So I've had at least two professors mention that backtracking makes an algorithm nondeterministic without giving too much explanation into why that is. I think I understand how this happens, but I have trouble putting it into words. Could somebody give me a concise explanation of the reason for this?

It's not so much the case that backtracking makes an algorithm nondeterministic. Rather, you usually need backtracking to process a nondeterministic algorithm, since (by the definition of nondeterministic) you don't know which path to take at a particular time in your processing, but instead you must try several. 


I'll just quote wikipedia:
Out of the Nondeterministic Programming article. 


Consider an algorithm for coloring a map of the world. No color can be used on adjacent countries. The algorithm arbitrarily starts at a country and colors it an arbitrary color. So it moves along, coloring countries, changing the color on each step until, "uh oh", two adjacent countries have the same color. Well, now we have to backtrack, and make a new color choice. Now we aren't making a choice as a nondeterministic algorithm would, that's not possible for our deterministic computers. Instead, we are simulating the nondeterministic algorithm with backtracking. A nondeterministic algorithm would have made the right choice for every country. 


The running time of backtracking on a deterministic computer is factorial, i.e. it is in O(n!). Where a nondeterministic computer could instantly guess correctly in each step, a deterministic computer has to try all possible combinations of choices. Since it is impossible to build a nondeterministic computer, what your professor probably meant is the following: A provenly hard problem in the complexity class NP (all problems that a nondeterministic computer can solve efficiently by always guessing correctly) cannot be solved more efficiently on real computers than by backtracking. The above statement is true, if the complexity classes P (all problems that a deterministic computer can solve efficiently) and NP are not the same. This is the famous P vs. NP problem. The Clay Mathematics Institute has offered a $1 Million prize for its solution, but the problem has resisted proof for many years. However, most researchers believe that P is not equal to NP. A simple way to sum it up would be: Most interesting problems a nondeterministic computer could solve efficiently by always guessing correctly, are so hard that a deterministic computer would probably have to try all possible combinations of choices, i.e. use backtracking. 


Thought experiment: 1) Hidden from view there is some distribution of electric charges which you feel a force from and you measure the potential field they create. Tell me exactly the positions of all the charges. 2) Take some charges and arrange them. Tell me exactly the potential field they create. Only the second question has a unique answer. This is the nonuniqueness of vector fields. This situation may be in analogy with some nondeterministic algorithms you are considering. Further consider in math limits which do not exist because they have different answers depending on which direction you approach a discontinuity from. 


If you allow backtracking you allow infinite looping in your program which makes it nondeterministic since the actual path taken may always include one more loop. 


NonDeterministic Turing Machines (NDTMs) could take multiple branches in a single step. DTMs on the other hand follow a trialanderror process. You can think of DTMs as regular computers. In contrast, quantum computers are alike to NDTMs and can solve nondeterministic problems much easier (e.g. see their application in breaking cryptography). So backtracking would actually be a linear process for them. 


I wrote a maze runner that uses backtracking (of course), which I'll use as an example. You walk through the maze. When you reach a junction, you flip a coin to decide which route to follow. If you chose a dead end, trace back to the junction and take another route. If you tried them all, return to the previous junction. This algorithm is nondeterministic, non because of the backtracking, but because of the coin flipping. Now change the algorithm: when you reach a junction, always try the leftmost route you haven't tried yet first. If that leads to a dead end, return to the junction and again try the leftmost route you haven't tried yet. This algorithm is deterministic. There's no chance involved, it's predictable: you'll always follow the same route in the same maze. 


I like the maze analogy. Lets think of the maze, for simplicity, as a binary tree, in which there is only one path out. Now you want to try a depth first search to find the correct way out of the maze. A non deterministic computer would, at every branching point, duplicate/clone itself and run each further calculations in parallel. It is like as if the person in the maze would duplicate/clone himself (like in the movie Prestige) at each branching point and send one copy of himself into the left subbranch of the tree and the other copy of himself into the right subbranch of the tree. The computers/persons who end up at a dead end they die (terminate without answer). Only one computer will survive (terminate with an answer), the one who gets out of the maze. The difference between backtracking and nondeterminism is the following. In the case of backtracking there is only one computer alive at any given moment, he does the traditional maze solving trick, simply marking his path with a chalk and when he gets to a dead end he just simply backtracks to a branching point whose sub branches he did not yet explore completely, just like in a depth first search. IN CONTRAST : A non deteministic computer can clone himself at every branching point and check for the way out by running paralell searches in the sub branches. So the backtracking algorithm simulates/emulates the cloning ability of the nondeterministic computer on a sequential/nonparallel/deterministic computer. 

