Title :
Progress in quantum functional devices to overcome barriers to ULSI scaling
Author :
Goronkin, H. ; Tehrani, S. ; Shen, J. ; Kramer, G. ; Tsui, R.K.
Author_Institution :
Motorola Inc., Tempe, AZ, USA
Abstract :
Barriers to traditional scaling in silicon technology, primarily gate tunneling leakage current and drain-induced barrier lowering, will begin to emerge with the 1 Gb DRAM. Further scaling will involve performance fall-offs as critical dimensions are relaxed in order to reduce leakage currents. Compound semiconductor HFETs will suffer similar scaling penalties. Thin film SOI can extend silicon scaling by two or three generations. However, by the year 2000, a new technology will be necessary to continue the performance trend. That technology will likely utilize quantum effects to increase the functionality of individual electronic devices. The barriers to scaling MOSFETs and HFETs as well as examples of worldwide progress in developing quantum-based technology for future ULSI applications operating at room temperature are discussed.
Keywords :
ULSI; elemental semiconductors; field effect digital integrated circuits; integrated circuit technology; leakage currents; quantum interference devices; silicon; DRAM; HFETs; MOSFETs; Si; ULSI scaling; critical dimensions; drain-induced barrier lowering; gate tunneling leakage current; quantum effects; quantum functional devices; quantum-based technology; silicon technology; HEMTs; Leakage current; MODFETs; MOSFETs; Random access memory; Semiconductor thin films; Silicon; Temperature; Tunneling; Ultra large scale integration;
Conference_Titel :
Gallium Arsenide Integrated Circuit (GaAs IC) Symposium, 1994. Technical Digest 1994., 16th Annual
Conference_Location :
Phildelphia, PA, USA
Print_ISBN :
0-7803-1975-3
DOI :
10.1109/GAAS.1994.636906
