S.P. Klepner scite author profile

Some transistor defects show a tendency to occur near the edges of emitters. Like ’’area defects’’, these ’’edge defects’’ occur in silicon wafers in a distribution pattern reminiscent of thermal-stress-induced dislocations. A peculiar feature is that often a number of edge defects which are close replicas of one another occur in a string, each in one of the neighboring emitters. Such edge defects are preponderant in transistors having silicon nitride surface films. In our proposed model, these emitter edge defects are generated when thermal-stress-induced dislocations glide through a row of emitters and interact with the emitter edge stresses, thereby, and under appropriate conditions, casting off small dislocation half-loops which straddle the edges. The model is shown to be consistent with all the observed phenomena pertaining to the emitter edge defect. To provide a foundation for the discussion of the finer details of the emitter edge defects, we also present an analysis of the nature and distribution of thermally induced dislocations, itself a topic of general interest.

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Submicrometer-channel CMOS for low-temperature operation

Sun

Taur

Dennard

et al. 1987

IEEE Trans. Electron Devices

123

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Source—Drain contact resistance in CMOS with self-aligned TiSi₂

Taur

Sun

Moy

et al. 1987

IEEE Trans. Electron Devices

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S.P. Klepner

A 2-ns cycle, 3.8-ns access 512-kb CMOS ECL SRAM with a fully pipelined architecture

0.5&#181;m-channel CMOS technology optimized for liquid-nitrogen-temperature operation

Dislocation propagation and emitter edge defects in silicon wafers

Submicrometer-channel CMOS for low-temperature operation

Source—Drain contact resistance in CMOS with self-aligned TiSi₂

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About

S.P. Klepner

A 2-ns cycle, 3.8-ns access 512-kb CMOS ECL SRAM with a fully pipelined architecture

0.5&amp;#181;m-channel CMOS technology optimized for liquid-nitrogen-temperature operation

Dislocation propagation and emitter edge defects in silicon wafers

Submicrometer-channel CMOS for low-temperature operation

Source—Drain contact resistance in CMOS with self-aligned TiSi2

Contact Info

Product

Resources

About

0.5µm-channel CMOS technology optimized for liquid-nitrogen-temperature operation

Source—Drain contact resistance in CMOS with self-aligned TiSi₂