Fluctuation Mechanisms in Superconductors : Nanowire Single-Photon Counters, Enabled by Effective Top-Down Manufacturing / / by Holger Bartolf
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| Autore: |
Bartolf Holger
|
| Titolo: |
Fluctuation Mechanisms in Superconductors : Nanowire Single-Photon Counters, Enabled by Effective Top-Down Manufacturing / / by Holger Bartolf
|
| Pubblicazione: | Wiesbaden : , : Springer Fachmedien Wiesbaden : , : Imprint : Springer Spektrum, , 2016 |
| Edizione: | 1st ed. 2016. |
| Descrizione fisica: | 1 online resource (336 p.) |
| Disciplina: | 530 |
| Soggetto topico: | Mathematical physics |
| Nanotechnology | |
| Theoretical, Mathematical and Computational Physics | |
| Note generali: | Description based upon print version of record. |
| Nota di bibliografia: | Includes bibliographical references and index. |
| Nota di contenuto: | Preface - Vortex-Fluctuation and Single-Photon Detection with a Nanowire; Physical Background; Personal Remarks; The Scope and Organization of this Book; Acknowledgment, Motivation and Funding; References; Contents; Chapter 1 Introduction; 1.1 Quantum Nature and its Detection; 1.1.1 Thermal Detectors; 1.1.2 Ionization Detectors; 1.2 Cryogenic Quantum Detectors at the Beginning of the 21st Century; 1.2.1 Transition-Edge Sensors TES; 1.2.2 Kinetic-Inductance Detectors KID; 1.2.3 Superconducting Tunnel Junction Detectors STJD; 1.2.4 Superconducting Nanowire Single-Photon Detectors SNSPD |
| ReferencesPart I Nanoscale Manufacturing Process Developments; Chapter 2 Considerations for Nanoscale Manufacturing; Chapter 3 Superconducting Thin-Film Preparation; 3.1 DC-Magnetron Sputtering; 3.1.1 The Physics of a DC Plasma Discharge; 3.1.2 Magnetron Sputtering of NbN Thin Films; 3.1.3 Magnetron Sputtering of Additional Superconducting Films; 3.2 Electron-Beam Evaporation; References; Chapter 4 Nanoscale-Precise Coordinate System: Scalable, GDSII-Design; 4.1 Process Layers; 4.2 Structure References; References; Chapter 5 Thin-Film Structuring | |
| 5.1 Easy and Effective Nanoscaled Top-Down Manufacturing5.2 Organic Resists; 5.2.1 Resist Properties; 5.2.2 Resist Fabrication: Spin Coating; 5.3 Microscale Fabrication: Contact Photolithography; 5.3.1 Principle of Photolithography; 5.3.2 Physical Limit of Contact Photolithography; 5.3.3 Perfect Contact Utilizing Newton's Interference Rings; 5.3.4 Additive and Subtractive Lithographic Pattern Transfer; 5.3.5 Alignment Structures; 5.3.6 Controlling the Undercut during Development; 5.3.7 Critical Dimensions & Resist Profile ; 5.4 Nanoscale Fabrication: Electron-Beam Lithography | |
| 5.4.1 The Electron-Matter Interaction5.4.2 Discrete Beam-Deflection, Exposure Dose and Dynamic Effects; 5.4.3 Alignment of the Stage Relative to the Beam; 5.4.4 Clearing-Dose Determination (PMMA950 k); 5.4.5 PMMA950 k to Obtain a Lift-Off Profile: Critical Dimension 10nm; 5.4.6 Proximity Effect Model(s); 5.4.7 Simulated Proximity-Effect Correction; 5.4.8 Manufacturing in the Sub - 100nm RegimeWithout Correction for the Proximity Effect; 5.4.9 ZEP 520A Etch Protection Layer: Critical Dimension 60nm; 5.5 Symbiotic Optimization of the Nanolithography and RF-Plasma Etching | |
| 5.6 Reactive Ion Etching5.6.1 Proper Operation of the Radio-Frequency Discharge; 5.6.2 Etching Rate Determination; 5.6.3 Etched Photolithographic Critical Dimensions; 5.7 The 50nm Scale Compared to the Bit-Pattern on a Compact-Disk; Appendix 5.1: Phenomenological Electron-Beam Proximity Effect; Appendix 5.2: CASINO: Monte Carlo Simulation of the Electron-Matter Interaction; References; Chapter 6 Device Manufacturing; 6.1 Fabrication Process Chains; 6.2 Postfabrication Procedures: Sawing & Wire Bonding; 6.3 Manufacturing Twenty Devices in One Run: Small Scale Production; References | |
| Chapter 7 Proof of Principle of the Above Described Approach | |
| Sommario/riassunto: | Holger Bartolf discusses state-of-the-art detection concepts based on superconducting nanotechnology as well as sophisticated analytical formulæ that model dissipative fluctuation-phenomena in superconducting nanowire single-photon detectors. Such knowledge is desirable for the development of advanced devices which are designed to possess an intrinsic robustness against vortex-fluctuations and it provides the perspective for honorable fundamental science in condensed matter physics. Especially the nanowire detector allows for ultra-low noise detection of signals with single-photon sensitivity and GHz repetition rates. Such devices have a huge potential for future technological impact and might enable unique applications (e.g. high rate interplanetary deep-space data links from Mars to Earth). Contents Superconducting Single-Photon Detectors Nanotechnological Manufacturing; Scale: 10 Nanometer Berezinskii-Kosterlitz Thouless (BKT) Transition, Edge-Barrier, Phase Slips Target Groups Researchers and students of physics in the fields of single-photon devices, nanofabrication, nanophotonics, nanoelectronics and superconductivity Industrial practitioners with focus on nanotechnology and single-photon detectors About the Author Holger Bartolf studied Solid State Physics at the Universities of Karlsruhe and Zürich. In 2011 he relocated at the Swiss Corporate Research Center of a leading company in power and automation technologies where his current interests focus on the applied R&D of the next generation of power semiconductors. |
| Titolo autorizzato: | Fluctuation Mechanisms in Superconductors |
| ISBN: | 3-658-12246-3 |
| Formato: | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione: | Inglese |
| Record Nr.: | 9910254607103321 |
| Lo trovi qui: | Univ. Federico II |
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