You seem a bit confused about how CPU's work. Assembly is not a separate language from machine code. It is simply a different (textual) representation of it.
Assembly code is simply a sequential listing of instructions to be executed. And machine code is exactly the same thing. Every instruction supported by the CPU has a certain bit-pattern that cause it to be executed, and it also has a textual name you can use in assembly code.
If I write
add $10, $9, $8 and run it through an assembler, I get the machine code for the add instruction, taking the values in registers 9 and 8, adding them and storing the result in register 10.
There is a 1 to 1 mapping between assembler and machine code.
There also are no "API calls". The CPU simply reads from address X, and matches the subsequent bits against all the instructions it understands. Once it finds an instruction that matches this bit pattern, it executes the instruction, and moves on to read the next one.
What you're asking is in a sense impossible or a contradiction. IL stands for Intermediate Language, that is, a kind of pseudocode that is emitted by the compiler, but has not yet been translated into machine code. But if the CPU could execute that directly, then it would no longer be intermediate, it would be machine code.
So the question becomes "is your IL code a better, more efficient representation of a program, than the machine code the CPU supports now?"
And the answer is most likely no. MSIL (I assume that's what you mean by IL, which is a much more general term) is designed to be portable, simple and consistent. Every .NET language compiles to MSIL, and every MSIL program must be able to be translated into machine code for any CPU anywhere. That means MSIL must be general and abstract and not make assumptions about the CPU. For this reason, as far as I know, it is a purely stack-based architecture. Instead of keeping data in registers, each instruction processes the data on the top of the stack. That's a nice clean and generic system, but it's not very efficient, and doesn't translate well to the rigid structure of a CPU. (In your wonderful little high-level world, you can pretend that the stack can grow freely. For the CPU to get fast access to it, it must be stored in some small, fast on-chip memory with finite size. So what happens if your program push too much data on the stack?)
Yes, you could make a CPU to execute MSIL directly, but what would you gain?
You'd no longer need to JIT code before execution, so the first time you start a program, it would launch a bit faster. Apart from that, though? Once your MSIL program has been JIT'ed, it has been translated to machine code and runs as efficiently as if it had been written in machine code originally. MSIL bytecode no longer exists, just a series of instructions understood by the CPU.
In fact, you'd be back where you were before .NET. Non-managed languages are compiled straight to machine code, just like this would be in your suggestion. The only difference is that non-managed code targets machine code that is designed by CPU designers to be suitable for execution on a CPU, while in your case, it'd target machine code that's designed by software designers to be easy to translate to and from.