You state that the speed of the algorithm is not important, but actually it's essential.
A lot depends on the definition of 'secure',
SHA512 is (just about) impossible to reverse, but actually it's fairly easy to brute force attack it.
This is because it is fast - you could think of it as a fundamental design flaw of the SHA 'family' in that they're designed to be very quick.
This is a problem -
SHA512 achieves it's design goal of being very fast (it's not much slower than
SHA1) but if you're a hacker trying brute force passwords that makes it easier to crack. 10 or even 5 years ago a serious brute force attack would have been out of the question, now it's a couple of fancy graphics cards or some cloud time.
This is where key-stretching algorithms come in - they make the process of building a password hash deliberately slow. Slow enough that users checking an individual hash won't notice but a brute force attack will take too long.
A good example of a key-stretching algorithm is RFC2898 or PBKDF2 - it uses a long salt and executes an SHA algorithm thousands of times to create a hash that's slow to reproduce.
.Net has a native implementation of this:
They use it for
System.Web.Crypto.HashPassword, but you can easily review their source to use that elsewhere.
On my machine now (a fairly rubbish old laptop) a single .Net
Rfc2898DeriveBytes hash with 1000 iterations (the default) takes around 50ms, while I can brute force around 250,000 SHA512 hashes in a second.
So in .Net right now the most secure option is to use
However RFC2898/PBKDF2 does have a weakness - while it is slow parallel computing is getting cheaper and cheaper and it doesn't take much memory to build each hash. Right now it's pretty un-brute-forceable, but in 5 or 10 years?
So the next generation are algorithms like bcrypt/scrypt that are designed to use a lot of memory for each hash, making parallel executions expensive. While there are .Net implementations there isn't a native one (yet) and I'd be wary of using one until there is - using these will affect loads of things like concurrent log-ons (if used for passwords) and so introduce a lot of risk for early adopters.