A quantum money scheme is a quantum cryptographic protocol that creates and verifies banknotes that are resistant to

forge A forge is a type of hearth used for heating metals, or the workplace (smithy) where such a hearth is located. The forge is used by the smith to heat a piece of metal to a temperature at which it becomes easier to shape by forging, or to th ...

ry. It is based on the principle that

quantum states In quantum physics, a quantum state is a mathematical entity that provides a probability distribution for the outcomes of each possible measurement in quantum mechanics, measurement on a system. Knowledge of the quantum state together with the rul ...

cannot be perfectly duplicated (the

no-cloning theorem In physics, the no-cloning theorem states that it is impossible to create an independent and identical copy of an arbitrary unknown quantum state, a statement which has profound implications in the field of quantum computing among others. The theore ...

), making it impossible to forge quantum money by including quantum systems in its design. The concept was first proposed by Stephen Wiesner circa 1970 (though it remained unpublished until 1983), and later influenced the development of

quantum key distribution Quantum key distribution (QKD) is a secure communication method which implements a cryptographic protocol involving components of quantum mechanics. It enables two parties to produce a shared random secret key known only to them, which can then be ...

protocols used in

quantum cryptography Quantum cryptography is the science of exploiting quantum mechanical properties to perform cryptographic tasks. The best known example of quantum cryptography is quantum key distribution which offers an information-theoretically secure solution ...

Wiesner's quantum money scheme

Wiesner's quantum money scheme was first published in 1983. A formal proof of security, using techniques from

semidefinite programming Semidefinite programming (SDP) is a subfield of convex optimization concerned with the optimization of a linear objective function (a user-specified function that the user wants to minimize or maximize) over the intersection of the cone of positive ...

, was given in 2013. In addition to a unique serial number on each bank note (these notes are actually more like cheques, since a verification step with the bank is required for each transaction), there is a series of isolated two-state quantum systems.Lo, Spiller & Popescu, ''Introduction to Quantum computation and information'' (1998) pp. 81–83 For example, photons in one of four polarizations could be used: at 0°, 45°, 90° and 135° to some axis, which is referred to as the vertical. Each of these is a two-state system in one of two bases: the horizontal basis has states with polarizations at 0° and 90° to the vertical, and the diagonal basis has states at 45° and 135° to the vertical. At the bank, there is a record of all the polarizations and the corresponding serial numbers. On the bank note, the serial number is printed, but the polarizations are kept secret. Thus, whilst the bank can always verify the polarizations by measuring the polarization of each photon in the correct basis without introducing any disturbance, a would-be counterfeiter ignorant of the bases cannot create a copy of the photon polarization states, since even if he knows the two bases, if he chooses the wrong one to measure a photon, it will change the polarization of the photon in the trap, and the forged banknote created will be with this wrong polarization. For each photon, the would-be counterfeiter has a probability

3/4

of success in duplicating it correctly. If the total number of photons on the bank note is

N

, a duplicate will have probability

(3/4)^N

of passing the bank's verification test. If

N

is large, this probability becomes exponentially small. The fact that a quantum state cannot be copied is ultimately guaranteed by its proof by the

, which underlies the security of this system.

Practical implementations

At this time, quantum money is not practical to implement with current technology because the quantum bank notes require to store the quantum states in a

quantum memory In quantum computing, quantum memory is the quantum-mechanical version of ordinary computer memory. Whereas ordinary memory stores information as binary states (represented by "1"s and "0"s), quantum memory stores a quantum state for later ...

. Quantum memories can currently store quantum states only for a very short time.

References

{{DEFAULTSORT:Quantum Money Quantum mechanics Banknotes