Subthreshold slope

The subthreshold slope is a feature of a MOSFET's current–voltage characteristic.

In the subthreshold region, the drain current behaviour—though being controlled by the gate terminal—is similar to the exponentially decreasing current of a forward biased diode. Therefore, a plot of drain current versus gate voltage with drain, source, and bulk voltages fixed will exhibit approximately log-linear behaviour in this MOSFET operating regime. Its slope is the subthreshold slope.

The subthreshold slope is also the reciprocal value of the subthreshold swing S_s-th which is usually given as:^[1]

${\displaystyle S_{s-th}=\ln (10)\frac{kT}{q}(1+\frac{C_d}{C_{ox}})}$

${\displaystyle C_d}$ = depletion layer capacitance

${\displaystyle C_{ox}}$ = gate-oxide capacitance

${\displaystyle \frac{kT}{q}}$ = thermal voltage

The minimum subthreshold swing of a conventional device can be found by letting ${\displaystyle C_d\to 0}$ and/or ${\displaystyle C_{ox}\to \mathrm{\infty }}$, which yield ${\displaystyle S_{s-th,\min }=\ln (10)\frac{kT}{q}}$(known as thermionic limit) and 60 mV/dec at room temperature (300 K). A typical experimental subthreshold swing for a scaled MOSFET at room temperature is ~70 mV/dec, slightly degraded due to short-channel MOSFET parasitics.^[2]

A dec (decade) corresponds to a 10 times increase of the drain current I_D.

A device characterized by steep subthreshold slope exhibits a faster transition between off (low current) and on (high current) states.

• Optimization of Ultra-Low-Power CMOS Transistors; Michael Stockinger, 2000