Surface characterization of plasma-treated and PEG-grafted PDMS for micro fluidic applications

Abstract

The contact angle measurements have shown that polydimethyl siloxane (PDMS) surfaces treated by air plasma can recover up to about 40% of its hydrophobic nature in less than 20 min of air exposure. Therefore, poly(ethylene glycol) (PEG) silane was grafted after plasma treatment to permanently change the PDMS surface as hydrophilic in nature for micro fluidic application. The surface chemistry of plasma-treated and PEG-grafted PDMS substrate has been studied using X-ray photoelectron spectroscopy (XPS). The proportion of carbon atoms as C–Si and hydrocarbon decreased for both plasma-treated as well as PEG-grafted PDMS surfaces. The plasma treatment had increased the proportion of carbon atoms as C O and C( O)OX in C1s, whereas grafting of PEG silane decreased the proportion of C( O)OX and an increase in C–OX and C O functionalities. This is due to the interaction of OCH 3 on Si (in PEG silane) with C–OX and C( O)OX on plasma-treated PDMS by covalent bonding. Therefore, an increase in C O and C–OX functionalities and relative decrease in C( O)OX is expected. The plasma treatment of micro channels had increased the fluid velocity by a factor or four and similar measurements were observed in PEG grafted micro channel in PDMS chip. This indicates that the fluid velocity depends on the hydrophilic nature of substrate. The effect of nature of fluids on the fluid velocity in PDMS-based micro channel was also studied. It was observed that the fluid velocity was decreased with decreasing the pH values of the fluid.