Dynamic Compression of in situ Grown Living Polymer Brush: Simulation and Experiment

TL;DR

This study combines simulation and experiment to analyze the behavior of living polymer brushes, revealing their density profiles, chain length distributions, and force interactions, with results aligning closely with theoretical predictions and experimental data.

Contribution

It provides a comparative analysis of polydisperse living polymer brushes through simulation and experiment, demonstrating agreement with diffusion-limited aggregation theory and experimental force measurements.

Findings

Density profile declines as z^{-2/3}

Chain length distribution scales as N^{-7/4}

Force-distance behavior matches experimental data

Abstract

A comparative dynamic Monte Carlo simulation study of polydisperse living polymer brushes, created by surface initiated living polymerization, and conventional polymer monodisperse brush, comprising linear polymer chains, grafted to a planar substrate under good solvent conditions, is presented. The living brush is created by end-monomer (de)polymerization reaction after placing an array of initiators on a grafting plane in contact with a solution of initially non-bonded segments (monomers). At equilibrium, the monomer density profile \phi(z) of the LPB is found to decline as \phi(z) ~ z^{-\alpha} with the distance from the grafting plane z, while the distribution of chain lengths in the brush scales as c(N) ~ N^{-\tau}. The measured values \alpha = 0.64 and \tau = 1.70 are very close to those, predicted within the framework of the Diffusion-Limited Aggregation theory, \alpha = 2/3 and \tau = 7/4. At varying mean degree of polymerization (from L = 28 to L = 170) and effective grafting density (from \sigma_g = 0.0625 to \sigma_g = 1.0), we observe a nearly perfect agreement in the force-distance behavior of the simulated LPB with own experimental data obtained from colloidal probe AFM analysis on PNIPAAm brush and with data obtained by Plunkett et. al., [Langmuir 2006, 22, 4259] from SFA measurements on same polymer.