Because SHA-256 is a bit-mixing algorithm, I don't think quantum computing would lend itself to cracking it any easier than traditional means. I haven't seen any algorithm suggested that would help to solve any hashing algorithm. IOW, QC isn't magic that spits out results for any given problem.

I think QC will even have a problem solving the Discrete Logarithm Problem for Elliptic Curve, because each point in the field is random compared the the adjacent scalar values in the underlying group.

EC is like having a huge stack of papers that are all in the wrong order. For example, the first page may be labeled 1,323, the second page is labeled 75, the third page is 7,888... etc. You can easily count through the stack to find the 75th piece of paper, and tell somebody that it is page number 999. Given that page number, they will have a hard time telling you that it's the 75th piece of paper in the stack. This is the EC DLP.

Now take that stack of papers and extend it so that it goes to the Andromeda galaxy that is 2.537 million light years away. That's only about an 85-bit number of pages. Double that distance (5 million light years), and that's an 86-bit number. We use 256 bits for Bitcoin and most other cryptocurrencies.

Where QC shines is for solving the DLP or factoring of RSA because each value is the value (no weird translation to another coordinate space, like EC requires). This is what the famous Shor algorithm helps to solve.

(Writing this comment inspired me to also create a blog post using the stack of papers metaphor: Introducing the Elliptic Curve Discrete Log Problem)