On Some Considerations of Cloud Particles and Photons Interaction

Main Article Content

Marika R. Tatishvili


The interaction of light (photon) and cloud particles according main quantum assumption that system internal energy is composed by bound microparticles (cluster) under certain conditions  can obtain allowed discrete significances has been discussed in the article. The objective is to calculate the transition probability from one state into another caused by inner forces or any internal processes. The cluster may be presented as multipole system. The some peculiarities of microstructure of cloud formations have been discussed using quantum disperse forces or Van-Der-Vaals forces that are typical for water particles. To obtain the expression for interaction potential the wave functions of basic and exited states of clusters and dispersion matrix have been introduced describing by virtual photon. It has been turned out that virtual photon interaction causes potential holes and barriers that are decreased by height and width. The isolated long wave quant may be the radiation that is generated throughout observed microphysical processes.


Water molecule, photon exchange, interaction potential, probability amplitude, wave functio
Published: Dec 30, 2021

Article Details

How to Cite
Tatishvili, M. R. . (2021). On Some Considerations of Cloud Particles and Photons Interaction . Journals of Georgian Geophysical Society, 24(2). https://doi.org/10.48614/ggs2420213324


Direct observation of ultrafast hydrogen bond strengthening in liquid water”. Jie Yang, Riccardo Dettori, J. Pedro F. Nunes, Nanna H. List, etc. Nature, 2021, DOI: 10.1038/s41586-021-03793-9

Landau L.D., Lifshic E.M. Quantum Mechanics. v.3. 1989

Perelman M.E., Badinov I.Ia. Model of cloud formations. Bulletin of Georgian Acedemy of Sciences, v.131, N2, 1988

Hasted D. Physics of atomic collisions. 1965

Tatishvili M. Some peculiarities of mathematical simulation of cloud microstructure. Transactions of the Institute of Hydrometeorology, v.114, 2009.

Baur G. et al. Nuclear Physics, A 729, 2003, pp. 787–808

Pekka Manninen. manninen@chem.helsinki.fi http://www.chem.helsinki.fi/»manninen/mqm06.html

Tatishvili M. Energy transformation in clouds according quantum principles. International Scientific Journal. Journal of Environmental Science, vol. 3, 2014, pp. 7-9.

Tatishvili M. Developing Weather Forecasting System in Georgia. Ecology & Environmental Sciences, 2 (7), 2017, DOI:10.15406/mojes.2017.02.00046

Selvam A. M. A General Systems Theory for Chaos, Quantum Mechanics and Gravity. Apeiron 11, 134-146, http://redshift.vif.com/JournalFiles/V11NO3PDF/V11N3SEL.PDF

http://arxiv.org/html/physics/0211066, 2004

Palmer T.N. Quantum Reality, Complex Numbers and the Meteorological Butterfly Effect. European Centre for Medium-Range Weather Forecasts Shinfield Park, RG2 9AX, Reading .UK. Bulletin of the American Meteorological Society”, April 2005

Hajcek P. A new approach to quantum measurement problem: cluster separability. Journal of Physics: Conference, Series 306, 2011, 012035 doi:10.1088/1742-6596/306/1/012035

Tatishvili M.R., Palavandishvili A.M. Impact of Short-Term Geomagnetic Activity on Weather and Climate Formation in Georgian Region. Journal of the Georgian Geophysical Society,Physics of Solid Earth, Atmosphere, Ocean and Space Plasma, ISSN: 1512-1127, v. 23(2), 2020.

Tatishvili M.R., Khvedelidze Z.V., Demetrashvili D.I. On some weather forecasting models in Georgia. Journal of the Georgian Geophysical Society, Physics of Solid Earth, Atmosphere, Ocean and Space Plasma, ISSN: 1512-1127, v. 23(2), 2020.