Info
- Utilizzare la checkbox di selezione a fianco di ciascun documento per attivare le funzionalità di stampa, invio email, download nei formati disponibili del (i) record.
Circuits and Systems Advances in Near Threshold Computing
| Circuits and Systems Advances in Near Threshold Computing |
| Autore | Roy Sanghamitra |
| Pubbl/distr/stampa | Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 |
| Descrizione fisica | 1 electronic resource (120 p.) |
| Soggetto topico | Technology: general issues |
| Soggetto non controllato |
machine learning
neural networks gait analysis embedded system NTV NTC low-power low-voltage memory and clocking circuits minimum-energy design power-performance resilient adaptive computing edge devices power management energy efficiency near-threshold computing (NTC) deep neural network (DNN) accelerators timing error AI tensor processing unit (TPU) multiply and accumulate (MAC) reliability Near-Threshold Computing functional unit performance optimization cross-layer optimization |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910557367903321 |
Roy Sanghamitra
|
||
| Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Engineering Fluid Dynamics 2019-2020 : Volume 2
| Engineering Fluid Dynamics 2019-2020 : Volume 2 |
| Autore | Hjertager Bjørn |
| Pubbl/distr/stampa | Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 |
| Descrizione fisica | 1 electronic resource (202 p.) |
| Soggetto topico | History of engineering & technology |
| Soggetto non controllato |
CFD
gap resonance hydrodynamic forces free surface waves URANS twin-box deck aerodynamics vortex shedding splash lubrication dynamic motion gearbox churning power losses non-inertial coordinate system ground roughness hill shape hill slope large-eddy simulations turbulent flow fields turbulent structure computational fluid dynamics (CFD) large eddy simulations (LES) 3D hill canopy flow fields radiation blocked-off-region procedure heat recuperation anisotropic scattering mie particles numerical simulation horizontal face angle energy dissipation rates stepped spillway ultra-low specific speed magnetic drive pump orthogonal test splitter blades optimized design pressure fluctuation radial force dilution turbulent flame premixed OH CH2O planar laser-induced fluorescence self-excited oscillation jet organ–Helmholtz nozzle pulse waterjet pressure pulsation amplitude WMLES VLSMs LSMs turbulent boundary flow roughness surrogate model deep neural network multiphase flow horizontal pipe liquid holdup pressure gradient coherent structures turbulent boundary layer stability pre-multiplied wind velocity spectrum spatial correlation coefficient field tunnel fires jet fan speed heat release rate aspect ratio smoke movement visibility smoke layer thickness smoke stratification orifice shape vertical jet velocity ratio numerical investigation hydraulic characteristics impinging water jet impinging height numerical calculation swirler optimized genetic algorithms recirculation combustion experimental validation welding spatter distribution shield arc metal welding particle heat transfer fire risk sprinkler fire dynamics simulator (FDS) fire suppression extinguishing coefficient smoke logging smoke spread pipe insulation fire growth rate index scale factor volume fraction ignition heat source maximum heat release rate time to reach maximum HRR (heat release rate) control cylinder energy efficiency clamping pneumatics unsteady