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Details
Table of Contents
Intro
Editorial Board
Editor-in-Chief
Associate Editors
Editors
Preface to the Series
Preface
Contents
Contributors
Project Overview
1 Introduction
1.1 Overall Scientific Objectives
1.2 Key Scientific Issues
2 Project Layout
2.1 Project Deployment
2.2 Comprehensive Integration and Interdisciplinary Efforts
3 Significant Progress
References
Research in China and Abroad
1 Research Status and Trends
1.1 Evolvement of Materials Preparation Techniques and New Materials: Constraints
1.2 Development of New Experimental Techniques and Theoretical Tools: Determining Situation
1.3 Major Scientific Issues and Major Application Problems: Power Source
2 Research Directions
2.1 Preparation and Construction of Quantum Materials
2.2 Single-Quantum-State Detection Techniques
2.3 Major Breakthroughs on Scientific Issues
References
Major Research Achievements
1 Exploration of New Phenomena, Theories, and Concepts of Single Quantum States
1.1 Iron-Based High-Temperature Superconductors and Interfacial Superconductors
1.2 Quantum States at Single-Molecule and Submolecule Scales
1.3 Full Quantum Effect of Water in Surface Reactions
1.4 Preparation and Control of Topological Quantum States
1.5 New Superconducting Qubits and Related Macroscopic Quantum Phenomena
1.6 Electronic and Spin Structures of Topological Insulators Investigated by Laser-Based Spin-Resolved Photoemission Spectroscopy
1.7 Interaction and Quantum Manipulation of Nuclear Spin Systems
1.8 Control of Topologically Protected Macroscopic Quantum States
2 New Techniques and Methods of Single Quantum States
2.1 Manipulation, Transformation, and Decoherence of Single Collective Excitations in Cold Atomic Ensembles
2.2 Detection and Coherence Manipulation of Superconducting Qubits and Integrated Solid-State Qubits
2.3 Dynamic Detection and Control of Single-Molecule Quantum Photonic States
2.4 Experimental Manipulation and Detection of Single Electron Spins at Room Temperature
2.5 Ultrafast and Hypersensitive Detection and Manipulation of Single Quantum States
2.6 New Techniques and Methods for Near-Infrared Single-Photon Detection and Imaging
2.7 Semiconductor Infrared Up-Conversion Single-Photon Detection
2.8 Single-Photon Detection and Device Fabrication of Microcavities and Single Quantum Dots
2.9 Optical Superlattices and Micro-Nano Structured Photonic Chips
2.10 Single-Photon Sensitive Detection, Precise Spectral Measurement, and Photon Control in Micro-Nano Structures
2.11 Single-Photon Detection and Circularly Polarized Emission Manipulated with Quantum Dots
3 Purification and Construction of Single-Quantum-State Systems
Editorial Board
Editor-in-Chief
Associate Editors
Editors
Preface to the Series
Preface
Contents
Contributors
Project Overview
1 Introduction
1.1 Overall Scientific Objectives
1.2 Key Scientific Issues
2 Project Layout
2.1 Project Deployment
2.2 Comprehensive Integration and Interdisciplinary Efforts
3 Significant Progress
References
Research in China and Abroad
1 Research Status and Trends
1.1 Evolvement of Materials Preparation Techniques and New Materials: Constraints
1.2 Development of New Experimental Techniques and Theoretical Tools: Determining Situation
1.3 Major Scientific Issues and Major Application Problems: Power Source
2 Research Directions
2.1 Preparation and Construction of Quantum Materials
2.2 Single-Quantum-State Detection Techniques
2.3 Major Breakthroughs on Scientific Issues
References
Major Research Achievements
1 Exploration of New Phenomena, Theories, and Concepts of Single Quantum States
1.1 Iron-Based High-Temperature Superconductors and Interfacial Superconductors
1.2 Quantum States at Single-Molecule and Submolecule Scales
1.3 Full Quantum Effect of Water in Surface Reactions
1.4 Preparation and Control of Topological Quantum States
1.5 New Superconducting Qubits and Related Macroscopic Quantum Phenomena
1.6 Electronic and Spin Structures of Topological Insulators Investigated by Laser-Based Spin-Resolved Photoemission Spectroscopy
1.7 Interaction and Quantum Manipulation of Nuclear Spin Systems
1.8 Control of Topologically Protected Macroscopic Quantum States
2 New Techniques and Methods of Single Quantum States
2.1 Manipulation, Transformation, and Decoherence of Single Collective Excitations in Cold Atomic Ensembles
2.2 Detection and Coherence Manipulation of Superconducting Qubits and Integrated Solid-State Qubits
2.3 Dynamic Detection and Control of Single-Molecule Quantum Photonic States
2.4 Experimental Manipulation and Detection of Single Electron Spins at Room Temperature
2.5 Ultrafast and Hypersensitive Detection and Manipulation of Single Quantum States
2.6 New Techniques and Methods for Near-Infrared Single-Photon Detection and Imaging
2.7 Semiconductor Infrared Up-Conversion Single-Photon Detection
2.8 Single-Photon Detection and Device Fabrication of Microcavities and Single Quantum Dots
2.9 Optical Superlattices and Micro-Nano Structured Photonic Chips
2.10 Single-Photon Sensitive Detection, Precise Spectral Measurement, and Photon Control in Micro-Nano Structures
2.11 Single-Photon Detection and Circularly Polarized Emission Manipulated with Quantum Dots
3 Purification and Construction of Single-Quantum-State Systems