Effects of Particle Size on the Dielectric, Mechanical, and Thermal Properties of Recycled Borosilicate Glass-Filled PTFE Microwave Substrates

Low dielectric loss and low-cost recycled borosilicate (BRS) glass-reinforced polytetrafluoroethylene (PTFE) composites were fabricated for microwave substrate applications. The composites were prepared through a dry powder processing technique by dispersing different micron sizes (25 mu m, 45 mu m, 63 mu m, 90 mu m, and 106 mu m) of the recycled BRS filler in the PTFE matrix. The effect of the filler sizes on the composites' thermal, mechanical, and dielectric properties was studied. The dielectric properties of the composites were characterised in the frequency range of 1-12 GHz using an open-ended coaxial probe (OCP) connected to a vector network analyser (VNA). XRD patterns confirmed the phase formation of PTFE and recycled BRS glass. The scanning electron microscope also showed good filler dispersion at larger filler particle sizes. In addition, the composites' coefficient of thermal expansion and tensile strength decreased from 12.93 MPa and 64.86 ppm/degrees C to 7.12 MPa and 55.77 ppm/degrees C when the filler size is reduced from 106 mu m to 25 mu m. However, moisture absorption and density of the composites increased from 0.01% and 2.17 g/cm(3) to 0.04% and 2.21 g/cm(3). The decrement in filler size from 106 mu m to 25 mu m also increased the mean dielectric constant and loss tangent of the composites from 2.07 and 0.0010 to 2.18 and 0.0011, respectively, while it reduced the mean signal transmission speed from 2.088 x 10(8) m/s to 2.031 x 10(8) m/s. The presented results showed that PTFE/recycled BRS composite exhibited comparable characteristics with commercial high-frequency laminates.

Automated summary

This study focused on the fabrication and characteristics of low dielectric loss and low-cost recycled borosilicate glass-reinforced polytetrafluoroethylene composites for microwave substrate applications. The impact of filler sizes on thermal, mechanical, and dielectric properties was explored, showing comparable characteristics with commercial high-frequency laminates.