SHA-3, also known as Keccak (its original name before it was chosen as the winner of the NIST SHA-3 competition), is a completely new hash algorithm that has nothing to do with SHA-1 and SHA-2.
Indeed, one of the stated reasons why NIST chose Keccak over the other SHA-3 competition finalists was its dissimilarity to the existing SHA-1/2 algorithms; it was argued that this dissimilarity makes it a better complement to the existing SHA-2 algorithms (which are still considered secure and recommended by NIST), as well as making it less likely that any future cryptanalytic breakthroughs would compromise the security of both SHA-2 and SHA-3.
For some background, the SHA-3 hash function competition was originally announced by NIST in 2007, after some new cryptanalytic attacks had called the security of SHA-1 into question. While the attacks on SHA-1 were mainly of theoretical interest back then, it was feared that further improvements on these techniques might allow practical collision-finding attacks on SHA-1, and that the same techniques might also be applied against SHA-2, which shares a similar design to SHA-1. Thus, NIST decided to hold a competition to select a successor for SHA-2, which would be named SHA-3.
However, while a real world collision attack on SHA-1 was finally demonstrated in 2017, the feared attacks on SHA-2 have failed to materialize. It's nowadays generally accepted that breaking SHA-2 won't be as easy as it seemed ten years ago, and thus all the variants of SHA-2 are still considered secure for the foreseeable future. However, since NIST had promised that SHA-3 would be chosen in 2012, and since a lot of people had spent quite a bit of time and effort on submitting and evaluating new hash functions for the competition, and since there were some really nice designs among the finalists, it would've seemed a shame not to choose any of them as the winner after all. So NIST decided to select Keccak as SHA-3, and to recommend it as an alternative (not successor) to the SHA-2 hash functions.
What all that means is that, if you want a secure and standardized hash function, you can choose either SHA-2 or SHA-3. If you're feeling really paranoid, you may even want to use both, and to design your cryptosystem so that it remains secure even if either one of the hash functions is broken.