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Thermal conductivity of polyacrylonitrile nanofibre web in various nanofibre diameters and surface densities

Thermal conductivity of polyacrylonitrile nanofibre web in various nanofibre diameters and surface densities

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© The Institution of Engineering and Technology
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The effects of variation in average nanofibre diameter and nanofibre web surface density on thermal conductivity of polyacrylonitrile nanofibre web was investigated in this study. The results demonstrate using thinner nanofibres results in a lower limit of thermal conductivity, better thermal insulation performance and a higher amount of Rosseland mean extinction coefficient that means lower radiative conductivity. It can be related to higher specific surface of thinner nanofibres that means more surface area for radiative scatter and absorption leading to lower conductivity. With the increase in the surface density of nanofibre web, thermal conductivity reduced and water vapour transmission rate and thermal insulation ability improved. Higher porosity percentage and smaller pore size in the web with higher surface density could result in lower thermal conductivity.

Inspec keywords: nanofibres; nanofabrication; thermal conductivity; surface structure; porosity; nanoporous materials; resins; extinction coefficients; polymer fibres; thermal insulating materials

Other keywords: nanofibre diameters; radiative absorption; radiative scatter; surface area; nanofibre web surface density; thermal insulation ability; thermal conductivity; radiative conductivity; polyacrylonitrile nanofibre web; pore size; water vapour transmission rate; Rosseland mean extinction coefficient; porosity

Subjects: Methods of nanofabrication and processing; Low-dimensional structures: growth, structure and nonelectronic properties; Optical properties of organic compounds and polymers (thin films, low-dimensional and nanoscale structures); Structure of solid clusters, nanoparticles, nanotubes and nanostructured materials; Nonelectronic thermal conduction and heat-pulse propagation in nonmetallic solids; Structure of polymers, elastomers, and plastics; Preparation of organic materials, polymers and plastics; Structure of powders and porous materials; Solid surface structure; Optical constants and parameters (condensed matter)

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