RANS simulation two-phase flow riser-induced slug flow LedaFlow VOF-model evacuation interaction between smoke and evacuees inner smoke force modified BR-smoke model twin H-rotor vertical-axis turbines wake instability wavelet transform computational fluid dynamics (CFD), multiphysics heat transfer thermoelectricity automotive traditional market fire spread rate radiant heat flux separation distance rotor stator interaction boundary layer secondary vortex unsteady flow submerged jet climate change renewable energy wind power accelerators turbines power extraction Betz freestream theory hybrid simulation method multi-fluid model discrete element method, sedimentation, bed formation PIV shell-and-tube shell side tube bundle heat exchanger baffle maldistribution |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Altri titoli varianti | Engineering Fluid Dynamics 2019-2020 |
| Record Nr. | UNINA-9910557117703321 |
|
Hjertager Bjørn
|
||
| Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Engineering Fluid Dynamics 2019-2020
| Engineering Fluid Dynamics 2019-2020 |
| Autore | Hjertager Bjørn |
| Pubbl/distr/stampa | Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 |
| Descrizione fisica | 1 electronic resource (384 p.) |
| Soggetto topico | History of engineering & technology |
| Soggetto non controllato |
CFD
gap resonance hydrodynamic forces free surface waves URANS twin-box deck aerodynamics vortex shedding splash lubrication dynamic motion gearbox churning power losses non-inertial coordinate system ground roughness hill shape hill slope large-eddy simulations turbulent flow fields turbulent structure computational fluid dynamics (CFD) large eddy simulations (LES) 3D hill canopy flow fields radiation blocked-off-region procedure heat recuperation anisotropic scattering mie particles numerical simulation horizontal face angle energy dissipation rates stepped spillway ultra-low specific speed magnetic drive pump orthogonal test splitter blades optimized design pressure fluctuation radial force dilution turbulent flame premixed OH CH2O planar laser-induced fluorescence self-excited oscillation jet organ–Helmholtz nozzle pulse waterjet pressure pulsation amplitude WMLES VLSMs LSMs turbulent boundary flow roughness surrogate model deep neural network multiphase flow horizontal pipe liquid holdup pressure gradient coherent structures turbulent boundary layer stability pre-multiplied wind velocity spectrum spatial correlation coefficient field tunnel fires jet fan speed heat release rate aspect ratio smoke movement visibility smoke layer thickness smoke stratification orifice shape vertical jet velocity ratio numerical investigation hydraulic characteristics impinging water jet impinging height numerical calculation swirler optimized genetic algorithms recirculation combustion experimental validation welding spatter distribution shield arc metal welding particle heat transfer fire risk sprinkler fire dynamics simulator (FDS) fire suppression extinguishing coefficient smoke logging smoke spread pipe insulation fire growth rate index scale factor volume fraction ignition heat source maximum heat release rate time to reach maximum HRR (heat release rate) control cylinder energy efficiency clamping pneumatics unsteady RANS simulation two-phase flow riser-induced slug flow LedaFlow VOF-model evacuation interaction between smoke and evacuees inner smoke force modified BR-smoke model twin H-rotor vertical-axis