Highly scaled nanoelectronics requires effective channel doping above 5 à 1019cm-3together with ohmic contacts with extremely low specific contact resistivity. Nowadays, Ge becomes very attractive for modern optoelectronics due to the high carrier mobility and the quasi-direct bandgap, but n-type Ge doped above 5 à 1019cm-3is metastable and thus difficult to be achieved. In this letter, we report on the formation of low-resistivity ohmic contacts in highly n-type doped Ge via non-equilibrium thermal processing consisting of millisecond-range flash lamp annealing. This is a single-step process that allows for the formation of a 90 nm thick NiGe layer with a very sharp interface between NiGe and Ge. The measured carrier concentration in Ge is above 9 à 1019cm-3with a specific contact resistivity of 1.2 à 10-6Ω cm2. Simultaneously, both the diffusion and the electrical deactivation of P are fully suppressed.
In situ ohmic contact formation for n-type Ge via non-equilibrium processing
Frigerio, J.;BALLABIO, ANDREA;Isella, G.;
2017-01-01
Abstract
Highly scaled nanoelectronics requires effective channel doping above 5 à 1019cm-3together with ohmic contacts with extremely low specific contact resistivity. Nowadays, Ge becomes very attractive for modern optoelectronics due to the high carrier mobility and the quasi-direct bandgap, but n-type Ge doped above 5 à 1019cm-3is metastable and thus difficult to be achieved. In this letter, we report on the formation of low-resistivity ohmic contacts in highly n-type doped Ge via non-equilibrium thermal processing consisting of millisecond-range flash lamp annealing. This is a single-step process that allows for the formation of a 90 nm thick NiGe layer with a very sharp interface between NiGe and Ge. The measured carrier concentration in Ge is above 9 à 1019cm-3with a specific contact resistivity of 1.2 à 10-6Ω cm2. Simultaneously, both the diffusion and the electrical deactivation of P are fully suppressed.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.