Your search keyword '"Hairong Shang"' showing total 3 results

1. Application of a machine learning based algorithm to online optimization of the nonlinear beam dynamics of the Argonne Advanced Photon Source

Author

Louis Emery, Hairong Shang, Yipeng Sun, and Xiaobiao Huang

Subjects

Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A machine learning-based optimization algorithm, the multigeneration Gaussian process optimizer, is used to optimize the nonlinear beam dynamics of the Advanced Photon Source storage ring. The dynamic aperture (DA) and the local momentum aperture (LMA) are first optimized separately with sextupole knobs. Solutions found with these optimizations are used to seed the initial population of seeds in two-objective optimizations that simultaneously optimize the DA and LMA, which lead to a distribution of solutions with different DA and LMA performances, from which a setting suitable for operation can be selected.

Published

2021

2. EAP Researcher-Practitioner Collaboration: Reciprocity or Inequality?

Author

Hairong Shang-Butler

Subjects

Linguistics and Language, Inequality, media_common.quotation_subject, Reciprocity (network science), Sociology, Social psychology, Language and Linguistics, media_common

Published

2016

3. Models for Quantum Effects in Electron Transfer: Co(Cp)2+|V(CO)6

Author

Kenneth G. Spears and Hairong Shang

Subjects

Physics, Absorption spectroscopy, Molecular vibration, Quantum mechanics, Resonance, Absorption (logic), Electronic structure, Orbital overlap, Physical and Theoretical Chemistry, Coupling (probability), Quantum number

Abstract

The authors model the absolute electron transfer (ET) rate and the vibrational quantum effects on ET rate previously observed experimentally for the ion pair complex Co(Cp){sub 2}{sup +}{vert_bar}V(CO){sub 6}{sup {minus}}. The absolute rate and vibrational rate effects cannot be predicted by the standard ET methods. In this work the authors analyze new resonance Raman, absorption, and infrared spectra and combine these results with density functional (DFT) quantum calculations of structure, vibrational modes, and solvent effects to predict absolute electron-transfer rates and vibrational quantum effects for ET. Related DFT calculations on Na{sup +}{vert_bar}V(CO){sub 6}{sup {minus}} are used to support a spectroscopic identification of the ion pair geometry. The ET is from the radical pair state reached by charge-transfer absorption of the ion pair Co(Cp){sub 2}{sup +}{vert_bar}V(CO){sub 6}{sup {minus}}. The weak coupling rate model based on the golden rule model of ET predicts absolute ET rates that are 135 times too large. From DFT calculations on Co(CP){sub 2}{vert_bar}V(CO){sub 6}, it was concluded that a small Jahn-Teller geometry change in both radicals can reduce the orbital overlap and electronic coupling in the radical pair state so that the effective coupling matrix element is much smaller than the 417 cm{sup {minus}1} inferred from themore » absorption spectrum. A new study of the electronic coupling versus geometry is required to test this suggestion versus the possibility that the weak coupling model is inappropriate for the molecule. The standard model, which emphasizes totally symmetric vibrations, also cannot explain prior experimental ET rates for quantum populations ({nu} = 0, 1, 2) in the nontotally symmetric CO stretching mode. These rate effects likely involve a fast IVR conversion from totally symmetric vibrations to IR active CO stretching motions followed by ET. The vibrational quantum effect on ET probably is caused by a breakdown in the Condon approximation, where an increase in the quantum number of vibration increases the electronic coupling matrix element. The models suggest a number of new experiments to probe the mechanism of ET in weak coupled molecules.« less

Published

2000