Fluctuation-dissipation theorem
The fluctuation–dissipation theorem (FDT) or fluctuation–dissipation relation (FDR) is a powerful tool in statistical physics for predicting the behavior of systems that obey detailed balance. Given that a system obeys detailed balance, the theorem is a general proof that thermodynamic fluctuations in a physical variable predict the response quantified by the admittance or impedance (to be intended in their general sense, not only in electromagnetic terms) of the same physical variable (like voltage, temperature difference, etc.), and vice versa. The fluctuation–dissipation theorem applies both to classical and quantum mechanical systems.
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Brendan ScaifeCorrelation function (statistical mechanics)DiffusionEigenstate thermalization hypothesisEinstein relation (kinetic theory)Extremal principles in non-equilibrium thermodynamicsFDTFick's laws of diffusionFluctuation-Dissipation theoremFluctuation-dissipation relationFluctuation-dissipation theoremFluctuation Dissipation TheoremFluctuation dissipation theoremFluctuation–dissipation relationFluctuation–dissipation theoremFokker–Planck equationHarry NyquistHerbert CallenIndex of physics articles (F)Jarzynski equalityJohnson–Nyquist noiseJoule heatingLSZ reduction formulaLangevin equationLate modern periodLiquidList of scientific publications by Albert EinsteinList of theoremsMagnetic tweezersMohammad H. AnsariMolecular motorNoise (electronics)Ornstein–Uhlenbeck processPhase-field modelRelaxation (physics)ResistorStatistical mechanicsSupersymmetric theory of stochastic dynamicsTheodore A. WeltonThermal fluctuations
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Fluctuation-dissipation theorem
The fluctuation–dissipation theorem (FDT) or fluctuation–dissipation relation (FDR) is a powerful tool in statistical physics for predicting the behavior of systems that obey detailed balance. Given that a system obeys detailed balance, the theorem is a general proof that thermodynamic fluctuations in a physical variable predict the response quantified by the admittance or impedance (to be intended in their general sense, not only in electromagnetic terms) of the same physical variable (like voltage, temperature difference, etc.), and vice versa. The fluctuation–dissipation theorem applies both to classical and quantum mechanical systems.
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De fluctuatie-dissipatiestelli ...... ierbij exponentieel verval op.
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El teorema de fluctuación-disi ...... por Herbert Callen y en 1951.
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En théorie de la réponse linéa ...... e livre de Landau et Lifshitz.
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O teorema de flutuação-dissipa ...... e Theodore A. Welton em 1951.
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The fluctuation–dissipation th ...... noise in electrical resistors.
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Флуктуативно-дисипативна теоре ...... ла Больцмана, T - температура.
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Флуктуационно-диссипационная т ...... ий в ведущих научных журналах.
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揺動散逸定理(ようどうさんいつていり、英: fluctuat ...... におけるゆらぎと抵抗(抗力)の間にある関係を示すものである。
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De fluctuatie-dissipatiestelli ...... Callen en Theodore A. Welton.
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El teorema de fluctuación-disi ...... temas clásicos como cuánticos.
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En théorie de la réponse linéa ...... e livre de Landau et Lifshitz.
@fr
O teorema de flutuação-dissipa ...... e Theodore A. Welton em 1951.
@pt
The fluctuation–dissipation th ...... nd quantum mechanical systems.
@en
Флуктуативно-дисипативна теоре ...... ла Больцмана, T - температура.
@uk
Флуктуационно-диссипационная т ...... ий в ведущих научных журналах.
@ru
揺動散逸定理(ようどうさんいつていり、英: fluctuat ...... におけるゆらぎと抵抗(抗力)の間にある関係を示すものである。
@ja
label
Fluctuatie-dissipatiestelling
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Fluctuation-dissipation theorem
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Fluktuations-Dissipations-Theorem
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Teorema de fluctuación-disipación
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Teorema de flutuação-dissipação
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Théorème de fluctuation-dissipation
@fr
Флуктуативно-дисипативна теорема
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Флуктуационно-диссипационная теорема
@ru
揺動散逸定理
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