BIO-DATA
KOTCHERLAKOTA LAKSHMI NARAYNA
SEX: MALE
Date of Birth: 23rd July 1940
MARITAL STATUS: SINGLE
Birth Place: Visakhapatnam
ACADEMIC QUALIFICATIONS:
M.Sc. Mathematical Physics, (1960) Andhra University
M.Sc. Nuclear Physics (1961) Andhra University
Ph. D. (Physics) (three foreign FRS examiners) 1964 Andhra University
J.R.F (CSIR): Nuclear Quadrupole Resonance: 1961-1964, Andhra University, Waltair.
International research Fellow: 1964-1965: Uppsala University, Sweden
Senior Scientific Assistant: Government of India, Defence Scheme on Microwaves
PROFESSIONAL EXPERIENCE:
Shivaji University, Kolhapur-416004; Lecturer from 1st June, 1966 to May 1975
Reader in Physics from June 1975 to 16th December 1984
Professor of Physics from 17th December 1984 to 31st July, 200
Member of Institute of Physics (London) 1975-2001
Guided several Ph.D. and M.Phil. students in Physics
Was a signatory of MOUs with NOAA, Boulder, USA, STEL, Nagoya University, Japan
Energy Center of Florida, USA and Shivaji University,
Was with BARC center of Kolhapur, Radio Astronomy Center, Kolhapur
Professor & Head PG Physics Dept at St.Theresa’s College for Women, (Feb 04 to March 05) Eluru.
TEACHING EXPERIENCE:
Physics Dept (A.U) Engg College, AU for Physics Practical and Theory as a JRF
M.Sc. and Ph.D. (34 years) taught subjects of Solid State Physics, Microprocessors, Plasma Physics, Quantum Mechanics, Classical mechanics, Cosmology, Relativity, Semi and Super conductors, Computer techniques, Particle and Advanced Quantum Theory, Electronics, Electrodynamics, General Physics.
RESEARCH EXPERIENCE:
Developed 18 research labs at Shivaji University, Kolhapur
Published about 20 papers on NQR, Ferroelectricity, BrCl molecule, Titanimu Coordinated Complexes
Guided about 204 M.Sc. dissertations.
SOCIAL ENTERPRISE:
Conducted National, Departmental and International Seminars.
Promoted Physics and Industry Interaction with Industrial Estate Enterprises
Promoted IT Forum of West Godavari District with D.I.O at Eluru as a founder member
PATENT: Has a patent on Pseudo-Ferroelectric Materials
FOREIGN COUNTRIES VISITED: Sweden, Denmark, Norway, Holland, Switzerland, France, Chekoslovakia, South Korea, Japan, USA, and Nepal.
Organized women study tour to Industry in the year 2004-2005 at Eluru
ATTENDED:
International Conferences:
Optical Society of America, New York, Fusion Energy Symposium, Salt Lake City, Polymer Composite, California, ACS, USA
National Level: (1961-2000) BARC symposia on Nuclear, Solid State and Particle Physics
Many other National Conferences, ISTAM, Bose Institute Seminars, Kolkatta, Gwalior, etc.
RETIRED: With full pension benefits on 31st July 2000 as a FULL Professor of Physics,
Shivaji University, Kolhapur-416604.
CURRENT INTEREST:
Polymer devices and Substrates of Novel materials. Materials Science and Solid State Physics, Nano & Smart Devices, Fuel cells and Energy Conversion Systems
Initiated a WEBSITE: http://tru_science.westgodavari.org/ to help and motivate young innovators in the cause of National Educational Endeavor.
Email Id: freekln@yahoo.co.in
Sunday, January 7, 2007
Saturday, January 6, 2007
ROSFET a Novel Device
94th Ind. Sci. Congress held at Annamalai University,Chidambaram
ISCA2007: 3nd- 7th, Januar, 2007 Paper No.112.
Physical Sciences:
The electronic liquid characteristics, model and theory of ROSFET device
Kotcherlakota Lakshmi Narayana,
(Affiliated to ANDHRA UNIVERSITY,Viskhapatnam)
A.G. L. College, P.G.Dept, Sankaramattam Road, near NH-5, Visakhapatnam-530016. Email Id : freekln@yahoo.co.in
Key words: ROSFET, electronic liquid, R and AR spins, Hall Resistance
ABSTRACT:
The electronic liquid characteristics of devices and their solid state chemistry yield rich information about the electron and quasi-particle or pseudo-spin configuration aspects of the residual disordered structures of both charge transport source-drain current carrying charge states and localized states of charges trapped by impurities. ROSFET design, model and the theory have been detailed in this article. The correlated motions of molecular topological excitation spin particles R and AR with the electrons and holes, relative to both the applied magnetic field and the gauge fields involved are solved using the Schrödinger equation using different sets of effective masses for electrons (holes) and R (AR) spin particles. The impurity structures of SiO2 insulating oxide and (dopant XY4) metal-oxide interface has been shown to give quantization of Hall resistances and fractional Hall resistances characterized by four quantum numbers n, m, γ, l, α, unlike in the Klaus von Klitzing theory of QHE or the FQHE of Clark and Maksym. The new quantum numbers m, γ describe the zx-plane and xy-plane oscillatory motion of the electrons (holes) and R (AR) with two different centers and the concomitant frequencies. Our model wave equation and its energy level features are detailed in terms of the new quantum numbers of the FQHE description. Laplace transform and the direct analytical solutions of the Schrödinger equation of the ROSFET have been obtained. The idea of Landau Levels description gets smeared out due to the consideration of a gauge magnetic field and the width of the device plays a role of quantization.
ISCA2007: 3nd- 7th, Januar, 2007 Paper No.112.
