Eavesdropping-proof Messaging

Security in data transfer is an important issue, and not only since the NSA scandal. Sometimes, however, the need for speed conflicts to a certain degree with the need for high security. Yet there is no doubt that when transferring sensitive data especially, for example from banks or in a political context, security must come first. This high level of security is one of the scientific tasks of the Collaborative Research Center 787 “Semiconductor Nanophotonics”, whose head institution is TU Berlin. Also involved are the mathematicians and MATHEON members Frank Schmidt, Sven Burger and Benjamin Wohlfeil of the Zuse Institute Berlin.

Data are generally transferred as light pulses through optical fibers. Normal transfer takes place as ones and zeroes. Transfer in this fashion runs the risk of having, say, 10.000 photons siphoned off from the many billions in order to listen in on the information. The normal recipient would never even notice. “As the recipient, you cannot distinguish whether all the information has arrived or if a part of it has been tapped,” explains Stephan Reitzenstein, member of the special research area and professor at the Institute of Physics at TU Berlin.

The aim in quantum communication is therefore to work with single photons. Put simply, this means that anyone trying to listen in has to pull that one single photon out of the transmission, which in turn means the message no longer arrives at the receiver, and the attempt to eavesdrop is clearly noticed. On top of this, the eavesdropping attempt irreversibly changes the state of the photon so that it cannot be simply reinserted into the data transmission. “Thus they will have disturbed the system in such a way that even copying would be noticed,” Reitzenstein says. Using quantum communication, one could – in theory – make eavesdropping completely impossible, or at least reduce it to a minimum.

Schematic depiction of the single photon source based on a quantum dot microlens. (Source: TUB)

Schematic depiction of the single photon source based on a quantum dot microlens. (Source: TUB)

There are in fact systems that already work on this basis. This research project, however, focuses on light sources that are not yet commercially available. Available systems employ normal lasers with an output power of about 1mW. Attenuators then minimize this power so far that, on average, one photon comes out of the system. The problem, however, is that for many pulses, this all-important strong attenuation causes either no photon to be emitted or more than one photon to be emitted per pulse. The possibility of failure of the current systems is thus relatively high, and so these systems are still very slow and relatively unreliable. In the real world, this means there is still no way commercially to incite individual light sources to reliably emit exactly one single photon at each push of a button.

According to the physicist’s knowledge, while these processes are being studied worldwide, the great progress made by the Berlin researchers is unique. Also unique is the special lithography method employed in the Berlin approach. They are working with quantum dots on a tiny semiconducting object spanning 10–20 nanometers. If this quantum dot is excited “at the push of a button”, then an electron is stored, with a so-called hole as a counterpart. After a certain time, these two oppositely charged particles recombine and emit a photon. During production, however, such quantum dots form randomly on the surface of the semiconductor material. So, one never knows with certainty where exactly the quantum dot is located in the active layer of the sample. This leads to an arbitrarily poor yield in general. In the special research area, they are therefore developing a model that helps locate the quantum dots, so they can then embed them targeted into a microlens as a single photon source.

This is where Frank Schmidt, Sven Burger and Benjamin Wohlfeil come in. The mathematicians are calculating the optical part of the quantum physics. “We were given a light source and a configuration as a starting point. We then had to clarify what the optimum shape, size and depth of the lens, that is the final optical component, should be. Ultimately, it’s all about optimizing the lens, so it’s a classical problem of optimization,” says Frank Schmidt. Another problem for the mathematicians was to guarantee the current flow through the appropriate substrate and then to calculate how much light will ultimately come out of the lens. This is no trivial task, since metals also absorb light. “These are all prerequisites to solve if we are to make a manufacturable and marketable design out of the physical effect,” Benjamin Wohlfeil adds. They accordingly experimented with many different lens shapes. In the end, the mathematicians were greatly successful, having managed to increase the emitted light in their models from about one percent to more than 60 percent.

The microlens thus developed hardly differs from a normal lens, except that the lens is now used in the reverse sense. The “focal spot” is the single photon source so that the lens efficiently emits this photon into the environment – in this case the communication channel. Without such a lens, only about one in every hundred photons would make it out. Meanwhile, during the lens production process, all other disturbing quantum dots are removed to ensure only the one, effective quantum dot resides in the lens. This requires an elaborate in-situ lithography method developed over the past three years in Reitzenstein’s group. The Berlin method thereby offers full control to produce the optimum lens with integrated quantum dot. The quantum dot and lens are made of the identical material. So far, this is unique in the world. The yield from this method is namely about 90 percent, unlike usual methods described worldwide, which achieve typically a yield of only around one percent.

The process is, of course, not yet mature enough to be incorporated into finished devices. The main hindrance is that it takes extremely low temperatures of less than −240 °C for it to work. Solving the cooling problem is one important goal. Another task will be to modify the emission wavelength of 900 nanometers to the 1300 nanometers typically used in telecommunications, and then couple the source directly to a glass fiber.

Finally, there is still the problem of the too short range of this quantum data transfer, since this type of communication in principle does not allow signal amplification. In all conventional fiber optic cables, the data are repeatedly amplified every few tens of kilometers in order to achieve the greatest possible range. In quantum communication, however, they will have to rely on teleportation, which still has its place more in science fiction films than anywhere else. Again, the MATHEON mathematicians are needed here just as much as for speeding up the transfer.

Reitzenstein does not expect this task will be fulfilled within the next four years and thus by the end of the special research area’s term, which is limited to a maximum of twelve years. “This last mentioned problem could be the task of a new Collaboratice Research Center. Yet we are facing major competition in this, above all from China, where sums in the two- to three-digit millions are currently being invested in this research,” the physicist admits. (Source: TU Berlin)

 

Reference: M. Gschrey et al.: Highly indistinguishable photons from deterministic quantum-dot microlenses utilizing three-dimensional in situ electron-beam lithography, Nature Communications 6, 7662 (2015); DOI: 10.1038/ncomms8662

Links: Zuse Institute Berlin • Forschungszentrum Matheon, Berlin • TU Berlin

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