Title :
A Focused Asymmetric Metal–Insulator–Metal Tunneling Diode: Fabrication, DC Characteristics and RF Rectification Analysis
Author :
Kwangsik Choi ; Yesilkoy, F. ; Geunmin Ryu ; Si Hyung Cho ; Goldsman, N. ; Dagenais, Mario ; Peckerar, M.
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Maryland, College Park, MD, USA
Abstract :
Asymmetric thin-film metal-insulator-metal (MIM) tunneling diodes have been demonstrated using the geometric field enhancement (GFE) technique in a Ni/NiO/Ni structure. The GFE technique provides several benefits: generating asymmetric tunneling currents, lowering tunneling resistance, increasing nonlinearity, enhancing the effective ac signal amplitude, and improving zero-bias rectifying performance. The GFE technique can be merged with a dissimilar electrode method and use surface plamon resonances for further performance improvement. In this paper, we disclose techniques for fully exploiting all these advantages. Detailed descriptions of process flows are provided. Performance improvements are experimentally verified by measuring the static current-voltage and dynamic (6.4 GHz) response of the developed Ni/NiO/Ni tunnel diodes.
Keywords :
MIM devices; microwave diodes; nickel compounds; surface plasmon resonance; tunnel diodes; AC signal amplitude; DC characteristics; GFE technique; MIM tunneling diodes; Ni-NiO-Ni; RF rectification analysis; dissimilar electrode method; focused asymmetric metal-insulator-metal tunneling diode; frequency 6.4 GHz; geometric field enhancement technique; static current-voltage measurement; surface plasmon resonances; tunneling resistance; Antennas; Electrodes; Junctions; Nickel; Resistance; Tunneling; Asymmetric tunneling diode; infrared energy conversion; metal–insulator–metal (MIM) tunneling diode; rectifier;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2011.2162414
