@Bergi is correct. More operations is more time. Why? More CPU clock cycles.
Time is really a reference to how many clock cycles it takes to execute the code.
In order to get to the nitty-gritty of that you need to look at the machine level code (like assembly level code) to find the true evidence. Each CPU (core?) clock cycle can execute one instruction, so how many instructions are you executing?
I haven't counted the clock cycles in a long time since programming Motorola CPUs for embedded applications. If your code is taking longer then it is in fact generating a larger instruction set of machine code, even if the loop is shorter or runs an equal amount of times.
Never forget that your code is actually getting compiled into a set of commands that the CPU is going to execute (memory pointers, instruction-code level pointers, interrupts, etc.). That is how computers work and its easier to understand at the micro controller level like an ARM or Motorola processor but the same is true for the sophisticated machines that we are running on today.
Your code simply does not run the way you write it (sounds crazy right?). It is run as it is compiled to run as machine level instructions (writing a compiler is no fun). Mathematical expression and logic can be compiled in to quite a heap of assembly, machine level code and that is up to how the compiler chooses to interpret it (it is bit shifting, etc, remember binary mathematics anyone?)
A masters in CS and you will get to counting clock cycles and sort times. You will likely make you own language framed on machine instruction sets.
Most people say who cares? Memory is cheap today and CPUs are screaming fast and getting faster.
But there are some critical applications where 10 ms matters, where an immediate interrupt is needed, etc.
Commerce, NASA, a Nuclear power plant, Defense Contractors, some robotics, you get the idea . . .
I vote let it ride and keep moving.