This book is the first to address a new generation of analytical tools based on new superconductor detectors demonstrating outstanding performance unsurpassed by any other conventional devices. Presenting the latest research and development in nanometer technologies and biochemistry this book:
- Discusses the development of nuclear sensing techniques.
- Provides guidance on the design and use of the next generation of detectors.
- Describes cryogenic detectors for nuclear measurements and spectrometry.
- Covers primary detectors, front–end readout electronics and digital signal processing.
- Presents applications in nanotechnology and modern biochemistry including DNA sequencing, proteinomics, microorganisms.
- Features examples of two applications in X–ray electron probe nanoanalysis and time–of–flight mass spectrometry.
This comprehensive treatment is the ideal reference for researchers, industrial engineers and graduate students involved in the development of high precision nuclear measurements, nuclear analytical instrumentation and advanced superconductor primary sensors. This book will also appeal to physicists, electrical and electronic engineers in the nuclear industry.
1. Detection Methods with Cryogenic Particle and Radiation Sensors.
1.1 Quasiparticle detectors. Interaction of nuclear radiation with superconductors.
1.2 Superconducting tunnel junction (STJ) detectors.
1.3 Microcalorimeters based on transition edge sensors (TES).
1.4 Other cryogenic detectors.
Chapter 2. Front–end Read–out Electronic Circuits.
2.1 FET transconductance preamplifiers.
2.2 Dynamics and noise of JFET amplifiers.
2.3 SQUID current amplifiers.
2.4 SQUID control electronics.
2.5 SQUID amplifier in the small signal limit (noise).
2.6 SQUID current amplifier in the large signal limit (dynamics).
2.7 SQUID current amplifier at ultra low temperature.
2.8 SQUID voltage amplifier.
Chapter 3. Energy Resolution (FWHM) of Superconducting Detectors.
3.1 Signal–to–noise ratio, equivalent noise charge and noise linewidth of nucleonic channels. General information.
3.2 Signal–to–noise ratio, energy resolution at FWHM of STJ detectors.
3.3 Noise equivalent power, energy resolution at FWHM of TES microcalorimeters.
3.4 Dynamics and noise of time variant spectrometers.
3.5 Signal–to–Noise ratio of detector arrays with multiplexed readout.
Chapter 4. Pulse Processing Electronics.
4.1 Pulse processing techniques.
4.2 Analogue–to–digital conversion.
4.3 Digital rise (fall) time discrimination.
4.4 Superconductor digital spectrometer.
4.5 Selected topics on the hardware design.
Chapter 5. Applications of Systems Based on Superconducting Detectors.
5.1 Electron–Probe Nanoanalysis with cryogenic detectors.
5.2 Biopolymer mass spectrometer.
Chapter 6. Selected Topics of Analysis and Synthesis of Detector Systems.
6.1 Analogue electronic circuitry analysis and design principles.
6.2 Discrete–time systems and Systems with periodically changing parameters.
6.3 Inductance calculations of the superconducting structures.