Wet Chemical Treatment and Mg Doping of p‐InP Surfaces for Ohmic Low‐Resistive Metal Contacts

Ebrahimzadeh, Masoud; Granroth, Sari; Vuori, Sami; Punkkinen, M.; Miettinen, Mikko; Punkkinen, Risto; Kuzmin, M.; Laukkanen, P.; Lastusaari, Mika; Kokko, K.

doi:10.1002/adem.202300762

Cited by 1 publication

(2 citation statements)

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“…Measurements of wet chemically treated III-V and Ge surfaces [174][175][176][177][178][179] also support that Si( 111) is an unusual case because the post heating in UHV is typically needed to increase a crystalline order and the formation of atomically smooth terraces on the etched surfaces. Another difference between Si and III-V is that Si surfaces have typically hydrogen termination after the wet chemistry while III-V surfaces become enriched by group-V element in chemical treatments.…”

Section: What Kind Of Properties Does Wet-chemically Cleaned Surfaces...mentioning

confidence: 99%

“…Extra group-V adsorbates can be removed at relative low temperatures in UHV [174][175][176][177][178]. For example, extra arsenic from GaAs at around 350 • C. However, recently it has been reported a surprising wet-chemically induced InP(100)c(2 × 2) surface which resembles atomically smooth Si (111), and which is expected to be hydrogen terminated after a proper HCl immersion [179]. Indeed, HCl-based etching solutions have been found to provide smoother surfaces for III-V and Ge, as compared to the F-containing wet chemistry [174][175][176][177][178][179][180].…”

Section: What Kind Of Properties Does Wet-chemically Cleaned Surfaces...mentioning

confidence: 99%

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Bridging the gap between surface physics and photonics

Laukkanen,

Punkkinen,

Kuzmin

et al. 2024

Rep. Prog. Phys.

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Use and performance criteria of photonic devices increase in various application areas such as information and communication, lighting, and photovoltaics. In many current and future photonic devices, surfaces of a semiconductor crystal are a weak part causing significant photo-electric losses and malfunctions in applications. These surface challenges, many of which arise from material defects at semiconductor surfaces, include signal attenuation in waveguides, light absorption in light emitting diodes, non-radiative recombination of carriers in solar cells, leakage (dark) current of photodiodes, and light reflection at solar cell interfaces for instance. To reduce harmful surface effects, the optical and electrical passivation of devices has been developed for several decades, especially with the methods of semiconductor technology. Because atomic scale control and knowledge of surface-related phenomena have become relevant to increase the performance of different devices, it might be useful to enhance the bridging of surface physics to photonics. Toward that target, we review some evolving research subjects with open questions and possible solutions, which hopefully provide example connecting points between photonic device passivation and surface physics. One question is related to the properties of the wet chemically cleaned semiconductor surfaces which are typically utilized in device manufacturing processes, but which appear to be different from crystalline surfaces studied in ultrahigh vacuum by physicists. In devices, a defective semiconductor surface often lies at an embedded interface formed by a thin metal or insulator film grown on the semiconductor crystal, which makes the measurements of its atomic and electronic structures difficult. To understand these interface properties, it is essential to combine quantum mechanical simulation methods. This review also covers metal-semiconductor interfaces which are included in most photonic devices to transmit electric carriers to the semiconductor structure. Low-resistive and passivated contacts with an ultrathin tunnelling barrier are an emergent solution to control electrical losses in photonic devices.

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