Crypto has spent years dealing with speed, fees and scalability. Now it may have to confront a more existential question: what happens when its core security breaks?
That question moves from theory to urgency. Quantum computers, machines that use the principles of quantum physics to process information in fundamentally different ways than today’s computers, could eventually solve the kinds of mathematical problems that underpin modern encryption.
Discussions surrounding post-quantum cryptography have intensified across the industry in recent weeks, particularly after new research from Google and academic collaborators suggested that such systems could one day break widespread encryption and potentially crack systems like Bitcoins in minutes instead of years.
As Bitcoin developers struggle to find a solution and Ethereum prepares for the event, Solana is trying to get ahead of that scenario.
Cryptography firm Project Eleven has teamed up with the Solana Foundation to experiment with post-quantum security, technology designed to withstand quantum attacks that could render today’s cryptography obsolete. The early work already reveals a difficult reality: Making Solana quantum-proof may come at the expense of its defining performance.
In practice, that effort has meant moving beyond theory and into live testing. Project Eleven has worked with the Solana ecosystem to model how the network would behave if its current cryptography were replaced, including implementing a test environment using quantum-resistant signatures – the digital keys that authorize transactions. The goal is not only to prove that the technology works, but to understand what breaks when pushed to scale.
The early results show a clear trade-off.
The new, quantum-secure “signatures” that authorize transactions are much larger and heavier than those used today, about 20 to 40 times larger, Project Eleven CEO Alex Pruden, who founded the project, after years in crypto and venture capital, bringing a mix of military and industry experience to the problem, told CoinDesk. This means that the network can handle far fewer transactions at once. In tests, a version of Solana that used this new cryptography ran about 90% slower than it does today, Pruden said.
This trade-off cuts right to the heart of Solana’s design. Blockchain has built its reputation on high throughput and low latency, positioning itself as one of the fastest networks in crypto. But post-quantum cryptography—while more secure against future threats—comes with heavier data and computational requirements, making it harder to maintain those speeds.
‘Choose any wallet’
Solana may also face a more immediate structural challenge than its peers.
Unlike Bitcoin and Ethereum, where wallet addresses are typically derived from hashed public keys, Solana exposes public keys directly. That difference matters in a quantum scenario. “In Solana, 100% of the network is vulnerable,” Pruden said.
“A quantum computer could pick any wallet and immediately start trying to recover the private key.”
Pruden, a former Army Green Beret, first became interested in Bitcoin while stationed in the Middle East, later worked at Coinbase and joined Andreessen Horowitz’s venture team on its first fund. He then became an early leader of privacy-focused blockchain Aleo before launching Project Eleven, a company focused on preparing digital assets for what he calls “Q-day,” the moment quantum computers can break today’s cryptography.
Some developers in the Solana ecosystem, meanwhile, are looking at simpler, more immediate fixes. An example is something called ‘Winternitz Vaults’ which uses a different form of cryptography that is believed to be more secure against quantum attacks. Instead of changing the entire network, these tools focus on protecting individual wallets, giving users a way to secure their money now while larger, system-wide upgrades are still being figured out.
Despite these obstacles, Solana has moved faster than much of the industry in at least one respect: experimentation. “There’s something tangible,” Pruden said. “We actually have a testnet with post-quantum signatures.” He added that the Solana Foundation “deserves credit for at least getting involved and wanting to do the work.”
Across crypto, this level of engagement remains rare. While some ecosystems, notably Ethereum, have begun to discuss long-term migration paths, concrete implementation has been limited.
The broader challenge is not just technical, but social: Upgrading cryptography in decentralized systems requires coordination across developers, validators, applications, and users, all of whom must move in sequence.
For Pruden, the risk is that the industry waits too long to begin that process. “This is tomorrow’s problem — until it’s today’s problem,” he said. “And then it takes four years to fix.”
Read more: Here’s how bitcoin, Ethereum and other networks are preparing for the looming quantum threat
