SCIENTIFIC REPORTS, ISSN 2045-2322, 04/2016, Volume 6, Issue 1, p. 25157

Coherent transport phenomena are difficult to observe due to several sources of decoherence. For instance, in the electronic transport through quantum devices...

CONDUCTANCE | MULTIDISCIPLINARY SCIENCES | Impurities | Temperature effects

CONDUCTANCE | MULTIDISCIPLINARY SCIENCES | Impurities | Temperature effects

Journal Article

The European Physical Journal Special Topics, ISSN 1951-6355, 2/2017, Volume 226, Issue 3, pp. 519 - 527

Based on recent results of the joint moments of proper delay times of open chaotic systems with ideal coupling, a new insight to obtain the partial delay times...

Condensed Matter Physics | Measurement Science and Instrumentation | Materials Science, general | Classical and Continuum Physics | Atomic, Molecular, Optical and Plasma Physics | Physics, general | Physics | MATRIX | TRANSPORT | PHASE-SHIFTS | SMALL CONDUCTORS | PHYSICS, MULTIDISCIPLINARY | STATISTICS | PARAMETRIC CORRELATIONS | SCATTERING | Physics - Mesoscale and Nanoscale Physics

Condensed Matter Physics | Measurement Science and Instrumentation | Materials Science, general | Classical and Continuum Physics | Atomic, Molecular, Optical and Plasma Physics | Physics, general | Physics | MATRIX | TRANSPORT | PHASE-SHIFTS | SMALL CONDUCTORS | PHYSICS, MULTIDISCIPLINARY | STATISTICS | PARAMETRIC CORRELATIONS | SCATTERING | Physics - Mesoscale and Nanoscale Physics

Journal Article

The European Physical Journal Special Topics, ISSN 1951-6355, 2/2017, Volume 226, Issue 3, pp. 417 - 425

We take advantage of a recently established equivalence, between the intermittent dynamics of a deterministic nonlinear map and the scattering matrix...

Condensed Matter Physics | Measurement Science and Instrumentation | Materials Science, general | Classical and Continuum Physics | Atomic, Molecular, Optical and Plasma Physics | Physics, general | Physics | PHYSICS, MULTIDISCIPLINARY | Physics - Disordered Systems and Neural Networks

Condensed Matter Physics | Measurement Science and Instrumentation | Materials Science, general | Classical and Continuum Physics | Atomic, Molecular, Optical and Plasma Physics | Physics, general | Physics | PHYSICS, MULTIDISCIPLINARY | Physics - Disordered Systems and Neural Networks

Journal Article

2011 North American Power Symposium, 08/2011, pp. 1 - 7

The restructuring of energy markets has increased the concern about the existing interdependency between the primary energy supply and electricity networks,...

lbmol °R | Active load ratio modeled as constant impedance | Pipelines | HP | Generated active power for case base at i | Gas extracted from the k | Reactive load ratio modeled as constant current | inches | Reactive power characteristic for the i | rad | Heat transfer coeff. at pipe from k to m | Natural gas load at k | Cp Gas heat capacity at constant pressure | Load modeling | gross heating value | 28.96 | П | and γ | Total natural gas injected by pipelines and compressors at k | Reactive load ratio modeled as constant impedance | SCFD | ) | State variables for the natural gas system | Conductance of the nodal admittance matrix | node | Number of natural gas loads from the node k | Compressor's gas consumption coefficients | Base value of pressure | Pipe's outlet elevation | ΔP | ΔQ | Natural gas | Qr | Natural gas injection at k | Joule-Thompson coefficient | D | E | G | Voltage angle at i | H | Mass of natural gas | X State variables for the coupled system | Thermal functions vector | L | N | ŏ | P | sec | Q | R/PSIA | Nodes in the electrical system | R | T | U | V | Rate active power for the i | Z | Heat rate coefficients for coupled nodes | BTU/SCF | a | b | ƒ Darcy-Weisbach friction factor | c | Load reactive power for case base at the i | Pipe's natural gas mass flow | node by the compressor connecting nodes k m | Frequency regulation constant for the i | Pipe's inlet elevation | i | Compressor's parasitic efficiency | k | Compressors' energy consumption functions vector | m | Compression process efficiency | lb | x | Active power nodal balance at the i | Susceptance of the nodal admittance matrix | BTU/ft | Average pressure for the pipeline connecting nodes k m | PSIA | bus | m Index of natural gas system nodes | Voltage magnitude at i | Generation of reactive power at i | Generated reactive power for case base at i | ƒ | Average temperature of the environment surrounding the pipe connecting nodes k m | air molecular weight | Load frequency dependence factor | Compressor's natural gas mass flow | Supercompressibility factor | Reactive load ratio modeled as constant power | Gas average temperature for the pipeline connecting nodes k m | generator (MW) | Load active power for case base at the i | Energy consumption for the compression station connecting nodes k m | Number of pipelines connected at node k | p.u. | Inner diameter of pipe linking nodes km | Final temperature of a mixture of several natural gas injections (°R) at k | MW | Base voltage for electric load connected the i | Equations | Reactive power nodal balance at the i | ft./sec | Natural gas nodal balance functions vector | Gas specific gravity | α | β | Compression ratio | γ | Gas specific heat ratio | δ | Number of sources injecting gas at the node k | Demand of active power at i | Base temperature | η | · | Power systems | 10.7316 gas constant (PSI ft | Demand of reactive power at i | Active load ratio modeled as constant current | ρ | Pipe's efficiency | τ | lbm/ft | Compressors' gas consumption functions vector | Nodes in the natural gas system | generator | Gas temperature at node m | BHP | Number of compressors connected at node k | ft | miles | Gas density calculated for the pipeline connecting nodes k m | g 32.2178 gravitational constant | Pressure at the k | Slope pipe correction | Δƒ Frequency deviation from rate value (pu) | Turbine-generator efficiency | Mathematical model | in the natural gas flowing by the pipe connecting nodes k m | GHV 1015 | Compression ratio functions vector | State variables for the electric power system | Generation of active power at i | Compressors | Pipe's length from node k to node m | Active load ratio modeled as constant power | dimensionless | Number of compressors in the natural gas system | j Index of electrical system nodes | C 77.54 for gas flow formulation in English units

