The Paradox of Quantum Computing

To try distract you from these times of war and disease, let me tell you a joke: “Schrodinger takes his cat to the vet, for a check-up. The vet comes back 10 minutes later and says, “Well, I have good news and bad news…..” If you snickered at this, you know a bit about the Schrodinger Cat paradox, and therefore perhaps a little bit about quantum physics. For those who did not, the paradox explains the seeming contradiction between what we see with our naked eye, and what quantum theory tells what actually is in the microscopic state. The ‘Copenhagen Interpretation’ of quantum mechanics. states that ‘a particle exists in all states at once until observed’. Schrodinger’s cat is in a box, and could be alive or dead. However, till the box is opened, you would not be able to know whether its state is. Thus, the vet’s quandary above.

This principle, among others, powers one of the most exciting and bleeding edge advances in technology: Quantum Computing. I have written about it before in this publication, but to summarise: Our current powerful computers follow the principles of the Turing machine, where information is encoded into bits (1 and 0) and a series of operations (AND, OR, NOT, etc.) make these bits compute. A quantum computer uses qubits or the quantum version of bits; a qubit is not permanently a 0 or a 1, but it can be both at the same time! Only at the end of the computation, or when the box is opened, you can know whether it is a 0 or a 1, but during the computation process its exact state is indeterminate and can contain bits of both! If this went whooshing over your head, console yourself with what Bill Gates said in a 2017 WSJ interview: “I know a lot of physics and a lot of math. But the one place where they put up slides and it is hieroglyphics, it’s quantum.”.

A quantum computer can exploit these properties of quantum physics to perform certain calculations far more efficiently and faster than any computer or supercomputer, inspiring the likes of Microsoft, IBM and Google to work feverishly on this new form of computing. This is especially urgent because Moore’s Law is flattening, but the problems that need to be solved are becoming more complex: climate change, artificial general intelligence, drug personalization. While this is super exciting, a recent BBC article (https://bbc.in/3pA7pIY ) about the ‘quantum apocalypse’ made me pause.

A hidden force behind ecommerce, online banking and trading, crypto trading, social networking, messaging, almost everything we do is encryption. Most encryption uses public and private keys, and that in turn uses arcane mathematical calculations using prime numbers. Using a Turing computer to crack this encryption is virtually impossible, it would take thousands of years. However, potentially, a quantum computer would do this in mere seconds. Every minute, huge amounts of encrypted data are harvested without us knowing and stored in vast data banks, waiting for the day that they can be decrypted. Today there is nothing data thieves can do with this treasure trove, “…but once a functioning quantum computer appears that will be able to break that encryption… it can almost instantly create the ability for whoever’s developed it to clear bank accounts, to completely shut down government defence systems – Bitcoin wallets will be drained.” says lyas Khan, CEO of Quantinuum. Not only this, but current encryption methods will be useless, halting online banking transactions, ecommerce, social media interactions, everything. . The security of every public blockchain will be under threat from quantum computing power, since it relies on heavy duty cryptography; it was no coincidence that the price of Bitcoin dropped sharply the day Google made its announcement of achieving Quantum Supremacy a year back. This is the Quantum Apocalypse.


The word is gearing up for this post-quantum world. Google, Microsoft, Intel and IBM are working on solutions, so are specialist startups like Post-Quantum and Quantinuum. The UK government claims that all its top-secret data is already ‘post-quantum’. The BBC talks of a ‘beauty parade’ taking place at the National Institute of Science and Technology (NIST), “to establish a standardised defence strategy that will protect industry, government, academia and critical national infrastructure against the perils of the quantum apocalypse.” Formidable new cryptographic methods like quantum key distribution are being developed, where even if the message gets intercepted no one can read it, much like the aforementioned Cat

All of this will not be cheap, nor will it be easy. But we have no choice in the matter – most of our world runs digitally now, and its wheels need to be kept humming. And, to do that, we will need to think out of the Box.

FAQ

Quantum refers to the quantum mechanics that the system uses to calculate outputs. Quantum is the smallest possible unit of any physical property in physics and usually refers to properties of atomic or subatomic particles, such as electrons, neutrinos, and photons.

Quantum computers uses the power of quantum mechanics and apply it to computing to store data, perform computations and deliver advanced programming methods. These can be extremely advantageous and vastly outperform even our best supercomputers.

Quantum computing can be used for a variety of innovations and estimations across all industries — from healthcare to finance, climate forecasting, travel and transportation and privacy. Quantum computers have potential to benefit society in various ways. However, there is one disadvantage of quantum computing — that it could break current cryptography



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