Title :
New Process Development for Planar-Type CIC Tunneling Diodes
Author :
Choi, Kwangsik ; Yesilkoy, Filiz ; Chryssis, Athanasios ; Dagenais, Mario ; Peckerar, Martin
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Maryland, College Park, MD, USA
Abstract :
A planar-type conductor-insulator-conductor tunneling diode is developed using a boiling water process for surface oxidation. First, microsized bow-tie patterns are transferred on a doped polysilicon layer using e-beam lithography. After reactive ion etching, the polysilicon bow-tie pattern has a very narrow knot between two triangles. Using a buffered oxide etchant (BOE) solution, hydrogen silsesquioxane patterns and native oxide layer are etched. The knot is oxidized by a boiling water oxidation process. By repeating the BOE etch and oxidation, the bow-tie patterns are transformed into tunneling diodes with a very thin oxide barrier separating two polysilicon conductors. We show that the resulting structures follow the Simmons tunneling current-voltage relationship after boiling. Moreover, a high sensitivity of 31 V-1 is achieved at a bias voltage of 80 mV.
Keywords :
boiling; electron beam lithography; insulators; oxidation; sputter etching; tunnel diodes; boiling water oxidation process; buffered oxide etchant solution; conductor-insulator-conductor; doped polysilicon layer; e-beam lithography; hydrogen silsesquioxane patterns; microsized bow-tie patterns; native oxide layer; planar-type CIC tunneling diodes; reactive ion etching; surface oxidation; voltage 80 mV; Bow-tie antenna; metal–insulator–metal (MIM) diode; optical antenna; surface plasmon; surface plasmon resonance (SPR); tunneling diode;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2010.2049637
