Fluctuational QED

Fluctuational QED

Radiation Pressure is a feature of non-equilibrium steady states with different temperatures

At short scales "near-field effects" due to evanescent waves modify classical "Stefan-Boltzmann" law:

"Surface Phonon Polaritons Mediated Energy Transfer between Nanoscale Gaps," S.Shen, A. Narayanaswamy, G. Chen

Nano Lett. 9, 2909 (2009) Breaking the law, at the nanoscale (MIT news, July 29, 2009)

A generalized approach for computation of Casimir forces, as well as radiation and heat transfer.

"Nonequilibrium Fluctuational QED: Heat Radiation, Heat Transfer and Force,"

G. Bimonte, T. Emig, M. Kardar, and M. Krüger, Annual Review of Condensed Matter Physics 8, 119 (2017)

S.M. Rytov (1959): "Fluctuational QED"

Fluctuating currents in each object are related to its temperature by a fluctuation-dissipation condition:

The EM field due to thermal fluctuations of one object is related to overall Green's function by:

The overall fluctuations with many objects at different temperatures is then given by:

From EM correlations follow the stress tensor and the Poynting vector, hence forces and radiation.

Heat transfer at short distances is dominated by evanescent modes at material dependent resonances.

For a single dominant frequency , the heat flux diverges at small separations as

Radiation force levitation of a hot (tungsten) micro-sphere on top of a cold plate.

Rytov formalism allows computation of fluctuations in force and heat, both in and out of thermal equilibrium

Linear response relates equilibrium fluctuations to responses to small perturbations:

Friction coeficient in vacuum at finite temperature

Green Kubo relation (explicitly confirmed) provide coefficient of thermal conductivity

Onsager relation (relying of symmetry of mixed expectation values) give

"Nonequilibrium Fluctuational QED: Heat Radiation, Heat Transfer and Force,"

V. Golyk, M. Krüger, and M. Kardar, Phys. Rev. B 88, 155117 (2013). (offline)