If by "laminated worktop" you mean HPL (or solid high pressure laminate), then you are into a whole different field. Softer plastics require the spindle speed to be reduced, often to 12k to 15k (assuming a hand held router with a standard 1/2in diameter 2-flute straight cutter), whilst the feed rate is increased as much as possible. The bigger the motor the better TBH. Harder plastics, such a phenolics, can be cut at slightly higher spindle speeds, but fed equally quickly. The idea is to create a stream of curled chips as opposed to dust
I personally won't tackle HPL or post formed laminate tops with anything less than 2000 watts of 1/2in router. Good dust extraction helps to keep the cutter cooler by reducing chip churn in the gullets. Solid upcut carbide spiral cutters do take less power, but require greater collet clamping pressure to avoid them being pulled out of the collet - so your collet needs to be in good order. Another downside is that they don't tolerate metalic or calcified inclusions in the chipboard core (if that is what you are cutting) chipping very badly if contact is made
Larger diameter cutters have more metal in them and bigger gullets, so the do run cooler - mainly a CNC thing, though.
On standard laminated chipboard worktops I've found that replaceable tip carbide cutters produce the best results - typically deWalt DWE625, 1/2in TC-RT @ circa 16 to 18k rpm, 3 incremental depth passes on the "off" side of the jig followed by a full depth cut (i.e. a 0.5 to 1mm cut) on the good side
As it happens any softer more deformable plastics such as nylon 66 or UHMW (aka high density polyethylene) benefit from making a flrst pass at 0.5 to 1mm oversize, conventional cut, followed by a final size cut at high feed, reduced spindle speed, but using a climb cut. So not for the router beginner and best performed on a CNC!