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Transfer of atomic mass with a photon solves the momentum paradox of light

Date:
June 30, 2017
Source:
Aalto University
Summary:
In a transparent medium, each photon is accompanied by an atomic mass density wave, scientists can demonstrate. The optical force of the photon sets the medium atoms in motion and makes them carry 92% of the total momentum of light, in the case of silicon.
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In a recent publication, Aalto University researchers show that in a transparent medium each photon is accompanied by an atomic mass density wave. The optical force of the photon sets the medium atoms in motion and makes them carry 92% of the total momentum of light, in the case of silicon.

The novel discovery solves the centennial momentum paradox of light. In the literature, there has existed two different values for the momentum of light in the transparent medium. Typically, these values differ by a factor of ten and this discrepancy is known as the momentum paradox of light. The difference between the momentum values is caused by neglecting the momentum of atoms moving with the light pulse.

To solve the momentum paradox the authors prove that the special theory of relativity requires an extra atomic density to travel with the photon. In related classical computer simulations, they use optical force field and Newton´s second law to show that a wave of increased atomic mass density is propagating through the medium with the light pulse.

The mass transfer leads to splitting of the total momentum of light into two components. The fields' share of momentum is equal to the Abraham momentum while the total momentum, which includes also the momentum of atoms driven forward by the optical force, is equal to the Minkowski momentum.

"Since our work is theoretical and computational it must be still verified experimentally, before it can become a standard model of light in a transparent medium. Measuring the total momentum of a light pulse is not enough but one also has to measure the transferred atomic mass. This should be feasible using present interferometric and microscopic techniques and common photonic materials," researcher Mikko Partanen says.

The researchers are working on potential optomechanical applications enabled by the optical shock wave of atoms predicted by the new theory. However, the theory applies not only to transparent liquids and solids but also to dilute interstellar gas. Using a simple kinematic consideration it can be shown that the energy loss caused by the mass transfer effect becomes for dilute interstellar gas proportional to the photon energy and distance travelled by light.

"This prompts for further simulations with realistic parameters for interstellar gas density, plasma properties and temperature. Presently the Hubble's law is explained by Doppler shift being larger from distant stars. This effectively supports the hypothesis of expanding universe. In the mass polariton theory of light this hypothesis is not needed since redshift becomes automatically proportional to the distance from the star to the observer," explains Professor Jukka Tulkki.


Story Source:

Materials provided by Aalto University. Note: Content may be edited for style and length.


Journal Reference:

  1. Mikko Partanen, Teppo Häyrynen, Jani Oksanen, Jukka Tulkki. Photon mass drag and the momentum of light in a medium. Physical Review A, 2017; 95 (6) DOI: 10.1103/PhysRevA.95.063850

Cite This Page:

Aalto University. "Transfer of atomic mass with a photon solves the momentum paradox of light." ScienceDaily. ScienceDaily, 30 June 2017. <www.sciencedaily.com/releases/2017/06/170630085627.htm>.
Aalto University. (2017, June 30). Transfer of atomic mass with a photon solves the momentum paradox of light. ScienceDaily. Retrieved December 22, 2024 from www.sciencedaily.com/releases/2017/06/170630085627.htm
Aalto University. "Transfer of atomic mass with a photon solves the momentum paradox of light." ScienceDaily. www.sciencedaily.com/releases/2017/06/170630085627.htm (accessed December 22, 2024).

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