Detail publikace

RTS in Submicron MOSFETs: Lateral Field Effect and Active Trap Position

Originální název

RTS in Submicron MOSFETs: Lateral Field Effect and Active Trap Position

Anglický název

RTS in Submicron MOSFETs: Lateral Field Effect and Active Trap Position

Jazyk

en

Originální abstrakt

Experiments were carried out for n-channel devices, processed in a 0.3 m spacerless CMOS technology. The investigated devices have a gate oxide thickness of 6 nm and the effective interface area is AG = 1.5 m2. The RTS measurements were performed for constant gate voltage, where the drain current was changed by varying the drain voltage. The capture time constant increases with increasing drain current. We will give a model explaining the experimentally observed capture time constant dependence on the lateral electric field and the trap position. From the dependence of the capture time constant c on the drain current we can calculate x-coordinate of the trap position. Electron concentration in the channel decreases linearly from the source to the drain contact. Diffusion current component is independent on the x-coordinate and it is equal to the drift current component for the low electric field. Lateral component of the electric field intensity is inhomogeneous in the channel and it has a minimum value near the source contact and increases with the distance from the source to the drain. It reaches maximum value near the drain electrode.

Anglický abstrakt

Experiments were carried out for n-channel devices, processed in a 0.3 m spacerless CMOS technology. The investigated devices have a gate oxide thickness of 6 nm and the effective interface area is AG = 1.5 m2. The RTS measurements were performed for constant gate voltage, where the drain current was changed by varying the drain voltage. The capture time constant increases with increasing drain current. We will give a model explaining the experimentally observed capture time constant dependence on the lateral electric field and the trap position. From the dependence of the capture time constant c on the drain current we can calculate x-coordinate of the trap position. Electron concentration in the channel decreases linearly from the source to the drain contact. Diffusion current component is independent on the x-coordinate and it is equal to the drift current component for the low electric field. Lateral component of the electric field intensity is inhomogeneous in the channel and it has a minimum value near the source contact and increases with the distance from the source to the drain. It reaches maximum value near the drain electrode.

BibTex


@article{BUT47684,
  author="Josef {Šikula} and Vlasta {Sedláková} and Miloš {Chvátal} and Jan {Pavelka} and Munecazu {Tacano} and Masato {Toita}",
  title="RTS in Submicron MOSFETs: Lateral Field Effect and Active Trap Position",
  annote="Experiments were carried out for n-channel devices, processed in a 0.3  m spacerless CMOS technology. The investigated devices have a gate oxide thickness of 6 nm and the effective interface area is AG = 1.5  m2. The RTS measurements were performed for constant gate voltage, where the drain current was changed by varying the drain voltage. The capture time constant increases with increasing drain current. We will give a model explaining the experimentally observed capture time constant dependence on the lateral electric field and the trap position. From the dependence of the capture time constant  c on the drain current we can calculate x-coordinate of the trap position. Electron concentration in the channel decreases linearly from the source to the drain contact. Diffusion current component is independent on the x-coordinate and it is equal to the drift current component for the low electric field. Lateral component of the electric field intensity is inhomogeneous in the channel and it has a minimum value near the source contact and increases with the distance from the source to the drain. It reaches maximum value near the drain electrode.",
  address="American Institute of Physics",
  chapter="47684",
  institution="American Institute of Physics",
  journal="AIP conference proceedings",
  number="1",
  volume="1129",
  year="2009",
  month="june",
  pages="205--208",
  publisher="American Institute of Physics",
  type="journal article"
}