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Quantum Dice Generate Truly Random Numbers

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ERLANGEN, Germany, Sept. 13, 2010 — In classical physics every event can be explained in mathematical terms, but researchers at the Max Planck Institute for the Physics of Light have reportedly constructed a device that works on the principle of true randomness. With the help of quantum physics, their machine generates random numbers that cannot be predicted in advance.

"True random numbers are difficult to generate but they are needed for a lot of applications," said Gerd Leuchs, director of the Max Planck Institute for the Physics of Light.

Security technology, in particular, needs random combinations of numbers to encode bank data for transfer. Random numbers can also be used to simulate complex processes whose outcome depends on probabilities. For example, economists use such Monte Carlo simulations to predict market developments and meteorologists use them to model changes in the weather and climate.

The phenomenon we commonly refer to as chance is merely a question of a lack of knowledge. If we knew the location, speed and other classical characteristics of all of the particles in the universe with absolute certainty, we would be able to predict almost all processes in the world of everyday experience. It would even be possible to predict the outcome of a puzzle or lottery numbers. Even if they are designed for this purpose, the results provided by computer programs are far from random.

"They merely simulate randomness but with the help of suitable tests and a sufficient volume of data, a pattern can usually be identified," said fellow researcher Christoph Marquardt.


A true game of chance: Max Planck researchers produce true random numbers by making the randomly varying intensity of the quantum noise visible. To do this, they use a strong laser (coming from the left), a beamsplitter, two identical detectors and several electronic components. The statistical spread of the measured values follows a Gaussian bell-shaped curve (bottom). Individual values are assigned to sections of the bell-shaped curve that correspond to a number. (Image: Max Planck Institute for the Physics of Light)

In response to this problem, a group of researchers working with Leuchs and Marquardt at the Max Planck Institute for the Physics of Light and the University of Erlangen-Nuremberg, and Ulrik Andersen from the Technical University of Denmark have developed a generator for true random numbers.

True randomness only exists in the world of quantum mechanics. A quantum particle will remain in one place or another and move at one speed or another with a certain degree of probability.

"We exploit this randomness of quantum-mechanical processes to generate random numbers," Marquardt said.

The scientists use vacuum fluctuations as quantum dice. Such fluctuations are another characteristic of the quantum world — there is nothing that does not exist there. Even in absolute darkness, the energy of a half photon is available and, although it remains invisible, it leaves tracks that are detectable in sophisticated measurements. These tracks take the form of quantum noise. This completely random noise only arises when the physicists look for it, that is, when they carry out a measurement.

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To make the quantum noise visible, the scientists resorted once again to the quantum physics box of tricks — they split a strong laser beam into equal parts using a beam splitter. A beam splitter has two input and output ports. The researchers covered the second input port to block light from entering. The vacuum fluctuations were still there, however, and they influenced the two partial output beams. The physicists then send them to the detectors and measure the intensity of the photon stream. Each photon produces an electron and the resulting electrical current is registered by the detector.

When the scientists subtract the measurement curves produced by the two detectors from each other, they are not left with nothing. What remains is the quantum noise.

"During measurement the quantum-mechanical wave function is converted into a measured value," said Christian Gabriel, who carried out the experiment with his Max Planck colleagues. "The statistics are predefined but the intensity measured remains a matter of pure chance."

When plotted in a Gaussian bell-shaped curve, the weakest values arise frequently while the strongest occur rarely. The researchers divided the bell-shaped curve of the intensity spread into sections with areas of equal size and assigned a number to each section.

There is a good reason why the Erlangen-based physicists chose to produce the random numbers using highly complex vacuum fluctuations rather than other random quantum processes. When physicists observe the velocity distribution of electrons or the quantum noise of a laser, for example, the random quantum noise is usually superimposed by classical noise, which is not random.

"When we want to measure the quantum noise of a laser beam, we also observe classical noise that originates, for example, from a shaking mirror," said Christoffer Wittmann who also worked on the experiment. In principle, the vibration of the mirror can be calculated as a classical physical process and therefore destroys the random game of chance.

"Admittedly, we also get a certain amount of classical noise from the measurement electronics," said Wolfgang Mauerer who studied this aspect of the experiment. "But we know our system very well and can calculate this noise very accurately and remove it."

Not only can the quantum fluctuations enable the physicists to eavesdrop on the pure quantum noise, no one else can listen in.

"The vacuum fluctuations provide unique random numbers," said Marquardt. With other quantum processes, this proof is more difficult to provide and the danger arises that a data spy will obtain a copy of the numbers. "This is precisely what we want to avoid in the case of random numbers for data keys."

Although the quantum dice are based on mysterious phenomena from the quantum world that are entirely counterintuitive to everyday experience, the physicists do not require particularly sophisticated equipment to observe them. The technical components of their random generator can be found among the basic equipment used in many laser laboratories.

"We do not need either a particularly good laser or particularly expensive detectors for the set-up," explained Gabriel. This is, no doubt, one of the reasons why companies have already expressed interest in acquiring this technology for commercial use.

For more information, visit:  www.mpl.mpg.de 



Published: September 2010
Glossary
quantum mechanics
The science of all complex elements of atomic and molecular spectra, and the interaction of radiation and matter.
quantum noise
Noise generated within an optical communications system link that has both internal (dark current) and external (background noise, or noise in signal) components.
beam splitterChristian GabrielChristoffer WittmannChristoph Marquardtclassical physicsdefenseencoding bank dataEuropeGerd LeuchsGermanyMax Planck Institute for the Physics of LightMont Carlo simulationsprobabilitiesquantum dicequantum mechanicsquantum noisequantum physics box of tricksquatum physicsquntum mechanicsrandom numbersResearch & Technologysecurity technologySensors & Detectorssimulating randomnessstrong laser beamTechnical University of Denmarktrue randomnessUlrik AndersenUniversity of Erlangen-Nurembergvacuum fluctuationsWolfgang MauererLasers

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