turbines wake instability wavelet transform computational fluid dynamics (CFD), multiphysics heat transfer thermoelectricity automotive traditional market fire spread rate radiant heat flux separation distance rotor stator interaction boundary layer secondary vortex unsteady flow submerged jet climate change renewable energy wind power accelerators turbines power extraction Betz freestream theory hybrid simulation method multi-fluid model discrete element method, sedimentation, bed formation PIV shell-and-tube shell side tube bundle heat exchanger baffle maldistribution |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910557503803321 |
|
Hjertager Bjørn
|
||
| Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Particle physics : an introduction / / Robert Purdy
| Particle physics : an introduction / / Robert Purdy |
| Autore | Purdy Robert |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Duxbury, Massachusetts : , : Mercury Learning and Information, , [2022] |
| Descrizione fisica | 1 online resource (441 pages) |
| Disciplina | 415 |
| Collana | Providing an Essential Overview of the Topic, These Books Provide a Concise Introduction to the Essential Fields of Physics |
| Soggetto topico | Particles (Nuclear physics) |
| Soggetto non controllato |
accelerators
atoms colliders detectors quarks string theory |
| ISBN |
1-68392-875-X
1-68392-876-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Half-Title -- Title -- Copyright -- Dedication -- Contents -- Introduction -- Chapter 1: A History of Particle Physics -- 1.1 Atomic Theory -- 1.2 Atomic Structure -- 1.3 Forces and Interactions -- 1.4 Strange and Unexpected Developments -- 1.5 Strangeness -- 1.6 Quarks and Symmetries -- 1.7 The Standard Model of Particle Physics -- 1.8 The Current State of the Field -- 1.9 Exercises -- Chapter 2: Special Relativity -- 2.1 Lorentz Transformations -- 2.1.1 Scalars, Vectors, and Reference Frames -- 2.1.2 Special Relativity -- 2.1.3 Minkowski Space -- 2.2 Energy and Momentum in Minkowski Space -- 2.2.1 Example Calculation -- 2.2.2 Invariant Mass -- 2.3 Exercises -- Chapter 3: Quantum Mechanics -- 3.1 States and Operators -- 3.2 The Schrödinger Equation -- 3.3 Probability Current -- 3.4 Angular Momentum and Spin -- 3.5 Spin 1/2 Particles and the Pauli Matrices -- 3.6 The Hamiltonian -- 3.6.1 The Lagrangian -- 3.7 Quantum Mechanics and Electromagnetism: The Schrödinger Approach -- 3.8 Quantum Mechanics and Electromagnetism: The Pauli Equation -- 3.9 Exercises -- Chapter 4: Symmetries and Groups -- 4.1 The Importance of Symmetry in Physics -- 4.2 Discrete Symmetries -- 4.2.1 Mathematical Structure of Discrete Symmetries -- 4.2.2 Discrete Symmetries in Particle Physics -- 4.3 Continuous Symmetries -- 4.3.1 Mathematical Structure of Continuous Symmetries -- 4.3.2 Continuous Symmetries in Particle Physics -- 4.4 Exercises -- Chapter 5: Experimental Particle Physics -- 5.1 Detectors -- 5.1.1 Interactions of Particles with Matter -- 5.1.2 Early Detectors -- 5.1.3 Modern Detectors -- 5.2 Accelerators -- 5.2.1 Linear Accelerators -- 5.2.2 Cyclotrons -- 5.2.3 Synchrotrons -- 5.3 Measurable Quantities in Particle Physics: Matching Theory to Experiment -- 5.3.1 Cross-Sections -- 5.3.2 Lifetimes -- 5.4 Exercises -- Chapter 6: Particle Classification.
