Any CPython object that has no references is immediately freed. Periodically, Python does a garbage collection to take care of groups of objects that refer only to each other but are not reachable by a program (cyclic references). You can call the garbage collector manually to clear those up if it needs to be done at a particular time (
gc.collect()). This makes the memory available for reuse by your Python script but may or may not immediately (or ever) release that memory back to the operating system.
CPython allocates memory in 256KB arenas that it divides into 4KB pools, which are further subdivided into blocks, which are designated for particular sizes of objects (these will generally be of similar type but need not be). This memory can be reused within the Python process but it doesn't get released back to the operating system until the entire arena is empty.
Now, before 2005 some commonly-used types of objects didn't use this scheme. For example, once you create an 'int' or a 'float', that memory was never returned to the OS even if it was freed by Python, but it could be reused for other objects of these types. (Of course small
ints are shared and don't take up any extra memory, but if you allocated, say, a list of large
ints, or of
floats, that memory would be retained by CPython even after those objects are freed.) Python also retained some memory allocated by lists and dictionaries (e.g. the most recent 80 lists).
This is all according to this document about improvements made to the Python memory allocator circa version 2.3. I understand some further work has been done since then, so some of the details may have changed (the
float situation has been rectified according to arbautjc's comment below) but the basic situation remains: for performance reasons, Python does not return all memory to the OS immediately, because
malloc() has relatively high overhead for small allocations, and gets slower the more fragmented memory is. Thus Python only
mallocs() large-ish chunks of memory and allocates memory within those chunks itself, and only returns these chunks to the OS when they are completely empty.
You might try alternative Python implementations, such as PyPy (which aims to be as compatible with CPython as possible), Jython (runs on JVM), or IronPython (runs on .NET CLR) to see if their memory management is more copacetic with what you're doing. If you are currently using a 32-bit Python, you could try a 64-bit one (assuming your CPU and OS support it).
However, your approach of calling your scripts sequentially from a shell script seems perfectly fine to me. You could use the
subprocess module to write the master script in Python, but it's probably simpler in the shell.
Without knowing more about what your script is doing, though, it's hard to guess what is causing this situation.