Abstract
Computational investigation of interfacial failure in composite materials is challenging because it is inherently multi-scale: the bond-breaking processes that occur at the covalently bonded interface and initiate failure involve quantum mechanical phenomena, yet the mechanisms by which external stresses are transferred through the matrix occur on length and time scales far in excess of anything that can be simulated quantum mechanically. In this work, we demonstrate and validate an adaptive quantum mechanics (QM)/molecular mechanics simulation method that can be used to address these issues and apply it to study critical failure at a covalently bonded carbon nanotube (CNT)-polymer interface. In this hybrid approach, the majority of the system is simulated with a classical forcefield, while areas of particular interest are identified on-the-fly and atomic forces in those regions are updated based on QM calculations. We demonstrate that the hybrid method results are in excellent agreement with fully QM benchmark simulations and offers qualitative insights missing from classical simulations. We use the hybrid approach to show how the chemical structure at the CNT-polymer interface determines its strength, and we propose candidate chemistries to guide further experimental work in this area.
Highlights
The excellent mechanical properties of carbon fibrepolymer composites (CFPCs) make them remarkable and wellestablished structural materials
The majority of the system is simulated with a classical forcefield, while areas of particular interest are identified on-the-fly and atomic forces in those regions are updated based on quantum mechanics (QM) calculations
IV, we demonstrate the locality of quantum mechanical effects in carbon nanotube (CNT)/polymer systems; Sec
Summary
The excellent mechanical properties of carbon fibrepolymer composites (CFPCs) make them remarkable and wellestablished structural materials. The method is used to evaluate a variety of strategies for grafting polymer chains to the CNT surface and enables us to propose candidates chemistries that could be used to optimise the interfacial properties of high-performance CNPCs. The remainder of the paper is structured as follows: in Sec. II, we describe our novel hybrid simulation method; in Sec. III, we show the results of a dynamical study of the mechanism of load transfer at the CNT-polymer interface; in Sec. IV, we demonstrate the locality of quantum mechanical effects in CNT/polymer systems; Sec. V describes the QM/MM study of fracture in defective CNT, while Sec. VI contains the conclusions of this paper
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