6.1 The Spin-Statistics Theorem -- 6.2 The Strong Force -- 6.2.1 Isospin -- 6.2.2 Flavor SU (3) -- 6.3 Color -- 6.4 Building Hadrons -- 6.4.1 Quark Content -- 6.4.2 Mass -- 6.4.3 Resonances -- 6.4.4 Larger Flavor Symmetries -- 6.5 Exercises -- Chapter 7: Relativistic Quantum Mechanics -- 7.1 The Klein-Gordon Equation -- 7.1.1 A Relativistic Schrödinger Equation -- 7.1.2 Solutions of the Klein-Gordon Equation -- 7.1.3 Conserved Current -- 7.2 The Maxwell and Proca Equations -- 7.2.1 Derivation of the Maxwell Equation -- 7.2.2 Solutions of the Maxwell Equation -- 7.2.3 Including Mass: The Proca Equation -- 7.2.4 Spin of Vector Particles -- 7.3 Combining Equations: How Do Particles Interact? -- 7.3.1 Quantum Field Theory Without the Maths -- 7.3.2 Feynman Rules -- 7.4 Exercises -- Chapter 8: The Dirac Equation -- 8.1 A Linear Relativistic Equation -- 8.2 Representations of the Gamma Matrices -- 8.2.1 The Dirac Representation -- 8.2.2 The Weyl Representation -- 8.3 Spinors and Lorentz Transformations -- 8.4 Solutions of the Dirac Equation -- 8.4.1 Basis Spinors -- 8.4.2 Spin -- 8.4.3 Antiparticles -- 8.4.4 Helicity -- 8.4.5 Chirality -- 8.5 Massless Particles -- 8.6 Charge Conjugation -- 8.7 Dirac, Weyl, and Majorana Spinors -- 8.8 Bilinear Covariants -- 8.9 Exercises -- Chapter 9: Quantum Electrodynamics -- 9.1 U(1) Symmetry in Wave Equations -- 9.2 Localizing the U(1) Symmetry -- 9.3 The Link with Classical Physics -- 9.4 A Well-Tested Theory -- 9.5 Calculations in QED -- 9.5.1 Feynman Rules for QED -- 9.5.2 Calculating Amplitudes -- 9.5.3 Calculating the Differential Cross-Section -- 9.6 Beyond Leading Order: Renormalization -- 9.7 Form Factors and Structure Functions -- 9.7.1 Electromagnetic Form Factors -- 9.7.2 Structure Functions and the Quark Model -- 9.8 Exercises -- Chapter 10: Non-Abelian Gauge Theory and Color. 10.1 Non-Abelian Symmetry in the Dirac Equation -- 10.1.1 SU(3) and Color -- 10.1.2 Localizing the SU(3) Symmetry -- 10.2 Gluon Self-Interactions -- 10.3 Strong Force Interactions -- 10.3.1 Quantum Chromodynamics -- 10.3.2 Scale-Dependence -- 10.4 High-Energy QCD -- 10.4.1 Asymptotic Freedom -- 10.4.2 Perturbative QCD -- 10.5 Low-Energy QCD -- 10.5.1 Quark Confinement -- 10.5.2 The Residual Nuclear Force -- 10.5.3 Perturbative and Lattice QCD -- 10.6 Exotic Matter -- 10.6.1 Pentaquarks and Tetraquarks -- 10.6.2 Glueballs -- 10.6.3 Quark-Gluon Plasma -- 10.7 Exercises -- Chapter 11: Symmetry Breaking and The Higgs Mechanism -- 11.1 The Weak Force as a Boson-Mediated Interaction -- 11.1.1 P Violation -- 11.1.2 C Violation -- 11.2 Renormalizability and the Need for Symmetry -- 11.3 Hidden Symmetry -- 11.3.1 Toy Model 1: Z2 Symmetry Breaking -- 11.3.2 Toy Model 2: U(1) Symmetry Breaking -- 11.3.3 Local U(1) Symmetry Breaking -- 11.3.4 The Higgs Mechanism: SU(2) x U(1) Breaking -- 11.4 Electroweak Interactions -- 11.4.1 Hypercharge and Weak Isospin -- 11.5 Exercises -- Chapter 12: The Standard Model of Particle Physics -- 12.1 Putting It All Together -- 12.2 Fermion Masses -- 12.3 Quark Mixing and the CKM Matrix -- 12.3.1 The Cabibbo Hypothesis -- 12.3.2 Neutral Mesons -- 12.3.3 More General Quark Mixing -- 12.4 CP Violation in the Weak Sector -- 12.4.1 The Electron Electric Dipole Moment -- 12.5 Successes of the Standard Model -- 12.5.1 Anomaly Cancelation -- 12.6 Problems with the Standard Model -- 12.6.1 Baryogenesis -- 12.6.2 The Hierarchy Problem -- 12.6.3 The Muon Anomalous Magnetic Moment -- 12.6.4 The Strong CP Problem -- 12.7 Exercises -- Chapter 13: Beyond the Standard Model -- 13.1 Neutrino Oscillations and the PMNS Matrix -- 13.2 The See-Saw Mechanism -- 13.3 Grand Unification -- 13.3.1 SU(5) as an Example GUT -- 13.3.2 Magnetic Monopoles. 