The additional physical memory consumed will be effectively none at all. Until and unless the thread does work, the operating system won't waste physical memory holding its stack or related structures. (It will likely consume some physical memory, of course, because it will create the initial stack. But that can, and will, be paged out with no harm to performance if the thread isn't running.)
However, the thread's stack will consume virtual memory. You can tune the thread's maximum stack size, and it's the maximum stack size that controls how much virtual memory is consumed. If the thread just sits there, it's effectively free. It counts against virtual memory limits even though it consumes no real, limited resources.
If you encounter errors due to running out of virtual memory from thread stacks, probably your best option is to increase the virtual memory limit. The purpose of the virtual memory limit is to cap use of physical memory indirectly -- physical memory use won't exceed virtual memory use. But if you use programming patterns (like lots of threads) that consume virtual memory without corresponding use of physical memory, the limits just kick in when they shouldn't.
Of course, a 32-bit process is fundamentally limited to 2GB, 3GB, or 4GB of virtual memory (depending on the platform). So you may have no choice but to reduce the maximum thread stack size. (A thread immediately consumes virtual memory equal to its maximum stack size because the address space must be reserved even if it's never used.)
Reducing the maximum thread stack size is also an option. This is a compromise though. A larger maximum prevents the thread from causing an exception if it needs a lot of stack ever during its lifetime. And the only resource consumed is address space, which is ordinarily cheap. But the only practical limit you can impose on the program, to keep it from running low on physical memory and performing badly, is to limit virtual memory. So the knob you really want doesn't exist.