I did not look at the link, not sure it's relevance to this thread, but some power transistors (FETs, BJTs, etc.) include explicit clamp diodes. They may be, but often are not, body diodes but rather extra diodes, either fabricated on the device die, or discretes added inside the package.
From that link:
Body diode
It can be seen in figure 1 that the source metallization connects both the N+ and P+ implantations, although the operating principle of the MOSFET only requires the source to be connected to the N+ zone. However, if it were, this would result in a floating P zone between the N-doped source and drain, which is equivalent to a
NPN transistor with a non-connected base. Under certain conditions (under high drain current, when the on-state drain to source voltage is in the order of some volts), this parasitic NPN transistor would be triggered, making the MOSFET uncontrollable. The connection of the P implantation to the source metallization shorts the base of the parasitic transistor to its emitter (the source of the MOSFET) and thus prevents spurious latching.
This solution, however, creates a
diode between the drain (cathode) and the source (anode) of the MOSFET, making it able to block current in only one direction.
Body diodes may be utilized as
freewheeling diodes for inductive loads in configurations such as
H-bridge or half bridge. While these diodes usually have rather high forward voltage drop, they can handle large currents and are sufficient in many applications, reducing part count, and thus, device cost and board space.
In fact most of the schematic symbols I use in my designs show that...
As to relevance, the
https://www.psemi.com/newsroom/pres...fastest-switching-speeds-to-gan-class-d-audio
the page mentions:
“GaN is disrupting traditional, power MOSFET markets and changing the way we live,” says Alex Lidow, CEO and co-founder of Efficient Power Conversion Corporation (EPC). “In class-D audio systems, the audio performance is impacted by the FET characteristics. Our enhancement-mode GaN (eGaN®) transistors enable a significant increase in the sonic quality and higher efficiency. High-speed FET drivers, like Peregrine’s PE29102, are critical to unlocking the performance potential of eGaN FET technology in applications like class-D audio.”
In the video that's on that page:
Mentions the "parasitic diode" - also known as "body diodes- as well as gate capacitance as a source of jitter in typical MOSFETS: