Key instances are represented as a string of bytes resulting from their
getEncoded() method. This is what needs to be stored in order to reconstruct the key later.
However, to store a key safely in electronic form, it should be encrypted. Of course, encrypting the key would require another key (or password)… and so you have an infinite regress. A Java
KeyStore can be used to store
SecretKey objects in this manner, and that is useful when you have many secret keys that are all protected by a single "master" password. But for protecting a single key, it doesn't make a lot of sense.
One alternative is to present the key to the user in a form that can be stored in some safe manner (in many applications, that might be on a slip of paper in their wallet). This could be as simple as displaying the bytes of the key encoded in hexadecimal, Base-64, or other text encoding, and asking the user to write it down.
Another approach is to allow the user to choose a memorable password, and generate a key with that, using an algorithm like PBKDF2. The salt (and maybe the iteration count) used for key derivation would need to be recorded somewhere though. Another drawback is that people tend to choose from a relatively limited number of passwords out of the total available. So keys derived from passwords may be easier guess than than the key size suggests.
Here is an illustration of the basic technique for persisting and reconstituting a secret key.
byte encoded = aesKey.getEncoded();
/* Now store "encoded" somewhere. For example, display the key and
ask the user to write it down. */
String output = Base64.getEncoder().withoutPadding().encodeToString(encoded);
System.out.println("Keep it secret, keep it safe! " + output);
/* At some point, you need to reconstitute the key. Let's say the user
enters it as a base-64 number that you convert to bytes. */
String input = ... ;
byte encoded = Base64.getDecoder().decode(input);
SecretKey aesKey = new SecretKeySpec(encoded, "AES");