HIGH PERFORMANCE III-NITRIDE ULTRAVIOLET AVALANCHE PHOTODETECTORS
Author(s)
Jeong, Hoon
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Abstract
In this dissertation, two projects are demonstrated: 1) Al0.6Ga0.4N p-i-n avalanche
photodiode (APD) and 2) the low-temperature Geiger-mode measurement system for a GaN p-i-n
APD. In the first project, the AlGaN APD structure is designed, grown by metalorganic chemical
vapor deposition on an aluminum nitride (AlN) bulk substrate and on two different crystalline
quality AlN/sapphire templates. The AlGaN APD structure is then fabricated into circular devices
with a diameter of 20 um starting with 1) reactive-ion etching (RIE) of mesa structure 2) n-type
and p-type metal stacks patterning with electron-beam evaporation, 3) passivation of the surface
with plasma enhanced chemical vapor deposition (PECVD) silicon oxide and RIE etching for via
holes, and 4) metal pads deposition for wire-bonding. The APD devices showed the reverse
breakdown voltage around -140V, which corresponds to a breakdown electric field of
6~6.2MV/cm for the Al0.6Ga0.4N material as estimated by TCAD Silvaco simulation. The APD
devices grown on the AlN bulk substrate exhibited the lowest leakage current density below
1 × 10଼𝐴/𝑐𝑚ଶ
compared to that of the devices grown on the AlN templates. The maximum
photocurrent gain of 1.2 × 10ସ
at 250nm of light was calculated. The average temperature
coefficients of the breakdown voltage are negative for the APD devices but these data show that
the coefficient is the largest with the devices grown on the low-dislocation-density AlN bulk
substrate. in the second project, the low-temperature Geiger-mode measurement system was
constructed by integrating a device driver circuit system, an ultraviolet (UV) illumination system,
and a low-temperature control system. The principle of single-photon detection is studied based
on the Poisson statistics. In the low temperature control system, a thermoelectric cooler module
was used to control the temperature of the device in the range of -40 to 20°C. With the constructed
Geiger-mode measurement system, the temperature dependence of the breakdown voltage of the
GaN APD was measured 0.0159 ± 0.0034 V/K. Dark count rate (DCR) as a function of different
temperature set points was exhibited and discovered that the dominant mechanism contributing to
the DCR of the GaN APD is band-to-band tunneling. Finally, the photon detection efficiency (PDE)
of the APD as a function of excess bias at different temperature set points was exhibited and found
that the PDE is independent of the temperature set points.
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Date
2022-01-04
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Dissertation