13.4 Supersymmetry -- 13.5 Problems with Standard Model Extensions -- 13.6 Gravitons -- 13.6.1 Can We Go Further Than Spin-2? -- 13.6.2 Problems with Gravity -- 13.7 Axions -- 13.8 Dark Matter -- 13.8.1 Axions -- 13.8.2 Sterile Neutrinos -- 13.8.3 Lightest Supersymmetric Particle -- 13.8.4 Something New -- 13.9 Dark Energy and Inflation -- 13.9.1 Inflation -- 13.9.2 Dark Energy -- 13.10 The Future of Particle Physics -- 13.11 Exercises -- Appendix A: Elementary Particle Properties and Other Useful Quantities -- Appendix B: Feynman Rules -- Appendix C: Gamma Matrix Identities -- Bibliography -- Index. |
| Record Nr. | UNINA-9910780583203321 |
|
Purdy Robert
|
||
| Duxbury, Massachusetts : , : Mercury Learning and Information, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Particle physics : an introduction / / Robert Purdy
| Particle physics : an introduction / / Robert Purdy |
| Autore | Purdy Robert |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Duxbury, Massachusetts : , : Mercury Learning and Information, , [2022] |
| Descrizione fisica | 1 online resource (441 pages) |
| Disciplina | 415 |
| Collana | Providing an Essential Overview of the Topic, These Books Provide a Concise Introduction to the Essential Fields of Physics |
| Soggetto topico | Particles (Nuclear physics) |
| Soggetto non controllato |
accelerators
atoms colliders detectors quarks string theory |
| ISBN |
1-68392-875-X
1-68392-876-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Half-Title -- Title -- Copyright -- Dedication -- Contents -- Introduction -- Chapter 1: A History of Particle Physics -- 1.1 Atomic Theory -- 1.2 Atomic Structure -- 1.3 Forces and Interactions -- 1.4 Strange and Unexpected Developments -- 1.5 Strangeness -- 1.6 Quarks and Symmetries -- 1.7 The Standard Model of Particle Physics -- 1.8 The Current State of the Field -- 1.9 Exercises -- Chapter 2: Special Relativity -- 2.1 Lorentz Transformations -- 2.1.1 Scalars, Vectors, and Reference Frames -- 2.1.2 Special Relativity -- 2.1.3 Minkowski Space -- 2.2 Energy and Momentum in Minkowski Space -- 2.2.1 Example Calculation -- 2.2.2 Invariant Mass -- 2.3 Exercises -- Chapter 3: Quantum Mechanics -- 3.1 States and Operators -- 3.2 The Schrödinger Equation -- 3.3 Probability Current -- 3.4 Angular Momentum and Spin -- 3.5 Spin 1/2 Particles and the Pauli Matrices -- 3.6 The Hamiltonian -- 3.6.1 The Lagrangian -- 3.7 Quantum Mechanics and Electromagnetism: The Schrödinger Approach -- 3.8 Quantum Mechanics and Electromagnetism: The Pauli Equation -- 3.9 Exercises -- Chapter 4: Symmetries and Groups -- 4.1 The Importance of Symmetry in Physics -- 4.2 Discrete Symmetries -- 4.2.1 Mathematical Structure of Discrete Symmetries -- 4.2.2 Discrete Symmetries in Particle Physics -- 4.3 Continuous Symmetries -- 4.3.1 Mathematical Structure of Continuous Symmetries -- 4.3.2 Continuous Symmetries in Particle Physics -- 4.4 Exercises -- Chapter 5: Experimental Particle Physics -- 5.1 Detectors -- 5.1.1 Interactions of Particles with Matter -- 5.1.2 Early Detectors -- 5.1.3 Modern Detectors -- 5.2 Accelerators -- 5.2.1 Linear Accelerators -- 5.2.2 Cyclotrons -- 5.2.3 Synchrotrons -- 5.3 Measurable Quantities in Particle Physics: Matching Theory to Experiment -- 5.3.1 Cross-Sections -- 5.3.2 Lifetimes -- 5.4 Exercises -- Chapter 6: Particle Classification.
