This work reports on the fabrication and characterization of a novel high-speed, low-noise X-ray Avalanche Photodiode based on III-V compound semiconductors operating over an extended photon energy range. These materials were suggested as their higher atomic numbers allow for the absorption of higher photon energies; hence, shorter response times can be achieved by growing APDs with thinner active regions. In addition, the use of staircase hetero-junctions enhances electron multiplication and results in lower noise if compared with conventional p-i-n diodes. In this work, molecular beam epitaxy was used to produce GaAs/AlGaAs APDs with separated absorption and multiplication regions. The multiplication region, separated from the absorption region by a δ p-doped layer of carbon, contains a staircase structure composed of nanometric layers of AlGaAs and GaAs, which alternate periodically. The periodic modulation of the band gap enables a well-defined charge multiplication and results in low multiplication noise. Several devices were characterized in terms of dark current, photocurrents generated utilizing visible and hard X-ray sources as well as noise generated under laser light.
Investigation of the behaviour of GaAs/AlGaAs SAM-APDs for synchrotron radiation / Nichetti, Camilla; Steinhartova, Tereza; Antonelli, Matias; Cautero, Giuseppe; Menk, Ralf Hendrik; Pilotto, Alessandro; Driussi, Francesco; Palestri, Pierpaolo; Selmi, Luca; Arfelli, Fulvia; Biasiol, Giorgio. - (2019). (Intervento presentato al convegno 13th International Conference on Synchrotron Radiation Instrumentation, SRI 2018 tenutosi a Taipei International Convention Center, twn nel 2018) [10.1063/1.5084695].
Investigation of the behaviour of GaAs/AlGaAs SAM-APDs for synchrotron radiation
Palestri, Pierpaolo;Selmi, Luca;
2019
Abstract
This work reports on the fabrication and characterization of a novel high-speed, low-noise X-ray Avalanche Photodiode based on III-V compound semiconductors operating over an extended photon energy range. These materials were suggested as their higher atomic numbers allow for the absorption of higher photon energies; hence, shorter response times can be achieved by growing APDs with thinner active regions. In addition, the use of staircase hetero-junctions enhances electron multiplication and results in lower noise if compared with conventional p-i-n diodes. In this work, molecular beam epitaxy was used to produce GaAs/AlGaAs APDs with separated absorption and multiplication regions. The multiplication region, separated from the absorption region by a δ p-doped layer of carbon, contains a staircase structure composed of nanometric layers of AlGaAs and GaAs, which alternate periodically. The periodic modulation of the band gap enables a well-defined charge multiplication and results in low multiplication noise. Several devices were characterized in terms of dark current, photocurrents generated utilizing visible and hard X-ray sources as well as noise generated under laser light.
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