One possibility to consider decouples the key used to encrypt the data from the key used to gain access to the data. Done carefully, this allows the user to change their password as often as they desire, while you only change one record in the database. Separately, you can schedule changes to the key(s) encrypting their data when it is convenient for you.
How does it work?
- You encrypt the data D for user U with a randomly generated key, KU,D.
- You encrypt the key KU,D with a separate key K1U,K generated from a random salt, S1U (which you keep a record of) and the user's password P1U (which you may or may not keep track of). The encrypted key is E1U.
- You store S1U and K1U,K ready for when the user wants to access their data.
- When user U wants to access their data, they provide you with their password, P1U, and you look up S1U and regenerate K1U,K from that data, and use that to decrypt E1U, giving you KU,D once more, with which you decrypt their actual data.
- You ensure you can detect when the password given is correct so you don't spew forth binary gibberish if the users types the wrong password.
The advantage of this level of indirection comes when the user wants to change their password. If you don't use some technique analogous to this, you will have to get and validate the old password and the new password, decrypt all the data with the old password, and re-encrypt it all with the new password.
With the level of indirection, you still prompt the user for their old password (P1U) and their new password (P2U) and validate them, but you only have to decrypt E1U and then re-encrypt it with a new key K2U,K generated from a new salt S2U and the new password P2U. You do not have to touch the encrypted data at all.
With the level of indirection, the system S can also keep a second encrypted copy of the data key KU,D, encrypted with the system's password. If it becomes necessary or desirable to change the key used for encrypting the data, the system can use its encrypted copy of the key to do so. It can keep a record of which key was last recorded by the user in their key, so when the user returns to look at the data, it can arrange to to change the stored key K2U,D because at that time, it has their password (the rest of the time, it does not).
This is a mild variation on some of the ideas in "Cryptography in the Database: The Last Line of Defense" by Kevin Kenan. The KnU,K keys are examples of a KEK, a Key-Encrypting Key. You could also read about key families in the book, which would help with the management of encrypted data.