When one looks toward improving a program or snippet of code's performance (i.e. using a better algorithm to compute the same result), it is important to consider the visible output of the algorithm. That is to say how does the (output of the) algorithm get used or consumed? In other words, what does the algorithm return, and how is that return consumed?
The above steps in your question indicate that a list should be built, but then what? Were one to merely discard the results (you could easily write such a program or function), a good optimizer (human or machine) could substitute a null or empty program or function based on the fact that the result is never used. (Seriously: this is a common problem in benchmarks, an algorithm computes some result to measure performance of generated code but that result isn't used so the compiler removes potentially whole loops, memory allocations, maybe whole functions!)
So, what really matters regarding the setup of your question about the analysis of how to go about changing an algorithm for better performance is: to identify or specify the portion of the output that gets used (by some other part of the program).
Given a specification (of how the algorithm's results are consumed) we can work backward to find algorithmic improvements that yield the same results with less work.
When we compose algorithms, we can work thru the compositions to identify opportunities for improvement. Put another way, the algorithm you describe above might be used by some other algorithm to find only one value at a time, which means that Jeffry's solution is the appropriate better performing replacement algorithm.
However, a different consumer of your list algorithm may request a different part of its visible effect, and so a different optimization or algorithmic substitution might be appropriate. Such is the case as I describe above if the results are not used at all, and yet still, another consumer might just want to count the number of nodes in the list, in which case a wholly different optimization is more appropriate.
In some cases, we can specify that the algorithm returns something, and we are forced to generate code for one reason or another without knowing who is consuming the result. In those cases, an optimizer (human or machine) would be forced to make a pessimistic presumption that every visible effect that is returned is potentially consumed. For example, let's assume that the list is was what is returned (as additional specification in your the question), and we prevent any optimizer from seeing further into the consumption, we'd in all likelihood have to actually build the list (and so Jeffry's answer wouldn't work).
In short, we cannot fully analyze the problem and its solution space without additional context.
In part, that additional context takes the form of an explicit return statement (or some other externally visible side effect, such as modifying a global variable).
And further, some of that additional context may take the form of another algorithm that is enclosing, invoking or composing (with the original algorithm of interest); hence, the process of optimizing is recursive, and yields better results the more the (human or machine) can "see".