If I had to re-phrase your question from how I understand it, you are asking the following:

If public key cryptography ensures that a public key *can* be derived from a private key, but a private key *cannot* be derived from a public key, then you might wonder, **how can a public key ***decrypt* a message signed with a private key without the sender exposing the private key within the signed message to the recipient? (re-read that a few times until it makes sense)

Other answers have already explained how **asymmetric** cryptography means that you can *either*:

- Encrypt with public key, decrypt with matching private key (pseudocode below)

```
var msg = 'secret message';
var encryptedMessage = encrypt(pub_key, msg);
var decryptedMessage = decrypt(priv_key, encryptedMessage);
print(msg == decryptedMessage == 'secret message'); // True
```

- Encrypt with private key, decrypt with matching public key (pseudocode below)

```
var msg = 'secret message';
var encryptedMessage = encrypt(priv_key, msg);
var decryptedMessage = decrypt(pub_key, encryptedMessage); // HOW DOES THIS WORK???
print(msg == decryptedMessage == 'secret message'); // True
```

We *know* that both example #1 and #2 work. Example #1 makes intuitive sense, while example #2 begs the **original question**.

Turns out, elliptic curve cryptography (also called "elliptic curve multiplication") is the answer to the original question. Elliptic curve cryptography is the mathematical relationship that makes the following conditions possible:

- A public key
**can** be mathematically generated from a private key
- A private key
**cannot** be mathematically generated from a public key (i.e. "trapdoor function")
- A private key
**can** be *verified* by a public key

To most, conditions #1 and #2 make sense, but what about #3?

**You have two choices here:**

- You can go down a rabbit-hole and spend hours upon hours learning how elliptic curve cryptography works (here is a great starting point)... OR...
- You can accept the properties above--just like you accept Newton's 3 laws of motion without needing to
*derive* them yourself.

In conclusion, a public/private keypair is created using elliptic curve cryptography, which **by nature, creates a public and private key that are mathematically ***linked* in both directions, but not mathematically *derived* in both directions. This is what makes it possible for you to use someone's public key to verify that they signed a specific message, without them exposing their private key to you.