Singapore : , : Springer Nature Singapore : , : Imprint : Springer, , 2023

9789819957804

981995780X

1 online resource (VIII, 73 p. 35 illus., 34 illus. in color.)

SpringerBriefs in Materials, , 2192-1105

620.19

Materials

Detectors

Chemical detectors

Sensors and biosensors

Materials Engineering

Sensors

Inglese

Includes bibliographical references.

1. Printed Strain Sensor -- 2. Carbon conductive ink-based Printed Strain Sensor -- 3. Metal conductive ink -based Printed Strain Sensor -- 4. Composites and Hybrid conductive ink-based Printer Strain Sensor -- 5. Performance evaluation of Printed Strain Sensor.

This book reviews different types of nanomaterials-based-conductive inks used to develop printed strain sensors, printing fabrication methods, and applications such as wearable health monitoring. Printed wearable electronic devices have recently drawn a lot of attention, as shown by the increasing number of publications and commercialized devices covering various facets in emerging fields. Many researchers are working toward optimizing nanoparticle-based-conductive inks for wearable electronics. However, issues related to its stability, dispersion, and annealing temperature often limit its applications. General important information and requirements of flexible electronics for health monitoring are covered in the book chapter. The target audiences are researchers and students who are involved in the development of printed wearable electronics.

Cham : , : Springer Nature Switzerland : , : Imprint : Springer, , 2024

3-031-66477-9

1 online resource (188 pages)

621.382

Telecommunication

Quantum computers

Computers

Cryptography

Data encryption (Computer science)

Communications Engineering, Networks

Quantum Computing

Hardware Performance and Reliability

Cryptology

Inglese

Chapter 1. Trapped Ion Quantum Computing -- Chapter 2. Superconducting Quantum Computing -- Chapter 3. Photonic Quantum Computing -- Chapter 4. Bose – Einstein Condensate -- Chapter 5. Nitrogen Vacancy Centers -- Chapter 6. Nuclear Magnetic Resonance Quantum Computing -- Chapter 7. Electron Based Quantum Computing -- Chapter 8. Fullerene Based Quantum Computers -- Chapter 9. D-Wave and Adiabatic Quantum Computing -- Chapter 10. Topological Quantum Computing -- Chapter 11. Neutral Atom Based Quantum Computing -- Chapter 12. Reducing Noise and Error Correcting.

This book covers extensively the physical implementation of qubits and quantum architecture. The author demonstrates how quantum computing is implemented by the underlying physical implementation of qubits, including trapped ions, nitrogen vacancy centers, frozen neon, and other implementations. The book shows how, ultimately, the

physical implementation of the qubit is the foundation of quantum computing, and that the choice of physical qubit will impact such things as decoherence times, computational efficiency, and even error rate. The book explores all the current approaches to physical qubit implementation and includes appendices that review basic quantum computing and physics. Describes the physical implementation of qubits including trapped ion, superconducting, neutral atom, and others. Covers the physical implementation of qubits Includes appendices that review basic quantum computing and physics.