Controlling recast layer and material removal in reverse µEDM for sustainable fabrication of microelectrode arrays

Abstract: Microelectrode arrays (MEAs) are essential for researching neurons and heart tissue because they record and stimulate neuronal activity. For manufacturing MEAs on conductive materials, reverse microelectrical discharge machining, or reverse µEDM, presents a viable method. However, achieving precise MEAs requires control over recast layers generated during micromachining. This study focuses on recast layer thickness (RLT) and material removal rate (MRR) as key performance indicators for sustainable reverse µEDM… Show more

“…In other words, in contrast to traditional machining techniques, the micro EDM technique demonstrates a concurrent trade-off between machining efficiency and accuracy: the geometric accuracy of the microholes improves as the machining time decreases. Researchers have developed auxiliary processing techniques to remove interelectrode debris, such as the vibration and rotation of electrodes [14][15][16], which have shown some improvement, but still cannot completely avoid the accumulation of discharge debris in the interelectrode gap [17,18].…”

Pulsed power supply of Tr-RC and Tr-RLC topologies for improvement of micro electrical discharge machining

“…In other words, in contrast to traditional machining techniques, the micro EDM technique demonstrates a concurrent trade-off between machining efficiency and accuracy: the geometric accuracy of the microholes improves as the machining time decreases. Researchers have developed auxiliary processing techniques to remove interelectrode debris, such as the vibration and rotation of electrodes [14][15][16], which have shown some improvement, but still cannot completely avoid the accumulation of discharge debris in the interelectrode gap [17,18].…”

Pulsed power supply of Tr-RC and Tr-RLC topologies for improvement of micro electrical discharge machining