There are noticeable effects of low temperatures on many materials (for example, the classic liberty ship cracking - or the samauri sword issues in mainland China during winter) - but these are due to a ductile/brittle transition in ferrous metals - impeding dislocation movement. Mechanical properties under stress are affected - not electrical properties that remain after return to room temperature.

The notion that the atomic bonds weaken at low temperatures is actually backwards. Annealing of defects will take place at high temps, not low (just look at the kinetics). A good example of this is the quenching process for many materials. High temperature treatment can induce mucleation of new grains. If the material is cooled slowly, then the grains can grow, leading to a softer material. If it is instead quenched at a high cooling rate, then the fine grained structure is frozen in place. Increases in the rate of cooling and decreases in the final temperature increase the fineness of the structure. This is the opposite of what is often claimed.

From a materials engineering viewpoint, I'd find it highly suspect that there'd be any changes in tube materials, copper or especially semiconductors from a cryogenic treatment.

Rich