Here we report computational results from an off-lattice Monte Carlo investigation of the effective thermal transport properties in multiphase biological systems containing carbon nanomaterials. A three-phase system that consists of a cell, healthy tissue and carbon nanotubes (CNTs) was built in silico for this study. The CNTs were embedded in both the cell and the healthy tissue. The effective thermal conductivity (Keff) of such biological systems can be predicted by taking into account the dispersion of the CNTs and the interfacial thermal resistances (ITRs) between any pair of components. We quantitatively investigated the effects of the distribution (CNTs at different locations in the system), concentration (0.01–0.1 vol%), and morphology (diameter of 2–10 nm, length of 200–800 nm) of the CNTs on the Keff of the biological systems. Additionally, we studied the effects of the ITRs between any pair of components (0.05–76.5 × 10?8 m2 K W?1) on the Keff of the biological systems. The results showed that greater enhancement of the Keff values of the biological systems can be achieved by using longer CNTs in higher concentration, and reducing the ITRs between the CNTs and their surroundings. Finally, CNTs embedded on the cell membrane have a stronger effect than being dispersed within the cell or in the tissue surrounding the cell.
展开▼
机译:在这里,我们报告了对包含碳纳米材料的多相生物系统中有效传热特性的非格子蒙特卡洛研究的计算结果。在这项研究中,我们在计算机上构建了一个由细胞,健康组织和碳纳米管(CNT)组成的三相系统。碳纳米管嵌入细胞和健康组织中。此类生物系统的有效导热系数( K eff )可以通过考虑CNT的分散性和界面热阻来预测任意一对组件之间的(ITR)。我们定量研究了碳纳米管的分布(碳纳米管在系统中不同位置),浓度(0.01-0.1%(体积))和形态(直径2-10 nm,长度200-800 nm)对<生物系统的em> K eff 。此外,我们研究了ITR对任意一对组件之间的影响(0.05–76.5×10 ?8 m 2 K eff 上的small> KW ?1 )。结果表明,通过使用较高浓度的较长碳纳米管并减少碳纳米管的含量,可以更大程度地提高生物系统的 K eff 值。碳纳米管及其周围环境之间的ITR。最后,嵌入细胞膜中的CNT比分散在细胞内或细胞周围的组织中具有更强的作用。
展开▼
