materials-congress-2018-keynote

W o r l d C o n g r e s s o n

Materials Science & Engineering

Nano Research & Applications

ISSN: 2471-9838

August 23-25, 2018

Amsterdam, Netherlands

Materials Congress 2018

Page 20

he fast growing branches of nanotechnology permitted advancements in

different fields. Among them is the recent success in Low Energy Nuclear

Reactions/Lattice Enabled Nanoscale reactions (LENR). This requires a new

theoretical understanding for processes in atomic sub-nanometric scale. The

atomic models derived in the Basic Structures of Matter Supergravitation Unified

Theory (BSM-SG), denoted as the BSM-SG models, fit quite well to this need. The

BSM-SG theory reveals the existence of a space microcurvature surrounding

the elementary particles and the super dense atomic nuclei. This explains why

quantum mechanical models work only with energy levels and not with the

dimension of length. The re-examination of scattering experiments from the

BSM-SG point of view reveals a complex three-dimensional nuclear structure

different from the quantum mechanical models of atoms based on the Bohr

atomic model. Protons and neutrons are not point-like; the atomic nuclei have a

much larger overall size, so the Coulomb barrier is not so strong. Therefore, some

nuclear transmutations are possible at accessible temperatures. The pattern of

the Periodic Table carries a strong signature of the spatial arrangement of protons

and neutrons in the atomic nuclei. Nuclear stability depends on the symmetrical

arrangement of protons and neutrons. Nuclear spin and nuclear magnetic

resonance are also identifiable features of the nuclear configuration. The BSM-

SG atomic models provide a new opportunity for analysis and prediction of many

nuclear transmutations in the field of LENR. This issue is presented in the author’s

book ‘Structural Physics of Nuclear Fusion’. The book describes a newmethod for

theoretical estimation of the binding nuclear energy based on the derived nuclear

dimensions of hadrons and derived strong force parameters. This provides new

considerations for the proper selection of isotopes suitable for realization of cold

fusion energy with minimal or no radioactive waste.

Biography

Stoyan Sarg Sargoytchev completed his PhD in Physics from

the Bulgarian Academy of Sciences in 1984. Until 1990, he

worked on space research projects coordinated by the program

Intercosmos, and on a project of the ESA European agency.

From 1990 he was a Visiting Scientist at Cornel University for

two years. From 1992 he worked with Canadian government

institutions and universities and retired from York University in

2013. Currently he is a Distinguished Scientific Advisor at the

World Institute for Scientific Exploration, (WISE), USA. Selected

articles:

http://vixra.org/author/stoyan_sarg. sto.sarg@gmail.com

Analysis of LENR and recommendations

for cold fusion energy using the BSM-SG

atomic models

Stoyan Sarg Sargoytchev

World Institute for Scientific Exploration, USA

Stoyan Sarg Sargoytchev, Nano Res Appl 2018, Volume: 4

DOI: 10.21767/2471-9838-C4-016