6.1 The Spin-Statistics Theorem -- 6.2 The Strong Force -- 6.2.1 Isospin -- 6.2.2 Flavor SU (3) -- 6.3 Color -- 6.4 Building Hadrons -- 6.4.1 Quark Content -- 6.4.2 Mass -- 6.4.3 Resonances -- 6.4.4 Larger Flavor Symmetries -- 6.5 Exercises -- Chapter 7: Relativistic Quantum Mechanics -- 7.1 The Klein-Gordon Equation -- 7.1.1 A Relativistic Schrödinger Equation -- 7.1.2 Solutions of the Klein-Gordon Equation -- 7.1.3 Conserved Current -- 7.2 The Maxwell and Proca Equations -- 7.2.1 Derivation of the Maxwell Equation -- 7.2.2 Solutions of the Maxwell Equation -- 7.2.3 Including Mass: The Proca Equation -- 7.2.4 Spin of Vector Particles -- 7.3 Combining Equations: How Do Particles Interact? -- 7.3.1 Quantum Field Theory Without the Maths -- 7.3.2 Feynman Rules -- 7.4 Exercises -- Chapter 8: The Dirac Equation -- 8.1 A Linear Relativistic Equation -- 8.2 Representations of the Gamma Matrices -- 8.2.1 The Dirac Representation -- 8.2.2 The Weyl Representation -- 8.3 Spinors and Lorentz Transformations -- 8.4 Solutions of the Dirac Equation -- 8.4.1 Basis Spinors -- 8.4.2 Spin -- 8.4.3 Antiparticles -- 8.4.4 Helicity -- 8.4.5 Chirality -- 8.5 Massless Particles -- 8.6 Charge Conjugation -- 8.7 Dirac, Weyl, and Majorana Spinors -- 8.8 Bilinear Covariants -- 8.9 Exercises -- Chapter 9: Quantum Electrodynamics -- 9.1 U(1) Symmetry in Wave Equations -- 9.2 Localizing the U(1) Symmetry -- 9.3 The Link with Classical Physics -- 9.4 A Well-Tested Theory -- 9.5 Calculations in QED -- 9.5.1 Feynman Rules for QED -- 9.5.2 Calculating Amplitudes -- 9.5.3 Calculating the Differential Cross-Section -- 9.6 Beyond Leading Order: Renormalization -- 9.7 Form Factors and Structure Functions -- 9.7.1 Electromagnetic Form Factors -- 9.7.2 Structure Functions and the Quark Model -- 9.8 Exercises -- Chapter 10: Non-Abelian Gauge Theory and Color. 10.1 Non-Abelian Symmetry in the Dirac Equation -- 10.1.1 SU(3) and Color -- 10.1.2 Localizing the SU(3) Symmetry -- 10.2 Gluon Self-Interactions -- 10.3 Strong Force Interactions -- 10.3.1 Quantum Chromodynamics -- 10.3.2 Scale-Dependence -- 10.4 High-Energy QCD -- 10.4.1 Asymptotic Freedom -- 10.4.2 Perturbative QCD -- 10.5 Low-Energy QCD -- 10.5.1 Quark Confinement -- 10.5.2 The Residual Nuclear Force -- 10.5.3 Perturbative and Lattice QCD -- 10.6 Exotic Matter -- 10.6.1 Pentaquarks and Tetraquarks -- 10.6.2 Glueballs -- 10.6.3 Quark-Gluon Plasma -- 10.7 Exercises -- Chapter 11: Symmetry Breaking and The Higgs Mechanism -- 11.1 The Weak Force as a Boson-Mediated Interaction -- 11.1.1 P Violation -- 11.1.2 C Violation -- 11.2 Renormalizability and the Need for Symmetry -- 11.3 Hidden Symmetry -- 11.3.1 Toy Model 1: Z2 Symmetry Breaking -- 11.3.2 Toy Model 2: U(1) Symmetry Breaking -- 11.3.3 Local U(1) Symmetry Breaking -- 11.3.4 The Higgs Mechanism: SU(2) x U(1) Breaking -- 11.4 Electroweak Interactions -- 11.4.1 Hypercharge and Weak Isospin -- 11.5 Exercises -- Chapter 12: The Standard Model of Particle Physics -- 12.1 Putting It All Together -- 12.2 Fermion Masses -- 12.3 Quark Mixing and the CKM Matrix -- 12.3.1 The Cabibbo Hypothesis -- 12.3.2 Neutral Mesons -- 12.3.3 More General Quark Mixing -- 12.4 CP Violation in the Weak Sector -- 12.4.1 The Electron Electric Dipole Moment -- 12.5 Successes of the Standard Model -- 12.5.1 Anomaly Cancelation -- 12.6 Problems with the Standard Model -- 12.6.1 Baryogenesis -- 12.6.2 The Hierarchy Problem -- 12.6.3 The Muon Anomalous Magnetic Moment -- 12.6.4 The Strong CP Problem -- 12.7 Exercises -- Chapter 13: Beyond the Standard Model -- 13.1 Neutrino Oscillations and the PMNS Matrix -- 13.2 The See-Saw Mechanism -- 13.3 Grand Unification -- 13.3.1 SU(5) as an Example GUT -- 13.3.2 Magnetic Monopoles. 13.4 Supersymmetry -- 13.5 Problems with Standard Model Extensions -- 13.6 Gravitons -- 13.6.1 Can We Go Further Than Spin-2? -- 13.6.2 Problems with Gravity -- 13.7 Axions -- 13.8 Dark Matter -- 13.8.1 Axions -- 13.8.2 Sterile Neutrinos -- 13.8.3 Lightest Supersymmetric Particle -- 13.8.4 Something New -- 13.9 Dark Energy and Inflation -- 13.9.1 Inflation -- 13.9.2 Dark Energy -- 13.10 The Future of Particle Physics -- 13.11 Exercises -- Appendix A: Elementary Particle Properties and Other Useful Quantities -- Appendix B: Feynman Rules -- Appendix C: Gamma Matrix Identities -- Bibliography -- Index. |
