It depends a bit on what you think of as the optimization here. If you're thinking of it purely as "std::sort vs. qsort", then there are thousands of other similar optimizations. Using a C++ template can supports inlining in situations where essentially the only reasonable alternative in C is to use a pointer to a function and nearly no known compiler will inline the code being called. Depending on your viewpoint, this is either a single optimization, or an entire (open-ended) family of them.
Another possibility is using template meta-programming to turn something into a compile-time constant that would normally have to be computed at run-time with C. In theory, you could usually do this by embedding a magic number. This is possible via a
#define into C, but can lose context, flexibility or both (e.g., in C++ you can define a constant at compile time, carry out an arbitrary calculation from that input, and produce a compile-time constant used by the rest of the code. Given the much more limited calculations you can carry out in a
#define, that's not possible nearly as often.
Yet another possibility is function overloading and template specialization. These are separate, but give the same basic result: using code that's specialized to a particular type. In C, to keep the number of functions you deal with halfway reasonable, you frequently end up writing code that (for example) converts all integers to a
long, then does math on that. Templates, template specialization, and overloading make it relatively easy to use code that keeps the smaller types their native sizes, which can give a substantial speed increase (especially when it can enable vectorizing the math).
One last obvious possibility stems from simply providing quite a few pre-built data structures and algorithms, and allowing such things to be packaged for relatively easy, efficient re-use. I doubt I could even count the number of times I wrote code in C using what I knew were relatively inefficient data structures and/or algorithms, simply because it wasn't worth the time to find (or adapt) a more efficient one to the task at hand. Yes, if it really became a major bottleneck, I'd go to the trouble of finding or writing something better -- but doing a bit of comparing, it's still fairly common to see speed double when written in C++.
I should add, however, that all of these are undoubtedly possible with C, at least in theory. If you approach this from a viewpoint of something like language complexity theory and theoretical models of computation (e.g., Turing machines) there's no question that C and C++ are equivalent. With enough work writing specialized versions of each function, you can/could theoretically do all of those same things with C as you can with C++.
From a viewpoint of what code you can plan on really writing in a practical project, the story changes very quickly -- the limit on what you can do mostly comes down to what you can reasonably manage, not anything like the theoretical model of computation represented by the language. Levels of optimization that are almost entirely theoretical in C are not only practical, but quite routine in C++.