They can't cause a nuclear explosion, yes.
However, there are two general categories of fucking-it-up-real-bad in a nuclear reactor that ends in explosions (and the only two accidents that people really care about were either of the two variants!) if you don't do the right stuff at the right time, both are the result of failure to remove the heat load being generated by the reactor, but occur at different rates:
1) Power (heat) spikes rapidly in the reactor, causing coolant temperature to rise rapidly above saturation pressure, causing steam formation in the reactor coolant channels. Steam is understandably much worse at removing heat than water, then temperature starts increasing even faster, and the resultant super-heated vapor can increase pressure so rapidly that it causes a pressure explosion. Chernobyl did this (quite by accident - the plant did everything it was supposed to do; the guys running the show had no idea what Xenon-precluded startup was) by inserting way way too much moderator into the core, to the effect that the power overshoot could not be controlled and was exacerbated by something called control rod water hole power peaking, which has since dramatically changed the design of control rods. This reactor was too a boiling water reactor operating with something called a positive temperature coefficient of reactivity (basically, when coolant temperature changes, power follows that change) - this today is generally regarded as an unacceptable design choice regardless of safety measures in place, given that when power increases temperature increases which can too cause power to increase further, and if the safety system fails then you get a big fucken problem.
2) Heat is incapable of being removed over a longer period of time, even maintaining coolant saturation. Most of the structural metal in the reactor vessel itself is a Zirconium-Tin-(and very small doping by percentages other things) alloy (called Zircaloy). Zirconium nuclei have a comparatively small propensity for interacting with neutrons (a small microscopic cross section for absorption) which makes it an excellent choice for use in nuclear reactors, however in the presence of water at temperatures of ~800C(1500F), zirconium likes to start oxidizing rapidly by an exothermic reaction called zirconium-hydriding, where zirconium oxides and free hydrogen are formed, and typically pushes local temperatures past saturation. All of that hydrogen likes to collect in a bubble at the top of the core and generally presents a large backpressure to coolant flow, and if the core is in this condition you likely don't have forced flow via coolant pumps available for some reason or another, and this causes the process to rapidly increase and result in a hydrogen explosion. This is what happened at Fukushima. We were extremely fortunate to not have this happen at Three Mile Island, but were oh so close.
But yeah, nothing so spectacular as that gif.
