3 part Article!
Part I - Part II - Part III


The semiconductor industry's recent motivation to employ SOI (a 30 year-old theory) actually derives from current design changes which force engineers to rethink the MOS, and CMOS transistor all over. As microprocessors are scaled down, and transistors (or micro circuitry) "shrinks" the number of circuits increase in an ever diminutive amount of space. One might surmise a larger number of circuits populating less silicon real-estate would yield prima facie speed increases. However; the opposite is true, in many respects. As the number of transistors increases, so does the wiring, along which voltage travels, thereby increasing the time it takes signals, or voltage to reach a particular destination. Although copper is now implemented, this in itself is not adequate compensation. A more mundane approach was warranted, and SOI literally changes the properties (and topography) of semiconductors substrate around the switches themselves. Manufacturing technologies such as Nan topography, SOI wafer fab, and micro-architecture are now courting heavily, and for good reason soon they will be bedfellows. As the die shrinks, industry-wide manufacturing technologies must grow, and adapt with each advancement. Albeit unforeseen theoretical or real-world effects, all must be considered and must be measured:



It's clear the ramifications of the .09 micron architecture, and below will extend well beyond the microchip itself. This begs an industry wide recompense in order to improve equipment used for QC, voltage and other "back-line" related anomalies which can lead to failure. It's obviously not as simple as packing twice as many circuits into a given area, as the technology shrinks, the entire circuitry's electrical behavior changes, as does interaction with the treated silicon. This has given CPU manufacturers a run for their money, literally. As gates become smaller, and voltage drops, capacitance must be reduced, and one must try to curb leakage into other areas of the silicon. Capacitance and leakage become an increasingly difficult challenge. This is where the implementation of SOI wafers is becoming critical:



Although not named in the quote above, capacitance is evident in every type of electrical switch, otherwise known as the "transistor". Any material which can store electric current has capacitance. A microprocessor is fundamentally a large number of electronic gates, and switches which are either on or off (1 or 0) packed into a silicon substrate. Another term for these silicon/metal switches is MOS (Metal Oxide Semiconductor). In a MOS switch, when high voltage is applied to the metal "gate" the switch closes and current flows. You may also have heard the term CMOS. This is a Complimentary Metal Oxide Semiconductor; in this switch, (which works in a reversal of polarity), when high voltage is applied to the metal gate, the switch opens and current ceases to flow, when low voltage is applied to the gate the switch closes, and current flows, "complimenting" the behavior of the MOS. Both are used in current microprocessor core technology. Albeit a MOS or CMOS, prior to the switches ability to operate, all its internal "capacitance" must be charged. It actually takes longer to charge the switch, and then it does to turn it on and off. In the quote above pertaining to Silicon On Insulator technology, it describes SOI as improving the "communication," via "isolation," and this is crucial element SOI brings to the table. SOI technology places an "Insulator" upon those areas on each side of the gate which, (in prior technologies) having had "impurities" added to them, enable them to conduct charge.

The term "communication" as it is used in the quote above, infers there will be less capacitance, due to the insulation (oxide layer), which insulates static current from leaking into the surrounding silicon. This leakage not only slows the switch down (impairing communication) but static current equates to heat build-up. It's silicon's predilection to be so malleable as to either conduct or insulate electrical current which has made it the material of choice for so long in the semiconductor industry. It also makes it more susceptible to static current, leakage, and electro migration. As microprocessors now fall into the realm of nanotechnology, and the voltages with which they operate have become ever smaller, so new technologies have to be implemented: