Ring and Linear Copolymer Blends under Confinement

Abstract: The behavior of dense mixtures of two topologically different diblock-copolymer (CP) chains, viz., linear(L)-CP and ring(R)-CP of same molecular weight which forms lamellae is studied under confinement by two non-selective substrates. The effect of varying interaction strength between L-CP and R-CP, from purely repulsive (demixed state) to weakly attractive (mixed state), on the morphology, domain size, chain conformations and distribution of chains in the film are investigated. In the demixed state, collectiv… Show more

“…In this section, we study how the domain size of charged DBCs changes when the charge fraction of A‐block is varied. Here, we employ box counting method [ 27,28 ] to compute the domain sizes. In this approach, we calculate the concentration of A‐monomers ρ A in a sphere of radius r drawn at a random position within our simulation box.…”

“…In this section, we study how the domain size of charged DBCs changes when the charge fraction of A-block is varied. Here, we employ box counting method [27,28] to compute the domain sizes.…”

Phase and Order Behavior of Charged Asymmetric Diblock‐Copolymer Melts in Bulk

“…In this section, we study how the domain size of charged DBCs changes when the charge fraction of A‐block is varied. Here, we employ box counting method [ 27,28 ] to compute the domain sizes. In this approach, we calculate the concentration of A‐monomers ρ A in a sphere of radius r drawn at a random position within our simulation box.…”

“…In this section, we study how the domain size of charged DBCs changes when the charge fraction of A-block is varied. Here, we employ box counting method [27,28] to compute the domain sizes.…”

Phase and Order Behavior of Charged Asymmetric Diblock‐Copolymer Melts in Bulk

“…In this regard, ring or cyclic polymer, a topologically constrained chain made by closing the chain ends of a linear polymer and thus no chain ends, is relevant not only in physics, but also in biology as a model system for chromatin folding and existence of chromosome territories. [4][5][6][7] DOI: 10.1002/mats. 202200074 The existance of circular topology in biopolymer, e.g., in DNA of bacteriophage, ϕX174, was observed as early as 1964.…”

“…In this regard, ring or cyclic polymer, a topologically constrained chain made by closing the chain ends of a linear polymer and thus no chain ends, is relevant not only in physics, but also in biology as a model system for chromatin folding and existence of chromosome territories. [ 4–7 ]…”

Effect of Topology on the Collapse Transition and the Instantaneous Shape of a Model Heteropolymer