[1] H H Rossi, M Zaider. Microdosimetry and its applications(1996).

[2] A B Rosenfeld. Novel detectors for silicon based microdosimetry, their concepts and applications. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 809, 156-170(2016).

[3] J A Davis, M Petasecca, S Guatelli et al. Evolution of Diamond based Microdosimetry. Journal of Physics: Conference Series, 1154, 012007(2019).

[4] S K Yu, D Wang, X J Zhong et al. A theoretical comparison of silicon and diamond in microdosimetry. Journal of Instrumentation, 18, P01032(2023).

[5] J A Davis, S Guatelli, M Petasecca et al. Tissue equivalence study of a novel diamond-based microdosimeter for galactic cosmic rays and solar particle events. IEEE Transactions on Nuclear Science, 61, 1544-1551(2014).

[6] J A Davis, P Lazarakis, J Vohradsky et al. Tissue equivalence of diamond for heavy charged particles. Radiation Measurements, 122, 1-9(2019).

[7] D Bolst, S Guatelli, L T Tran et al. Correction factors to convert microdosimetry measurements in silicon to tissue in 12C ion therapy. Physics in Medicine and Biology, 62, 2055-2069(2017).

[8] J A Davis. Diamond microdosimetry for radioprotection applications in space(2015).

[10] B J McParland. Medical radiation dosimetry(2014).

[11] P Sigmund. Particle penetration and radiation effects(2006).

[12] Songke YU, Zhenjian XIE, Lin TANG et al. The experiment design of solid-state microdosimeter tissue equivalence conversion. Experimental Technology and Management, 40, 170-174(2023).

[13] S K Yu, W J Fan, L Tang et al. A method for converting microdosimetric spectra in diamond to tissue in proton therapy. Medical Physics, 49, 4743-4754(2022).