Diodes are very complex things, made up of Forward Voltage, Forward Current, Reverse Current, Reverse Voltage, Reverse Current leak and Recovery Times. And then all voltages and currents have steady-state values, repetitive peak values and non-repetitive peak values.
Everything always has influence.
The reason diodes often are only high current or high voltage is because a lot of the features of a diode are a trade-off.
If you want a diode with huge current capability and a very good reverse voltage specification you need much more silicon material and many more controls during the process than when you choose only one to optimise.
Now, I assume your 3-phase signal is somewhere in the 1 to 100Hz, since most 3-phase power applications are.
That's a pretty low frequency to a diode, so you can pretty much skip "reverse recovery time" and all those parameters. They mean how quickly the diode will start blocking current after it previously conducted, but to 100Hz power any recovery out there is fast.
You will want to make sure the diode can handle the voltage even if it isn't exactly what you expect. One thing, for example, you didn't specify if whether the 40V is AC or expected DC. I'll assume AC. In that case, with 3-phase, you will get an approximate DC voltage of 1.8 times (rounded up) that, which is 72VDC.
So your diode must at least have a reverse voltage of 80V, preferably over 100V.
Then, the forward voltage and current are linked.
On page 4, top left, of your second datasheet (the Microsemi diode) you can see that at 25 degrees junction temperature at 40A it will only have a forward voltage of 0.8V
That forward voltage is per one diode, yes.
The difference between Steady State forward current and peak non-repetitive forward current is that a very high current will make the diode drop a higher voltage and the total peak power for a 200A spike becomes well beyond 200W, even in your first diode.
For a very short duration, and only once, the diode can handle that amount of energy, but if you keep the current constant the energy dissipated will build up. That's why the first one can only handle 12A continuous, anything higher will make it heat up more than its internal design can get rid off.
Now, many diodes have a Repetitive Peak Current, based on a 2phase 60Hz or 50Hz rectification, which is a little higher than their steady state current, that's because a diode in a rectifier will only be used part of the time. Half in a 2-phase and one third in a 3-phase.
So if you can find a diode that has only 35A steady state, but allows for 50A or such (or preferably higher of course) of Repetitive Peak current you should be reasonably safe with your 40A specification, if your 3-phase signal isn't below 35Hz.
Ideally, a circuit breaker should never trip while carrying its rated current.
Looking further down the graph to where it should trip, we find that a 30 Amp breaker will trip in about 10 seconds if carrying 60 Amps (200% of rating). A short pulse of 200% overload (say, 5 seconds) will not cause a trip, but a continuous 200% overload will, after about 10 seconds.
The spec sheet states that that is a thermal breaker - something inside has to heat up before it will trip. There are also magnetic breakers which will operate much faster than the thermal types.
Best Answer
The breakers are likely rated for 40C (104F) ambient.That would be the meaning of 40C marked on the breaker. They are likely rated for connection to wire that has a 60/75C insulation temperature rating. That would also be marked on the breaker. The surface temperature of the breaker can be expected to be higher than the ambient temperature. A surface temperature of 47C should not be a problem if the ambient temperature is 40C, but 47C surface temperature in a 20C ambient could be a problem. That would mean the surface temperature has a 27C rise and would reach 67C in a 40C ambient. However the following information seems to indicate that the breaker is allowed to get hotter than the wire.
UL Surface Temperature Rise Limits
Non-metallic 60 deg. C
Metallic 35 deg. C
UL Terminal Temperature Rise
80% Rated CB 50 deg. C
100% Rated CB 60 deg. C
The above information was found in another forum, not directly from UL.