| Record Nr. | UNINA-9910807335203321 |
|
Purdy Robert
|
||
| Duxbury, Massachusetts : , : Mercury Learning and Information, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Polymer Processing and Surfaces
| Polymer Processing and Surfaces |
| Autore | Sedlačík Michal |
| Pubbl/distr/stampa | Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 |
| Descrizione fisica | 1 electronic resource (436 p.) |
| Soggetto topico |
Research & information: general
Biology, life sciences |
| Soggetto non controllato |
thermoplastic polyurethanes blends
pressure sensitive adhesives viscoelastic properties adhesion properties tack creep cohesion properties nano-structure functional film magnetron sputtering cellulose insulation polymer space charge hydrophobicity zinc oxide polytetrafluoroethylene bromoisobutyryl esterification cornstarch synthesis process past stability adhesion film properties mullite whiskers nonaqueous precipitation method aluminum fluoride polar transformation screw aspect ratio carbon nanotube dispersion masterbatch nanocomposite polyamide polyamide 6 halloysite nanotube functionalizing agent in situ polymerization melt blending polymorphism hydrothermal ageing polymers octaglycidyl-POSS DGEBA dicyandiamide accelerators corrosion protective coatings infrared spectroscopy rheology poplar wood waterborne UV lacquer product wood modification contact angle spectroscopy super-hydrophobic coating elastic sensor carbon nanotubes wearable electronics monitoring of breathing strain sensor polymer composite CNTs construction composite friction resistance surface state low dielectric constant PI irradiation dielectric loss tin compounds valsartan poly(vinyl chloride) additives average molecular weight weight loss functional group index PET polymer plasma jet tilted application ROS distribution UV VUV epoxy Joule heating fast curing accelerated forming shape memory Acrylonitrile Butadiene Styrene sound absorption 3D printing technology frequency thickness air gap polyvinyl alcohol cationic polyacrylamide polyvinyl chloride azodicarbonamide micro-structure diffusion plate micro injection molding grinding ethylene-octene-copolymer carbon fibers polyaniline polypyrrole thermoelectric composites surface coating dopamine hydrochloride graphene oxide surgical suture friction Poly(vinylidene chloride-co-acrylonitrile) (P(VDC-co-AN )) thermo-dynamic surface characterization surface free energy inverse gas chromatography visual traits computer vision and image processing basalt fiber epoxy composite glass transition temperature DMA TMA creep recovery stress-relaxation heterogeneous nucleation cell morphology injection molding foaming composite materials visualization gloss transition defect surface defect surface gloss shrinkage mold surface replication surface analysis injection molding polymer surface modification hydrophobic properties optimization mathematical modeling poly(ethylene glycol) (PEG) conjugation N,N′-disuccinimidyl carbonate (DSC) immobilization surface modification ultra-high molecular weight polyethylene cellulose nanofiber bionanocomposite melt-blending ethanol mixing |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910566465503321 |
|
Sedlačík Michal
|
||
| Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||