When programming you can think of atomic operations as conceptually parallel (while still satisfying the requirements of atomicity).
When optimizing it helps to be aware of serialization that might be occuring. What actually happens depends on the hardware you are running on. Performance depends on the location and number of atomic memory units, as well as the pattern of memory accesses being performed in parallel.
For example, if the locations that are addressed in parallel map to completely different atomic units, they will occur in parallel. If many addresses in parallel map to the same atomic unit, they must be serialized.
Atomic operation performance has improved consistently from sm_11 (Compute capability 1.1, where it first appeared), to sm_2x (Fermi devices), to sm_3x (Kepler devices). Kepler improved worst-case atomic memory operation performance (where many atomic operations access the same memory address) by up to 10X, and best case performance (where many atomic operations access very different memory addresses) by up to 2X. Atomic performance on Kepler is high enough that you may consider using atomics where previously you might have employed explicit parallel reduction code. See this presentation for more details.
Note: this discussion applies to global memory atomics. Shared memory atomics are a different beast, and in general result in serialization and are therefore do not have very high performance.