lbmol °R | Active load ratio modeled as constant impedance | Pipelines | HP | Generated active power for case base at i | Gas extracted from the k | Reactive load ratio modeled as constant current | inches | Reactive power characteristic for the i | rad | Heat transfer coeff. at pipe from k to m | Natural gas load at k | Cp Gas heat capacity at constant pressure | Load modeling | gross heating value | 28.96 | П | and γ | Total natural gas injected by pipelines and compressors at k | Reactive load ratio modeled as constant impedance | SCFD | ) | State variables for the natural gas system | Conductance of the nodal admittance matrix | node | Number of natural gas loads from the node k | Compressor's gas consumption coefficients | Base value of pressure | Pipe's outlet elevation | ΔP | ΔQ | Natural gas | Qr | Natural gas injection at k | Joule-Thompson coefficient | D | E | G | Voltage angle at i | H | Mass of natural gas | X State variables for the coupled system | Thermal functions vector | L | N | ŏ | P | sec | Q | R/PSIA | Nodes in the electrical system | R | T | U | V | Rate active power for the i | Z | Heat rate coefficients for coupled nodes | BTU/SCF | a | b | ƒ Darcy-Weisbach friction factor | c | Load reactive power for case base at the i | Pipe's natural gas mass flow | node by the compressor connecting nodes k m | Frequency regulation constant for the i | Pipe's inlet elevation | i | Compressor's parasitic efficiency | k | Compressors' energy consumption functions vector | m | Compression process efficiency | lb | x | Active power nodal balance at the i | Susceptance of the nodal admittance matrix | BTU/ft | Average pressure for the pipeline connecting nodes k m | PSIA | bus | m Index of natural gas system nodes | Voltage magnitude at i | Generation of reactive power at i | Generated reactive power for case base at i | ƒ | Average temperature of the environment surrounding the pipe connecting nodes k m | air molecular weight | Load frequency dependence factor | Compressor's natural gas mass flow | Supercompressibility factor | Reactive load ratio modeled as constant power | Gas average temperature for the pipeline connecting nodes k m | generator (MW) | Load active power for case base at the i | Energy consumption for the compression station connecting nodes k m | Number of pipelines connected at node k | p.u. | Inner diameter of pipe linking nodes km | Final temperature of a mixture of several natural gas injections (°R) at k | MW | Base voltage for electric load connected the i | Equations | Reactive power nodal balance at the i | ft./sec | Natural gas nodal balance functions vector | Gas specific gravity | α | β | Compression ratio | γ | Gas specific heat ratio | δ | Number of sources injecting gas at the node k | Demand of active power at i | Base temperature | η | · | Power systems | 10.7316 gas constant (PSI ft | Demand of reactive power at i | Active load ratio modeled as constant current | ρ | Pipe's efficiency | τ | lbm/ft | Compressors' gas consumption functions vector | Nodes in the natural gas system | generator | Gas temperature at node m | BHP | Number of compressors connected at node k | ft | miles | Gas density calculated for the pipeline connecting nodes k m | g 32.2178 gravitational constant | Pressure at the k | Slope pipe correction | Δƒ Frequency deviation from rate value (pu) | Turbine-generator efficiency | Mathematical model | in the natural gas flowing by the pipe connecting nodes k m | GHV 1015 | Compression ratio functions vector | State variables for the electric power system | Generation of active power at i | Compressors | Pipe's length from node k to node m | Active load ratio modeled as constant power | dimensionless | Number of compressors in the natural gas system | j Index of electrical system nodes | C 77.54 for gas flow formulation in English units

