A block allocator does one large allocation to the free store/heap, it then internally splits this memory into chunks. One drawback here is that it allocates this chunk ( which needs to be large, and often user specified on a per use case basis ) straight up, so even if you don't use all of it, that memory is tied up. Secondly the standard memory allocator is built on top of new / delete, which in turn is often built on top of malloc / free. Although I don't recall whether malloc / free is guaranteed to be thread safe under all circumstances, it usually is.
But lastly the reason for why block allocators work so well is because they have information that is not present to the standard allocators, and they don't need to cover a very wide set of use cases. For example, if you did
std::map< int, int >() and it allocated 1mb you'd probably be pissed, but if you do
std::map< int, int, std::less< int >, block_alloc< 1024 * 1024 > >() you'd be expecting it. The standard allocators doesn't allocate in blocks, they request new memory via new, new in turn have no context at all. It gets a memory request of an arbitrary size and needs to find a contiguous number of bytes to return. What most implementations does is that they have a set of memory areas which they maintain of different multiples ( for example, a region for 4 bytes is more or less probably guaranteed to be present, as requests for 4 bytes is very common ). If a request isn't an even multiple it gets harder to return a good chunk without wasting space and cause fragmentation. Basically memory management of arbitrary sizes is very very hard to do if you want it to be close to constant time, low fragmentation, thread safe etc.
The Boost pool allocator documentation has some good info on how a good block allocator can work.