2004
DOI: 10.1103/physreve.69.061101
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Partition function, metastability, and kinetics of the escape transition for an ideal chain

Abstract: An end-tethered polymer chain squeezed between two pistons undergoes an abrupt transition from a confined coil state to an inhomogeneous flower-like conformation partially escaped from the gap. We present a rigorous analytical theory for the equilibrium and kinetic aspects of this phenomenon for a Gaussian chain. Applying the analogy with the problem of the adsorption of an ideal chain constrained by one of its ends, we obtain a closed analytical expression for the exact partition function. Various equilibrium… Show more

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Cited by 25 publications
(32 citation statements)
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“…A short-range repulsive force exists between the chain segments and the surfaces of the pistons. It was shown 25,30 that the confinement effect of the pistons is equivalent to an effective potential per segment in k B T units u = 1 6 ͑ a / H͒ 2 . The nature of this effective potential is purely entropic ͑u is the loss of entropy per polymer segment in slit͒.…”
Section: General Equationsmentioning
confidence: 99%
See 4 more Smart Citations
“…A short-range repulsive force exists between the chain segments and the surfaces of the pistons. It was shown 25,30 that the confinement effect of the pistons is equivalent to an effective potential per segment in k B T units u = 1 6 ͑ a / H͒ 2 . The nature of this effective potential is purely entropic ͑u is the loss of entropy per polymer segment in slit͒.…”
Section: General Equationsmentioning
confidence: 99%
“…Then, the two states coexist and the radial density and the free end distribution have a bimodal character. 25 The compressed coil minimum is located at s coil = 0 and its depth is given by ⌽͑s coil ͒ = N −1 ͑ R g / H͒ 2 . The minimum, corresponding to the escaped flower state, is found at s esc = a /3H, and this minimum is ⌽͑s esc ͒ = L / NH.…”
Section: Order Parameter and Landau Functionmentioning
confidence: 99%
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