Conference Proceeding

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 07/2012, Volume 86, Issue 1, p. 016207

We study the scattering of waves in systems with losses or gains simulated by imaginary potentials. This is done for a complex delta potential that corresponds...

DISORDERED-SYSTEMS | S-MATRIX | TRANSPORT | CAVITIES | PHYSICS, FLUIDS & PLASMAS | INFORMATION-THEORY | ABSORPTION | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | Models, Theoretical | Rheology - methods | Algorithms | Energy Transfer | Computer Simulation

DISORDERED-SYSTEMS | S-MATRIX | TRANSPORT | CAVITIES | PHYSICS, FLUIDS & PLASMAS | INFORMATION-THEORY | ABSORPTION | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | Models, Theoretical | Rheology - methods | Algorithms | Energy Transfer | Computer Simulation

Journal Article

AIP Conference Proceedings, ISSN 0094-243X, 08/2014, Volume 1579, Issue 1

AIP Conf. Proc. 1579, 46 (2014) We perform a study based on a random-matrix theory simulation for a three-terminal device, consisting of chaotic cavities on...

Physics - Mesoscale and Nanoscale Physics | WAVEGUIDES | ELECTRIC POTENTIAL | CONFIGURATION | VOLTAGE DROP | SIMULATION | MATHEMATICAL METHODS AND COMPUTING | CHAOS THEORY

Physics - Mesoscale and Nanoscale Physics | WAVEGUIDES | ELECTRIC POTENTIAL | CONFIGURATION | VOLTAGE DROP | SIMULATION | MATHEMATICAL METHODS AND COMPUTING | CHAOS THEORY

Journal Article

Journal of Physics A: Mathematical and Theoretical, ISSN 1751-8113, 06/2013, Volume 46, Issue 23, pp. 235101 - 12

In this paper, we study the evolution of the wavefunction with the system size in a locally periodic structure. In particular, we analyse the dependence of the...

CONDUCTANCE | TRANSPORT | WAVES | PHYSICS, MULTIDISCIPLINARY | ELECTRONS | SEMICONDUCTOR SUPERLATTICES | CRYSTAL | PHYSICS, MATHEMATICAL | Bands | Maps | Equivalence | Mean free path | Chaos theory | Mathematical analysis | Decay | Evolution | Wavefunctions

CONDUCTANCE | TRANSPORT | WAVES | PHYSICS, MULTIDISCIPLINARY | ELECTRONS | SEMICONDUCTOR SUPERLATTICES | CRYSTAL | PHYSICS, MATHEMATICAL | Bands | Maps | Equivalence | Mean free path | Chaos theory | Mathematical analysis | Decay | Evolution | Wavefunctions

Journal Article

EPL, ISSN 0295-5075, 06/2015, Volume 110, Issue 5, pp. 54003 - p1-54003-p5

In a wave resonant scattering process the interference of the continuous scattering amplitude with a discrete resonant state, both of the same undulatory...

VIBRATIONS | MATRIX | PHASE | BOUND-STATES | PHYSICS, MULTIDISCIPLINARY | Scattering amplitude | Resonance scattering | Amplitudes | Scattering | Interference

VIBRATIONS | MATRIX | PHASE | BOUND-STATES | PHYSICS, MULTIDISCIPLINARY | Scattering amplitude | Resonance scattering | Amplitudes | Scattering | Interference

Journal Article

Physical Review Letters, ISSN 0031-9007, 04/2005, Volume 94, Issue 14, p. 144101

We quantify the presence of direct processes in the S matrix of chaotic microwave cavities with absorption in the one-channel case. To this end the full...

S-MATRIX | REFLECTION | PHYSICS, MULTIDISCIPLINARY | STATISTICAL NUCLEAR-REACTIONS | INFORMATION-THEORY | SYSTEMS | SCATTERING

S-MATRIX | REFLECTION | PHYSICS, MULTIDISCIPLINARY | STATISTICAL NUCLEAR-REACTIONS | INFORMATION-THEORY | SYSTEMS | SCATTERING

Journal Article

Journal of Mathematical Physics, ISSN 0022-2488, 07/2014, Volume 55, Issue 8, p. 81901

We calculate negative moments of the N-dimensional Laguerre distribution for the orthogonal, unitary, and symplectic symmetries. These moments correspond to...

