ACS  Vol.4 No.4 , October 2014
A Quantistic Interpretation of the Relationship between the Earth-Core and the Atmosphere
Author(s) Sergio Manzetti

The atmospheric behaviour of air is largely governed by low and high pressure systems. However, the relationship between these systems is not linear, as winds, sea temperatures and solar intensity modulate their dynamics and reduce predictability. Several other factors are known to affect these atmospheric dynamics, such as solar cycles. Recent evidence shows however that the earth’s gravitational field can be quantized in terms of quantum numbers, as recently published in Nature. The implications of this relationship between gravity and quantum numbers give rise to the possible key role of a quantum behaviour of gravity in affecting the formation of high- and low-pressure systems. In this letter, the author suggests a relation between the recently observed quantized nature of gravity, the weight of air and the formation of Low and High pressure areas in the atmosphere. The theory is novel and can aid in the understanding of interplay between the earths core forces, the gravitational behaviour and the atmospheric dynamics. There are however several parts of this theory that need further development, and an initial expression of this putative relationship is introduced.

Cite this paper
Manzetti, S. (2014) A Quantistic Interpretation of the Relationship between the Earth-Core and the Atmosphere. Atmospheric and Climate Sciences, 4, 508-513. doi: 10.4236/acs.2014.44046.
[1]   Wilcox, J.M. (1975) Solar Activity and the Weather. Journal of Atmospheric and Terrestrial Physics, 37, 237-256.

[2]   Tinsley, B.A. (1996) Correlations of Atmospheric Dynamics with Solar Wind-Induced Changes of Air-Earth Current Density into Cloud Tops. Journal of Geophysical Research, 101, 29701-29714.

[3]   Mayewski, P.A., Meeker, L.D., Twickler, M.S., Whitlow, S., Yang, Q., Lyons, W.B. and Prentice, M. (1997) Major Features and Forcing of High-Latitude Northern Hemisphere Atmospheric Circulation Using a 110,000-Year-Long Glaciochemical Series. Journal of Geophysical Research, 102, 26345-26366.

[4]   Smith, D.E., Zuber, M.T., Haberle, R.M., Rowlands, D.D. and Murphy, J.R. (1999) The Mars Seasonal CO2 Cycle and the Time Variation of the Gravity Field: A General Circulation Model Simulation. Journal of Geophysical Research: Planets, 104, 1885-1896.

[5]   Connerney, J., Acuna, M., Wasilewski, P., Kletetschka, G., Ness, N., Reme, H., Lin, R. and Mitchell, D. (2001) The Global Magnetic Field of Mars and Implications for Crustal Evolution. Geophysical Research Letters, 28, 4015-4018.

[6]   Stevenson, D.J. (2001) Mars’ Core and Magnetism. Nature, 412, 214-219.

[7]   Malkus, W. (1968) Precession of the Earth as the Cause of Geomagnetism Experiments Lend Support to the Proposal That Precessional Torques Drive the Earth’s Dynamo. Science, 160, 259-264.

[8]   Olsen, N. and Mandea, M. (2008) Rapidly Changing Flows in the Earth’s Core. Nature Geoscience, 1, 390-394.

[9]   de Wijs, G.A., Kresse, G., Vocadlo, L., Dobson, D., Alfe, D., Gillan, M.J. and Price, G.D. (1998) The Viscosity of Liquid Iron at the Physical Conditions of the Earth’s Core. Nature, 392, 805-807.

[10]   Nesvizhevsky, V.V., Borner, H.G., Petukhov, A.K., Abele, H., Baeszler, S., Ruesz, F.J., Stoferle, T., Westphal, A., Gagarski, A.M., Petrov, G.A. and Strelkov, A.V. (2002) Quantum States of Neutrons in the Earth’s Gravitational Field. Nature, 415, 297-299.

[11]   Dirac, P.A.M. (1947) The Principles of Quantum Mechanics. The International Series of Monographs on Physics, Clarendon Press, Oxford, 1.

[12]   Schrodinger, E. (1935) Present Status of Quantum Mechanics. Die Naturwissenschaften, 23, 1-26.

[13]   Atkins, P.W. and Friedman, R.S. (1997) Molecular Quantum Mechanics. Vol. 3, Oxford University Press, Oxford.

[14]   Reigber, C., Schmidt, R., Flechtner, F., Konig, R., Meyer, U., Neumayer, K.-H., Schwintzer, P. and Zhu, S.Y. (2005) An Earth Gravity Field Model Complete to Degree and Order 150 from GRACE: EIGEN-GRACE02S. Journal of Geodynamics, 39, 1-10.

[15]   Higgins, M. (2014) World Weather Patterns 2013.

[16]   Manzetti, S. (2012) Electron Orbital Theory for an Alternative Interpretation of Low-Pressure Hurricane Systems. Marine Science, 2, 52-56.