| Title |
Published |
SHARCNET Authors |
Area |
|
941.
Are the Radical Centers in Peptide Radical Cations Mobile? The Generation, Tautomerism, and Dissociation of Isomeric α-Carbon-Centered Triglycine Radical Cations in the Gas Phase
|
2008 |
Ivan K. Chu, Junfang Zhao, Minjie Xu, Shiu On Siu, Alan C. Hopkinson, K. W. Michael Siu
|
Computational Chemistry
|
|
942.
Dissociation of the NâCα Bond and Competitive Formation of the [zn â H]â+ and [cn + 2H]+ Product Ions in Radical Peptide Ions Containing Tyrosine and Tryptophan: The Influence of Proton Affinities on Product Formation
|
2008 |
Chi-Kit Siu, Yuyong Ke, Galina Orlova, Alan C. Hopkinson, and K. W. Michael Siu
|
Computational Chemistry
|
|
943.
Structure of the Observable Histidine Radical Cation in the Gas Phase: a Captodative α Radical Ion
|
2008 |
Jeffrey Steill, Junfang Zhao, Chi-Kit Siu, Yuyong Ke, Udo H. Verkerk, Jos Oomens, Robert C. Dunbar, Alan C. Hopkinson, and K.W. Michael Siu
|
Computational Chemistry
|
|
944.
Recent Developments in Dual Lattice Algorithms
|
2008 |
J.W. Cherrington
|
Quantum Gravity
|
|
945.
A molecular dynamics study of RNA hexaring nanostructures
|
2008 |
M. Paliy, R. Melnik, and B. Shapiro
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
946.
Forced dynamics and stability of RNA nanostructures
|
2008 |
M. Paliy, R. Melnik, and B. Shapiro
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
947.
Nonlinear dynamics of cell cycles with stochastic mathematical models
|
2008 |
X. Wei, R.V.N. Melnik, G. Moreno-Hagelsieb
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
948.
Properties of quantum wires with polygonal inclusions and Eshelby formulations for anisotropic thermo-piezolectric full and half planes
|
2008 |
S. Patil and R. Melnik
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
949.
Strain and electromechanical effects in II-VI group semiconductor nanowires
|
2008 |
S. Patil and R. Melnik
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
950.
Thermopiezoelectric and nonlinear electromechanical effects in quantum dots and nanowires
|
2008 |
S. Patil, M. Bahrami-Samani, R.V.N. Melnik, M. Toropova and J. Zu
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
951.
Strain effects and temperature-dependent phase stability of II-VI semiconductor nanostructures
|
2008 |
S. Patil, B. Wen and R. Melnik
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
952.
Temperature-dependent phase stability of CdS quantum dots from first-principle molecular dynamic calculations
|
2008 |
Wen B, Melnik RVN
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
953.
First passage time for multivariate jump-diffusion processes in finance and other areas of applications
|
2008 |
D. Zhang and R. Melnik
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
954.
Young modulus and phase stability of ZnO nanowires under uniaxial stress: A first principles study
|
2008 |
Wen B, Melnik RVN
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
955.
Relative stability of nanosized wurtzite and graphitic ZnO from density function theory
|
2008 |
B. Wen, R. Melnik
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
956.
First principles molecular dynamics study of CdS nanostructure temperature-dependent phase stability
|
2008 |
Wen B, Melnik RVN
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
957.
Advanced Monte Carlo study of the Goldstone mode singularity in the 3D XY model
|
2008 |
Kaupuzs, J., Melnik, R.V.N., Rimshans, J.
|
Modelling dynamics of coupled systems for nanotechnology, biological and stochastic applications
|
|
958.
Lattice dynamics and the optical properties of semiconductors: theory of the temperature dependent dielectric functions of GaAs and Si and comparison with experiment
|
2008 |
A.I. Shkrebtii, Z. Ibrahim, M.J.G. Lee, W. Richter, M. Drago and T. Trepk
|
Condensed Matter Physics
|
|
959.
Lattice and hydrogen dynamics in hydrogenated amorphous Silicon: first-principles molecular dynamics versus experiment
|
2008 |
A.I. Shkrebtii, I.M. Kupchak, and F. Gaspari
|
Condensed Matter Physics
|
|
960.
Dependence of a-Si:H density of states on hydrogen content: modeling and experiment
|
2008 |
F. Gaspari, I. M. Kupchak, A. I. Shkrebtii, Z. Ibrahim, A. Kazakevitch
|
Condensed Matter Physics
|