MATRIX | LOCALIZATION | PHASE-SHIFTS | CONDUCTANCE FLUCTUATIONS | STATISTICAL PROPERTIES | SYSTEMS | PARAMETRIC CORRELATIONS | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | DERIVATIVES | QUANTUM DOTS | Variations | Holes | Delay time | Quantum dots | Delay | Physics - Mesoscale and Nanoscale Physics | LAGUERRE POLYNOMIALS | SYMMETRY | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | FLUCTUATIONS | CHAOS THEORY | CHARGED-PARTICLE TRANSPORT

MATRIX | LOCALIZATION | PHASE-SHIFTS | CONDUCTANCE FLUCTUATIONS | STATISTICAL PROPERTIES | SYSTEMS | PARAMETRIC CORRELATIONS | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | DERIVATIVES | QUANTUM DOTS | Variations | Holes | Delay time | Quantum dots | Delay | Physics - Mesoscale and Nanoscale Physics | LAGUERRE POLYNOMIALS | SYMMETRY | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | FLUCTUATIONS | CHAOS THEORY | CHARGED-PARTICLE TRANSPORT

Journal Article

Journal of Physics A: Mathematical and Theoretical, ISSN 1751-8121, 01/2008, Volume 41, Issue 1, p. 015103

The problem of chaotic scattering in the presence of direct processes or prompt responses is mapped via a transformation to the case of scattering in the...

REFLECTION | TRANSPORT | CAVITIES | PHYSICS, MULTIDISCIPLINARY | STATISTICAL NUCLEAR-REACTIONS | INFORMATION-THEORY | SYSTEMS | ABSORPTION | FORMULA | PHYSICS, MATHEMATICAL | GRAPHS

REFLECTION | TRANSPORT | CAVITIES | PHYSICS, MULTIDISCIPLINARY | STATISTICAL NUCLEAR-REACTIONS | INFORMATION-THEORY | SYSTEMS | ABSORPTION | FORMULA | PHYSICS, MATHEMATICAL | GRAPHS

Journal Article

ACTA PHYSICA POLONICA A, ISSN 0587-4246, 12/2013, Volume 124, Issue 6, pp. 1069 - 1073

We study the scattering of torsional waves through a quasi-one-dimensional cavity both from the experimental and theoretical points of view. The experiment...

MATRIX | TRANSPORT | PHYSICS, MULTIDISCIPLINARY | CHAOTIC SCATTERING | GRAPHS

MATRIX | TRANSPORT | PHYSICS, MULTIDISCIPLINARY | CHAOTIC SCATTERING | GRAPHS

Journal Article

04/2011

Phys. Rev. E 85, 057202 (2012) We show that the key transport states, insulating and conducting, of large regular networks of scatterers can be described...

Physics - Mesoscale and Nanoscale Physics

Physics - Mesoscale and Nanoscale Physics

Journal Article

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 03/2005, Volume 71, Issue 3, p. 036201

We study the effect of left-right symmetry on the distribution of the parametric derivative of the dimensionless conductance T with respect to an external...

TIME DELAYS | MATRIX | WEAK-LOCALIZATION | PHASE-SHIFTS | UNITARY | STATISTICS | PHYSICS, FLUIDS & PLASMAS | FLUCTUATIONS | SYSTEMS | CROSSOVER | PHYSICS, MATHEMATICAL | SCATTERING | Physics - Mesoscale and Nanoscale Physics

TIME DELAYS | MATRIX | WEAK-LOCALIZATION | PHASE-SHIFTS | UNITARY | STATISTICS | PHYSICS, FLUIDS & PLASMAS | FLUCTUATIONS | SYSTEMS | CROSSOVER | PHYSICS, MATHEMATICAL | SCATTERING | Physics - Mesoscale and Nanoscale Physics

Journal Article

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 10/2009, Volume 80, Issue 4, p. 045201

We exhibit a remarkable equivalence between the dynamics of an intermittent nonlinear map and the electronic transport properties (obtained via the scattering...

