There are discussions in the digital community about the threat of physical particle computing to blockchain algorithms. What changes can bring new-age hardware to the cryptocurrency economy, whether it is possible to combine quantum computer and mining – about this in a new article. We will also tell you how real are the fears that PoW mining will cease to exist
What is a quantum computer
Habitual machines use a binary system of calculations. Any information to be processed is counted in bits and looks like a combination of the numbers 1 and 0. The difficulty of working with it is the bulkiness of the data. However, the moment you need to model many variations using a large number of variables, a performance crisis comes. There are 4 unique combinations for 2 digits. In the case of searching all possible 10-digit variants for 10 variables – the search can take tens of months.
The hash in SHA-256 encryption is 32 characters long. To decrypt it, each combination of 32 variables must be searched in turn. Even with the combined power of a supercomputer, the process would take a billion years. This is why SHA-256 is considered safe for the time being.
In contrast to the binary system, a quantum method has been developed. Theoretically, a powerful physical particle computer can simulate variants for complex sequences in minutes, which would take hundreds of years for supercomputers.
Working principle
The quantum method does not use overshoot. Instead of bits, the unit of calculation is qubits. These are variables that have a value of 1 or 0 with a probability of 50%.
In other words, for a qubit, all variants are true and exist simultaneously in the same computation reality.
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If the answers are already there, we need to understand what takes time in the calculations. To extract the result, one needs to apply an interpretation algorithm. Translating information from quantum computer (QC) space into an understandable form takes time.
Facilities for such computations are under development. In parallel, researchers in quantum physics are trying to increase the speed of interpretation algorithms. Work in this area is taking place at all major research universities, such as MIT (USA) and leading commercial fintech labs at IBM and Google.
Date of emergence
In 1980, American researcher Paul Benioff and Soviet physicist Yuri Manin published the first papers related to the theory of quantum computing. A year later (in 1981), the first prototype of QC was presented, which contained 2 qubits. Its creator was Nobel laureate in physics Richard Feynman. The sample was based on a Turing computer. Further theoretical developments were carried out for more than 10 years. However, practical shifts began after the creation of the algorithm for factorization of numbers, which was described by Shore in 1994.
From that moment, employees of the Massachusetts Institute of Technology (MIT), and later the IBM research department, joined the race to create a working QC model. Various physical objects were chosen as the basis of computation: photons, electrons, cold atoms and others.
The list of realized installations is presented in the table.
| Year of presentation | Developers | Number of qubits |
|---|---|---|
Power
Active development of such computations is carried out to solve global problems. The main areas of application are:
- Space industry
- Transportation
- Computer technologies
- Health care
- Investment.
Taking into account the trajectory of movement, the load on materials, natural and human factors, quantum algorithms can optimize fuel consumption in aerospace and transportation logistics. The technology can increase the financial efficiency of the system or conduct engineering calculations in the design of interplanetary ships.
For QC, it is possible to create a new generation of encryption and expand the number of results in the work of artificial intelligence.
Trading, investment risk management, and predicting market behavior are also in the spectrum of possibilities for modeling. Chemistry, pharmacology, and genetics are considered the main reason for multi-billion dollar developments.
The capabilities of such a computer are comparable to evolution. Synthesizing new substances, creating stronger compounds, deciphering the genome. Drug development time takes an average of 5 to 10 years. QC can reduce the creation to 2 years, as well as model chemical formulas and synthesize a remedy for incurable diseases.
What is the danger of quantum computers for mining
There is a threat in so much computing power. Many current methods of encryption and cryptography will become defenseless and compromised. Bitcoin hashing using the SHA-256 algorithm could be cracked by a stable QC with 4 thousand qubits. Such computers have not yet been created. The last effective model for such a task is built with 127 qubits.
Despite the high figure, the interconnection of units is easily broken and requires ideal conditions for the calculations. For example, a random photon that enters the system due to a sealing error can introduce irreparable errors into the calculations.
The more qubits are used, the more unstable their communication is. For 4- and 16-qubit units produced by technology startup Rigatti, the recorded error rates are as high as 8.92% and 16.37%.
How to secure blockchain from quantum threats
According to rough estimates, the creation of a large enough QC will happen in the next 10-15 years. However, it is not enough to have a suitable number of qubits. It is important that the result of calculations can be interpreted in less than 10 minutes. This is due to the SHA-256 vulnerability, which occurs only before the block in the chain is closed.
The moment the interpretation time is less than that, Bitcoin mining will become meaningless. So will most of the digital mining on the Proof-of-Work (PoW) algorithm. In this regard, part of scientists are engaged in the development of methods of post-quantum cryptography. Their foundation is based on such mathematical foundations:
- Encryption on linear codes.
- Lattice theory.
- Algorithms using hash function with stable proofs.
Conclusion
The potential of quantum particles could lead to the next technological revolution. We are now encountering its applications at the household level – laser treatment of eye diseases or magnetic resonance imaging (MRI). The threat to compromise existing blockchain technologies is a great reason to create more secure encryption methods.
Frequently Asked Questions
✨ Is it possible to mine on QC?
A computer on quants will get all possible solutions to the hash function at one time. The blockchain will face the paradox of network complexity and will probably stop.
⚡ Is it possible to buy a quantum computer?
Commercial models are produced by the company D-Wave. The cost of installation is from $10 million.
📌 What programming language is used to write algorithms for QC?
Developers use: QPL, QCL, Haskell, Quipper.
🔥 What is superposition?
It is the simultaneous state of a qubit in the value of 1 and 0.
📢 What is Shor’s algorithm?
It is the basic principle of decomposing a number into prime multipliers, which is used in physical particle computing.
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Author: Saifedean Ammous, an expert in cryptocurrency economics.
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