Physical Sciences:
The electronic liquid characteristics, model and theory of ROSFET device
Kotcherlakota Lakshmi Narayana,
(Affiliated to ANDHRA UNIVERSITY,Viskhapatnam)
A.G. L. College, P.G.Dept, Sankaramattam Road, near NH-5, Visakhapatnam-530016. Email Id : freekln@yahoo.co.in
Key words: ROSFET, electronic liquid, R and AR spins, Hall Resistance
ABSTRACT:
The electronic liquid characteristics of devices and their solid state chemistry yield rich information about the electron and quasi-particle or pseudo-spin configuration aspects of the residual disordered structures of both charge transport source-drain current carrying charge states and localized states of charges trapped by impurities. ROSFET design, model and the theory have been detailed in this article. The correlated motions of molecular topological excitation spin particles R and AR with the electrons and holes, relative to both the applied magnetic field and the gauge fields involved are solved using the Schrödinger equation using different sets of effective masses for electrons (holes) and R (AR) spin particles. The impurity structures of SiO2 insulating oxide and (dopant XY4) metal-oxide interface has been shown to give quantization of Hall resistances and fractional Hall resistances characterized by four quantum numbers n, m, γ, l, α, unlike in the Klaus von Klitzing theory of QHE or the FQHE of Clark and Maksym. The new quantum numbers m, γ describe the zx-plane and xy-plane oscillatory motion of the electrons (holes) and R (AR) with two different centers and the concomitant frequencies. Our model wave equation and its energy level features are detailed in terms of the new quantum numbers of the FQHE description. Laplace transform and the direct analytical solutions of the Schrödinger equation of the ROSFET have been obtained. The idea of Landau Levels description gets smeared out due to the consideration of a gauge magnetic field and the width of the device plays a role of quantization.
New Matter and Stellar Structures
94th Ind. Sci. Congress held at Annamalai University, Chidambaram
ISCA 2007 3nd- 7th, Januar, 2007. Mathematical Sciences Section
:Paper No 21 Page 14
The possible symmetry-supersymmetry interaction currents & the properties of strange matter of stellar structures
Kotcherlakota Lakshmi Narayana
A.G.L.College, Post Graduate department Sankaramattam Road, Viskhapatnam-530016. Email:Kotcherlakota_l_n@hotmail.com
Key words: strange matter, supersymmetry, smon particles, aesthetic beauty
ABSTRACT:
A model involving the symmetry-supersymmetry interaction has been suggested to explain the properties of strange matter of compact stellar structures. The nine supersymmetry particles (smons) are endowed with the hypercharge and isospin assignments. These are G, ¯Nc, iS, -iR, A, D, T, θc, ¯θc .The imaginary particles are included for the aesthetic beauty of the model considerations. The strangeness-conserving and strangeness-changing expressions have been obtained. The typical amplitudes (θc n| S Ξ-)a*ν ae = (κ- S| κ0 θc) a*ν a e = a μ a*e (π – θ| κ+ ¯Nc) and a μ a*e (κ- θ| π+ Nc) = (κ- θ| κ0 R) aν a*e with the equality relations and the ax’s are typical coefficients. For the symmetry we took the Octet mesons that play a role in the strange or the neutron stars. A, D, T particles that constitute the diagonal elements of the Nonet, obey SO (3) structure. An important feature of our symmetry-supersymmetry model is that the gluon type X, Y, Z quanta carry the charges as per the QCD requirements, but as well they posses mass The meson-smon vertex terms and their diagrams are much more complex. The only reason of the mass acquisition by the colored gluons is the compactness of the strange matter. The processes that we envisaged in our theory are Meson+smonMeson+smon. The predicted amplitude relations would help experimental analysis of the Quark-Gluon fireball experiments of CERN, FERMI LAB, RHIC etc on the properties of the new matter.
ISCA 2007 3nd- 7th, Januar, 2007. Mathematical Sciences Section
:Paper No 21 Page 14
The possible symmetry-supersymmetry interaction currents & the properties of strange matter of stellar structures
Kotcherlakota Lakshmi Narayana
A.G.L.College, Post Graduate department Sankaramattam Road, Viskhapatnam-530016. Email:Kotcherlakota_l_n@hotmail.com
Key words: strange matter, supersymmetry, smon particles, aesthetic beauty
ABSTRACT:
A model involving the symmetry-supersymmetry interaction has been suggested to explain the properties of strange matter of compact stellar structures. The nine supersymmetry particles (smons) are endowed with the hypercharge and isospin assignments. These are G, ¯Nc, iS, -iR, A, D, T, θc, ¯θc .The imaginary particles are included for the aesthetic beauty of the model considerations. The strangeness-conserving and strangeness-changing expressions have been obtained. The typical amplitudes (θc n| S Ξ-)a*ν ae = (κ- S| κ0 θc) a*ν a e = a μ a*e (π – θ| κ+ ¯Nc) and a μ a*e (κ- θ| π+ Nc) = (κ- θ| κ0 R) aν a*e with the equality relations and the ax’s are typical coefficients. For the symmetry we took the Octet mesons that play a role in the strange or the neutron stars. A, D, T particles that constitute the diagonal elements of the Nonet, obey SO (3) structure. An important feature of our symmetry-supersymmetry model is that the gluon type X, Y, Z quanta carry the charges as per the QCD requirements, but as well they posses mass The meson-smon vertex terms and their diagrams are much more complex. The only reason of the mass acquisition by the colored gluons is the compactness of the strange matter. The processes that we envisaged in our theory are Meson+smonMeson+smon. The predicted amplitude relations would help experimental analysis of the Quark-Gluon fireball experiments of CERN, FERMI LAB, RHIC etc on the properties of the new matter.
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