LOCALIZATION | chaos | S-matrix theory | PHYSICS, FLUIDS & PLASMAS | trees (mathematics) | FIELD | PHYSICS, MATHEMATICAL | nonlinear dynamical systems | metal-insulator transition | CONDUCTION | TREE | electrical conductivity | LATTICE | Electron Transport | Algorithms | Manufactured Materials | Models, Chemical | Nonlinear Dynamics | Computer Simulation

LOCALIZATION | chaos | S-matrix theory | PHYSICS, FLUIDS & PLASMAS | trees (mathematics) | FIELD | PHYSICS, MATHEMATICAL | nonlinear dynamical systems | metal-insulator transition | CONDUCTION | TREE | electrical conductivity | LATTICE | Electron Transport | Algorithms | Manufactured Materials | Models, Chemical | Nonlinear Dynamics | Computer Simulation

Journal Article

16.
Full Text
Möbius transformations and electronic transport properties of large disorderless networks

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 05/2012, Volume 85, Issue 5, p. 057202

We show that the key transport states, insulating and conducting, of large regular networks of scatterers can be described generically by negative and zero...

CHAOS | SYSTEMS | PHYSICS, MATHEMATICAL | PHYSICS, FLUIDS & PLASMAS | QUANTUM | GRAPHS

CHAOS | SYSTEMS | PHYSICS, MATHEMATICAL | PHYSICS, FLUIDS & PLASMAS | QUANTUM | GRAPHS

Journal Article

Physical Review B - Condensed Matter and Materials Physics, ISSN 0163-1829, 02/2004, Volume 69, Issue 8, pp. 853011 - 8530112

We investigate the statistical fluctuations of currents in chaotic quantum dots induced by pumping and rectification at finite temperature and in the presence...

CONDUCTANCE | DENSITY | PHYSICS, CONDENSED MATTER | TRANSPORT | DERIVATIVES | Physics - Mesoscale and Nanoscale Physics

CONDUCTANCE | DENSITY | PHYSICS, CONDENSED MATTER | TRANSPORT | DERIVATIVES | Physics - Mesoscale and Nanoscale Physics

Journal Article

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 01/2005, Volume 71, Issue 1, p. 016223

We measure the transmission through asymmetric and reflection-symmetric chaotic microwave cavities in dependence on the number of attached waveguides. Ferrite...

QUANTUM TRANSPORT | MATRIX THEORY | SEMICLASSICAL APPROACH | ERGODIC BEHAVIOR | PHYSICS, FLUIDS & PLASMAS | CONDUCTANCE FLUCTUATIONS | BALLISTIC MICROSTRUCTURES | DOTS | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | DERIVATIVES | PROBE

QUANTUM TRANSPORT | MATRIX THEORY | SEMICLASSICAL APPROACH | ERGODIC BEHAVIOR | PHYSICS, FLUIDS & PLASMAS | CONDUCTANCE FLUCTUATIONS | BALLISTIC MICROSTRUCTURES | DOTS | CHAOTIC SCATTERING | PHYSICS, MATHEMATICAL | DERIVATIVES | PROBE

Journal Article

Electric Power Systems Research, ISSN 0378-7796, 07/2019, Volume 172, pp. 63 - 76

•A generalized short-term unit commitment approach for multi-energy systems is proposed.•The proposal integrates a multi-period nonlinear optimal gas and AC...

Mixed-integer nonlinear programming | Security-constrained unit commitment | Integrated gas and electricity networks | Power systems operation | NETWORK | COORDINATED ELECTRICITY | UNCERTAINTY | RELAXATION | OPTIMIZATION | ENGINEERING, ELECTRICAL & ELECTRONIC | Electric power production | Electric power systems | Analysis | Natural gas | Unit commitment | Scheduling | Optimization | Integer programming | Reactive power | Electricity | Gas flow | Power flow | Nonlinear programming | Electricity generation | Power dispatch | Heat transfer | Alternating current

Mixed-integer nonlinear programming | Security-constrained unit commitment | Integrated gas and electricity networks | Power systems operation | NETWORK | COORDINATED ELECTRICITY | UNCERTAINTY | RELAXATION | OPTIMIZATION | ENGINEERING, ELECTRICAL & ELECTRONIC | Electric power production | Electric power systems | Analysis | Natural gas | Unit commitment | Scheduling | Optimization | Integer programming | Reactive power | Electricity | Gas flow | Power flow | Nonlinear programming | Electricity generation | Power dispatch | Heat transfer | Alternating current

Journal Article

Physical Review B, ISSN 2469-9950, 08/2018, Volume 98, Issue 7

The Landauer-Buttiker formalism establishes an equivalence between the electrical conduction through a device, e.g., a quantum dot, and the transmission....

MATRIX | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | SCATTERING | Physics - Mesoscale and Nanoscale Physics

MATRIX | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | SCATTERING | Physics - Mesoscale and Nanoscale Physics

Journal Article

No results were found for your search.

Cannot display more than 1000 results, please narrow the terms of your search.