I n t e r n a t i o n a l C o n f e r e n c e o n

Metal, Mining and

Magnetic Materials

Journal of Material Sciences

ISSN: 2321-6212

N o v e m b e r 0 1 - 0 2 , 2 0 1 8

P a r i s , F r a n c e

Metal and Magnetism 2018

Page 19

B

y introducing the concept of fluid, or more accurately, of liquid space-time,

nearly ten years ago, Delplace proposed to modify classical quanta equations

in order to introduce energy density. In both Planck and Einstein equations for

electromagnetic waves, energy was divided by a volume representative of atomic

particles scale giving an energy density. This change in quanta equations gave a

strong analogy with classical fluid mechanics equations and Planck’s law took the

same form as a rheological equation of state (stress tensor proportional to rate

of strain tensor, proportionality constant being the liquid dynamic viscosity). This

result justified introduction of fluid space-time and analogy allowed to consider

the ratio of Planck constant to a volume as a dynamic viscosity value (dimensions

are the same). The problem was then to define a reference length or scale

length representative of phenomena at atomic level. By considering that, energy

densities should be identical at both atomic and astronomic (general relativity)

scales, Delplace found a reference value of 1 fm. Using a sphere volume of radius

1 fm, allowed electromagnetic stress was produced by electromagnetic waves to

be calculated as a function of wave-length. Finally, the approach was applied to

all atoms of periodic classification. Huge densities found for atomic material i.e.

electron, proton and neutron gave a very high value of stress produced by each

atom in fluid space-time. Using a fluid mechanics mixing model, we proposed to

characterize atoms by a parameter which depends on atoms orbitales shapes

and complexity. This model could be useful for nanotechnologies applications by

giving a new way to characterize atoms behaviour and physical properties

Biography

Franck Delplace has obtained his PhD in Mechanics at Nancy

University (France) in 1994 and he started his career as Re-

searcher in Fluid Mechanics and Thermal Sciences at INRA. Af-

ter Honorary Research Fellowship at Birmingham (GB) Universi-

ty, he was included in the American Who’s Who in Science and

Engineering (1998). He occupied Technical Expert Position in

several companies until today at EDF (French Major Electricity

Co). In 2011, he reached the Scientific Committee of ESI Group

(Leading French Co inNumerical Simulation) as an expert in Flu-

id Mechanics and Industrial Challenges. His research interests

are in both Physics and Mathematics: Fluid Mechanics, Gravity

Theory, Field Theories including Quantum Gravity, Riemannian

Manifolds and Complex Functions (Euler-Riemann zeta func-

tion). He published more than 50 papers in reputed journal and

he is a Co-author of publications with famous mathematician H

Srivastava. He is also Editorial BoardMember of many scientific

journals and Chief Editor.

fr.delplace@gmail.com

Energy density of electromagnetic waves

and its extension to all atoms of periodic

classification

Franck Delplace

ESI Group Scientific Committee, France

Franck Delplace, J Mat. Sci. 2018, Volume:6

DOI: 10.4172/2321-6212-C7-031