In present-day microfluidic device manufacturing, producing good adhesion between PDMS and the silicon-containing mating surface is performed by plasma activation. This plasma activation of the microfluidic silicon-containing parts is the key process that enables covalent bonding without a traditional adhesive. Plasma activation can be performed to produce a bond at some low level of relative adhesion, or it can be optimized to a higher level of repeatable bond strength that provides an increased level of device performance and reliability. This subtle difference in plasma process optimization and control leads to increased adhesion and superior microfluidic device performance.
Choosing a plasma system designed for microfluidic device activation with the proper control, instrumentation, design, material selection, and process optimization is key to achieving the highest bond strength possible to produce the best performing microfluidic device.
A significant factor in controlling plasma activation of microfluidic devices is accurate pressure control during the plasma process. Precise pressure control of the process gas determines the concentration of oxygen plasma coming into contact with the PDMS surface and mating silicon-containing parts. This plasma process pressure control is performed by having an automatic process control loop between the pressure measurement instrumentation and the mass flow control valve controlling the gas flow into the vacuum chamber. This controlled injection of gas into the vacuum chamber is continuously adjusted. as the vacuum pump removes gas from the vacuum chamber to produce the desired process pressure. Plasma systems designed for plasma activation of microfluidic device components have careful consideration of process pressure control designed explicitly for activating PDMS. Fluctuation in plasma activation process pressure will result in fluctuations in the bond strength and burst pressure of the finished microfluidic devices.
The total time the PDMS and silicon-containing mating part are in the plasma determine the level of activation on the parts' surface. This optimized level of plasma activation leads to the optimized level of covalent bond strength. If the parts are not activated long enough, the activation energy is low, and the bond strength is low. If the parts are plasma-activated too long, the parts' surface will begin to etch, and the bond strength will be low. A narrow process window of activation time must be performed to optimize the covalent bond strength in plasma-activated PDMS and silicon-containing mating parts. Repeatedly controlling the plasm activation process time allows optimization and activation without beginning to etch the PDMS surface or its mating part. Accurate plasma activation process time provides an optimum and uniform bond in microfluidic devices.
Another thing required to turn this carefully controlled gas process into plasma is power. Power control during the plasma process allows the control of what percentage of the gas is in a plasma state and is chemically active in the plasma processing chamber. This percentage of chemically active gas in the plasma process is referred to as plasma disassociation efficiency. The plasma disassociation efficiency will determine the concentration of reactive oxygen plasma species in the chamber. This chemical activity rate will determine the chemical reaction at the PDMS surface and silicon-containing parts causing activation. If the power is too low, there will not be enough chemical reaction, and activation will be low. If the power is too high, the activation process will lead to etching and non-uniformity issues. When this concentration is correct for the proper amount of time, good surface energy and bond strength will be produced in your microfluidic device.
After the plasma activation of the PDMS and the silicon-containing mating part, the plasma chamber is vented. It is best to bond the samples as soon as possible after venting. The activated parts surfaces should contact without any deformation of the material or lateral motion of the parts relative to each other when touching. Often tooling is utilized for alignment and control of the bonding process. Attempting to peel a sample apart for realignment will not result in a bond. After alignment and bonding is performed, it is recommended to allow the devices to continue to bond for approximately 24 hours before testing. This additional time will increase the bond strength and burst pressure of the finished device.
As discussed in this article, accurate and repeatable plasma process controls are crucial to creating reliable plasma-activated PDMS parts for microfluidic device assembly. Carefully controlled plasma activation processes result in the optimization of bond strength and burst pressure in finished microfluidic devices. Identifying plasma systems with the correct capabilities to control these process parameters are important when selecting a plasma system for PDMS bonding and microfluidic device manufacturing.
To learn more about the best practices for plasma activation of microfluidic devices, please read our eBook titled "How to Improve Burst Pressure and Yield in Microfluidic Devices."