There are a number of factors at play here, but it is unsurprising to be confused as most statistical problems do better with more data; assembly is unusual in falling apart.

One issue is with implementation. Every sequencing error creates a spray of new possibilities for the assembler; with many errors, the computational resources to sort these out grows with a worse than linear trend.

Many sequencing errors are not fully random either, so with more coverage the data is more likely to have repetitions of the same systematic error. Greater coverage is also more likely to generate very rare but very troublesome errors, such as chimaeric library members.

Also factoring into this is that at some point more data cannot actually help; the capability of a given technology on that genome will have been exhausted.

I think your guess about error rate is on track, though the class of error probably matters also (insertion/deletion vs. substitution). Error correcting stages upstream of assembly may also benefit from higher coverage that would cause problems for straight assembly.

thanks! it is more clear now!
so, if i have a 454 dataset with 300X coverage. and i subsampled it until 80X and then assemble. is a bad idea to use the (or part of the) excluded reads to extend contigs?

or would be better run several assemblies with 80X coverage datasets, but taking different randomly choosen reads and select the best assembly? (it could be a little time-consuming, i know )