Abstract
A two-stage model is developed to explain the phenomena of chain expansion, released from a confining cavity. In the first stage, the chain is assumed to expand as a sphere, while in the second stage it expands like a coil. The kinetic equations for the variation of chain size are derived in the two stages by balancing the rate of the free energy change with the rate of the energy dissipation. Langevin dynamics simulations are then performed to examine the theory. We find that the expansion process is dominated by the second stage and the evolution of chain size follows, mainly, the predicted curve for coil expansion, which depends on the chain length and is not sensitive to the confining volume fraction. It permits to define the expansion time for the process. Further study reveals that the chain does undergo a spherical expansion in the first stage with the characteristic time much shorter than the one for the second stage. As a consequence, the first-stage variation of chain size can be regarded as an add-on to the principal curve of expansion designated by the second stage. The scaling behaviors and the associated scaling exponents are analyzed in details. The simulation results well support the theory.
Funder
National Science and Technology Council, Taiwan
Subject
Polymers and Plastics,General Chemistry
Reference92 articles.
1. Iwasa, J., and Marshall, W. (2016). Karp’s Cell and Molecular Biology, John Wiley & Sons. [8th ed.].
2. Tortora, G.J., Funke, B.R., and Case, C.L. (2018). Microbiology: An Introduction, Pearson. [13th ed.].
3. Physical virology: From virus self-assembly to particle mechanics;Maity;Wiley Interdiscip. Rev. Nanomed. Nanobiotechnol.,2020
4. Anal, A.K. (2018). Bionanotechnology, CRC Press.
5. Taira, K., Kataoka, K., and Niidome, T. (2005). Non-Viral Gene Therapy, Springer.