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Autoren:
Lin, Jun; Monaghan, Scott; Sakhuja, Neha; Gity, Farzan; Kumar Jha, Ravindra; Coleman, Emma; Connolly, James; Cullen, Conor; Walsh, Lee; Mannarino, Teresa; Schmidt, Michael; Sheehan, Brendan; Düsberg, Georg; Mc Evoy, Niall; Bhat, Navakanta; Hurley, Paul; Povey, Ian; Bhattacharjee, Shubhadeep 
Dokumenttyp:
Konferenzbeitrag / Conference Paper 
Titel:
Chemical Vapor Deposition of MoS2 for Back-End-of-Line Applications 
Titel Konferenzpublikation:
240th ECS Meeting October 10, 2021 - October 14, 2021 
Reihentitel:
ECS Meeting Abstracts 
Bandnummer Reihe:
MA2021-02 
Konferenztitel:
ECS Meeting (240., 2021, online) 
Jahr der Konferenz:
2021 
Datum Beginn der Konferenz:
10.10.2021 
Datum Ende der Konferenz:
14.10.2021 
Verlag:
IOP Publishing 
Jahr:
2021 
Seiten von - bis:
1952 
Sprache:
Englisch 
Abstract:
2D transition metal dichalcogenides (TMDs) exhibit electronic properties from semimetals to wide bandgap semiconductors due to their thickness dependent bandgap. This property opens a wide diversity of applications that can be made from TMDs. For 3D heterogeneous integration of TMDs into the back-end-of-line (BEOL) of Si complementary metal-oxide-semiconductor circuitry, wafer-level direct growth (without film transfer) of TMDs within the BEOL thermal budget limit (550 °C/2 hours or 500 °C/5 hours [1]) is essential. In the literature, the majority of the TMDs (e.g. MoS2) are achieved from high temperature (650 °C - 1100 °C) deposition/anneal processes that are not compatible with BEOL [2]. In this work, MoS2 is successfully grown by chemical vapor deposition (CVD) approximately at/below BEOL thermal budget limit. We explore the potential of the achieved MoS2 films for BEOL logic (i.e … 
Article-ID:
1952 
Fakultät:
Fakultät für Elektrotechnik und Informationstechnik 
Institut:
EIT 2 - Institut für Physik 
Professur:
Düsberg, Georg 
Open Access ja oder nein?:
Ja / Yes