Charge Collection in SOI Microdosimeters and Their Radiation Hardness

A new batch of microdosimeters has been extensively studied for their charge collection efficiency (CCE) properties, as well as their radiation hardness for medical, space and accident applications. Silicon-on-insulator (SOI) microdosimeters with an active layer thickness of 10, 20, and 50 mu m have been investigated and were characterized with a 24 MeV carbon ion beam as well as a Co-60 gamma source. A negative pulse was observed in addition to the positive pulses generated within the sensitive volumes (SVs) by incident ions which led to undesirable low energy events in the SOI microdosimeters response. To study this phenomenon, the microdosimeters were irradiated with gamma radiation from a Co-60 source with a total dose of 3 and 10 Mrad(Si). It was determined that the negative pulse was originating from the support wafer due to the displacement current phenomenon. Irradiation with the Co-60 source led to a disappearance of the negative pulse due to an increase in recombination within the support wafer while almost no changes in CCE were observed. A radiation hardness study was also performed on the 50 mu m SOI microdosimeter with 16 SVs being irradiated with a fluence of similar to 10(8) C-12 ions/cm(2). A CCE deficit of approximately 2% was observed at an operation bias of 10 V within the SVs. The findings of this work demonstrate that the SOI microdosimeters can be utilized in space and medical applications as they can handle typical levels of dose encountered in these applications. Additionally, evidence for SOI microdosimeter fabrication standards in terms of support wafer resistivity and buried oxide (BOX) thickness is shown.

Automated summary

A new batch of microdosimeters was studied for their charge collection efficiency (CCE) and radiation hardness for various applications. The microdosimeters were characterized with different ion beams and a gamma source, and a negative pulse was observed in addition to the positive pulses generated by incident ions. It was determined that the negative pulse originated from the support wafer due to the displacement current phenomenon. Radiation hardness study showed a slight CCE deficit, but overall the microdosimeters were found suitable for space and medical applications.