interruption Time
- InAs Self-Assembled Quantum Dots Coupled with GaSb Monolayer Quantum Well
- Crystallographic Properties of Closely Stacked InAs Quantum Dots Investigated by Ion Channeling
- Threading Dislocations in Multilayer Structure of InAs Self-Assembled Quantum Dots
- Interdiffusion between InAs Quantum Dots and GaAs Matrices
- Electron Spin-relaxation Dynamics in GaAs/AlGaAs Quantum Wells and InGaAs/InP Quantum Wells
- Indium Adatom Migration in InAs/GaAs Quantum-Dot Growth
- Photon Antibunching Observed from an InAlAs Single Quantum Dot
- Spin Depolarization via Tunneling Effects in Asymmetric Double Quantum Dot Structure
- Quantum Gates Based on Electron Spins of Triple Quantum Dot
- An Approximate Method for Incommensurate Phase Transitions and Its Application to NaNO_2
- Exchange Interaction of Optically Created Electrons in Coupled Quantum Dots
- The ROP and the GLP in the Bethe Lattice
- Ising Model on the Bethe Lattice with Competing Interactions
- One-Dimensional Random Annealed Ising Spin System on the Site Model
- Ising Model on the Twin Cayley Tree
- Magnetization of Each Site in Ising Model under Weak Field on the Cayley Tree
- Photon Antibunching Observed from an InAlAs Single Quantum Dot
- Spin Depolarization via Tunneling Effects in Asymmetric Double Quantum Dot Structure
- Quantum Gates Based on Electron Spins of Triple Quantum Dot
- Transition from Excitonic Tunneling to Free Carrier Tunneling in GaAs/AlGaAs Double Quantum Wells
- Peculiar Field-Cycle Dependence of Magnetization Observed for Poly(phenyl)acetylene Prepared with a Rh Complex Catalyst
- Fiber-Based Bidirectional Solid-State Single-Photon Emitter Based on Semiconductor Quantum Dot
- Fiber-Based Bidirectional Solid-State Single-Photon Emitter Based on Semiconductor Quantum Dot