# Anisotropic mechanical properties of Dodecanophene nanosheets with pre-existing cracks by molecular dynamics simulation: Uncovering orientation- and temperature-induced variations

**Authors:** Wei Li, Mohammad Azadi, Mohammad Azadi, Mohammad Azadi, Mohammad Azadi

PMC · DOI: 10.1371/journal.pone.0339525 · 2026-03-06

## TL;DR

This study uses simulations to explore how cracks and temperature affect the mechanical properties of Dodecanophene nanosheets, a new type of 2D carbon material.

## Contribution

The first systematic investigation of pre-existing crack effects on Dodecanophene's fracture mechanics across extreme thermal conditions.

## Key findings

- Dodecanophene nanosheets show anisotropic mechanical properties with higher stiffness in the y-direction and superior toughness in the x-direction.
- Crack orientation significantly impacts mechanical degradation, with perpendicular cracks causing greater strength loss than parallel cracks.
- Temperature strongly influences toughness, increasing by 160% at 200 K and decreasing by 65% at 1000 K.

## Abstract

This work presents a comprehensive molecular dynamics simulation study investigating the anisotropic mechanical response and fracture mechanisms of defective Dodecanophene nanosheets, a novel two-dimensional carbon allotrope. Using the AIREBO-M reactive force field validated against Density Functional Theory (DFT) calculations, we systematically evaluate the effects of crack orientation (0°–90°), temperature-dependent behavior (200–1000 K), and pre-existing crack size (30–60 Å) on elastic modulus, tensile strength, fracture toughness, and energy absorption. The nanosheets exhibit clear anisotropy: the y-direction shows higher stiffness (562.41 GPa) and strength (148.38 GPa), while the x-direction shows superior toughness (34.53 GPa). Crack orientation plays a critical role, with perpendicular cracks causing severe degradation (48.0–54.0%) compared to moderate losses (16–24%) for parallel cracks. Temperature-dependent behavior is pronounced, as toughness rises 160% at 200 K but declines 65.0% at 1000 K. Increasing pre-existing crack length drastically reduces strength (75.0–86.0%) and toughness (79.0–86.0%). Distinct failure modes emerge: x-loading promotes ductile behavior with crack deflection and gradual bond breaking, while y-loading induces brittle catastrophic fracture with rapid crack propagation. This represents the first systematic investigation of pre-existing crack effects on Dodecanophene’s fracture mechanics across extreme thermal conditions (200–1000 K), providing critical insights for defect-tolerant design of 2D carbon materials.

## Full-text entities

- **Diseases:** DFT (MESH:D001851), crack (MESH:D003387), Fracture (MESH:D050723), ORCID iD (MESH:C535742)
- **Chemicals:** graphdiyne (MESH:C000657226), 2D carbon (-), graphene (MESH:D006108), acetylene (MESH:D000114), benzene (MESH:D001554), cyclobutane (MESH:D003503), C (MESH:D002244)

## Figures

50 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12965698/full.md

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Source: https://tomesphere.com/paper/PMC12965698