SSL (today TLS) is designed to protect data sent via wire and authenticate the server to which you are sending data (it can authenticate the client too, but it's out of the scope today). So if plain HTTP can be eavesdropped and modified by an attacker, HTTPS traffic can be happily sent over the channel with the assurance that only the legitimate recipient ("only" and "legitimate" emphasized separately).
Tor adds anonymisation. Plus to the above requirements, basically Tor prevents the client to be located. You know Facebook but Facebook won't know you. The Tor network, with its special sockets to
.onion addresses, enforces encryption and authentication because only a host with a valid private key can register itself to a specific .onion domain.
So if you know
facebookcorewwwi surely belongs to Facebook Inc., you don't need additional cryptography. Or do you?
Using a certificate still helps preventing phishing via domain scam. Onion domains are not regulated by ICANN so anyone can generate their own domain. This article explains that:
- Everybody can easily generate a
.onion address that starts with a given prefix (e.g.
exampl), but it gets incredibly slow to match longer prefixes
- If somebody was capable of generating
facebookcorewwwi, he would be also able to break e-commerce level cryptography
So while nobody can steal Facebook's exclusive
facebookcorewwwi.onion and nobody can eavesdrop traffic to
facebookcorewwwi.onion maybe somebody lucky can still turn a victim into a site resembling Facebook's home page or worse named
Basically the answer is:
- An SSL certificate adds no additional security in Tor Onion domains when dealing with encryption
- An SSL certificate adds no additional authentication to the hostname in the
.onion space, as anybody in the future might be able to obtain any
- An SSL certificate with EV extension can prove the real identity of the owner of the authenticated
Facebook doesn't yet use EV for their Tor website as displayed below, but we know their Tor endpoint is currently experimental.