2.1

Context

The £270 million (GBP) UK national quantum technologies programme¹ (UKNQTP) is designed to bring together academia, industry and government as part of a strategy to develop the UK as a future leader in quantum technology.² Part of this is an Engineering and Physical Sciences Research Council (EPSRC) funded national network of 4 different Quantum Technology Hubs, with each focusing on a different aspect of quantum science and technology. These include the Sensors and Metrology hub led by Birmingham University,³ the Communications Technologies hub led by the University of York,⁴ and the Quantum Enhanced Imaging hub (QuantIC) led by the University of Glasgow.⁵ The fourth hub, and the focus of the work presented here, is the Networked Quantum Information Technologies (NQIT) hub led by the University of Oxford.⁶ This is the largest of the four hubs and is working towards building a hybrid quantum computer linking light and matter technologies for quantum information processing.

Photonics is a major part of modern quantum science, with photons being the main route for mediating quantum interactions, entanglement and measurement.⁷ A recent report by the Photonics Leadership Group revealed that the UK photonics industry is worth around £12.9 billion (GBP) and employs more than 65,000 people.⁸ A report released by the Institute of Physics in May 2018 described the ‘health of photonics’ and highlighted many of the areas that this technology feeds in to.⁹ Some of these areas include aerospace, communications, health care, food, and energy, with many set to benefit from quantum photonics technologies. Quantum entanglement is frequently mediated through the use of single photons, which immediately means that any loss in components can be catastrophic to quantum systems. Quantum entanglement is also incredibly sensitive, and any external effects can easily destroy these fragile states. Therefore optical engineering is an important aspect for developing the low loss, quantum compatible components and systems that are required for these advanced circuits and communication technologies.

The University of Southampton has played a leading role in photonics and optical technologies research since the 1960’s. The Optical Engineering and Quantum Photonics group (OEQP) based within the Optoelectronics Research Centre (ORC) at Southampton have expertise in the design and fabrication of photonic components and devices and collaborate with many of the quantum hubs. The group also has a passion for outreach and public engagement, with its members having published several papers on engagement activities over the past few years.^10–12 The OEQP group were recognised in 2017 with a ‘Highly Commended’ awarded for group public engagement by the South East Physics Network (SEPNET). The group are using their expertise in these areas to develop a fiber-optic photonic Entangler system for the NQIT project and engage a wide audience with the science behind quantum technologies and how photonics plays an important role.

2.2

NQIT Entangler concept and fabrication

The OEQP group are collaborators within the NQIT hub, developing optical components for quantum applications. One key part of this collaboration is the development and testing of the optical network required for the NQIT hybrid quantum computer. This will consist of solid-state ion traps, based at Oxford, which will be used as computational nodes. Each node needs to be linked with its neighbors via a fiber-optical ‘Entangler’ capable of causing photons emitted by the trapped ions to undergo quantum entanglement.¹³ This will then allow the ions themselves to become entangled. The system is designed so that it is possible to ‘scale-up’ by adding further ion traps and optical entangler systems.

The Entangler itself is designed to be constructed with off-the-shelf optical fiber components currently available. This poses a technological challenge in that the majority of components are developed for the current telecommunications market which works with infrared wavelengths of light. The ions used in the NQIT project emit light in the visible blue region, at 422 nm wavelength, for which many off-the-shelf components show a great deal of loss. With a long history of optical engineering the OEQP groups role is to source and test components for operation at blue wavelengths before assembling these into an optical Entangler system for use with the ion traps. These components are individually tested and assembled inside a 19” rack mount for stability, ease of use and for system expansion through adding further units. The input fibers are attached to the ion traps and guide the photons emitted from the traps to the Entangler unit. Inside, the photons are introduced to each other at a fiber beam splitter. It is here that the photons experience quantum entanglement. If the photons emitted from the ion traps become entangled this filters back to the traps, meaning that the trapped ions become entangled with each other too. The entangled photons then propagate to a secondary component which splits the photons depending on their polarisation. This stage is used for tuning the ion trap/Entangler system, and for measurement purposes. After the measurement it is possible to tell if entanglement between the ions was successful.

It is clear that the function of this device, and the science behind it, can be quite challenging to explain. It was decided to produce an interactive replica of the real device for engagement purposes. The following sections describe the design and construction of the interactive Demonstrator, as well as accompanying software and a handout designed to highlight the importance of photonics to quantum technology.

3.1

Hardware

The hardware was designed to replicate the real-world Entangler unit that would be used in the fundamental physical experiments of the NQIT project. Blue laser diode illuminated optical fibers were used, along with an electronic circuit to drive them and Arduino for control. The electronics were housed within a 19” rack mountable unit with the illuminated fibers feeding through to an additional unit above. The construction of the unit, and its operation, are discussed in the following sections.

3.1.1

Construction

The equipment required for constructing the unit is listed as follows, with total costs displayed in GB Pounds. The total equipment cost was approximately £685.43. The cost of staff time taken to assemble the device is not taken into account here.

• • 2 x 1U 19” rack mountable units (RS components PF-19), used for housing the optics and electronics and for operation of the demonstrations. (£95.74)

• • 5 x Toggle switches for activating the device and controlling circuit. (£5.28)

• • 5 x Blue laser diode illuminated fibers (World Star Tech ML5-20G-450-2M), which relate directly to the optical fiber component of the real Entangler. These illuminate to show the paths that photons would take in the device. (£450)

• • 1 x Arduino Uno, microcontroller for control of the electronics to allow the fibers to light up under certain combinations of switches. (£20.70)

• • 1 x Buck Voltage/Current converter, for electronically driving the illuminated fibers and LED’s on the unit. (£1.20)

• • 5 x Transistors (FET’s), used for gating the illuminated fibers with the Arduino. (£4.50)

• • 1 x Piece of clear Polycarbonate, for the lid of the unit so that the fibers can be viewed, but are also protected. (£38.16)

• • 1 x USB port and cable, for reprogramming Arduino without having to dismantle the box. (£8.11)

• • 2x Die cast boxes to represent the beamsplitter components. (£11.74)

• • Other components such as; resistors, cables, electronic connectors, cable glands, electronic prototype board, LED’s, foam etc. (approx. £50)

The electronic components were assembled as shown by the circuit diagram in figure (1). The entire circuit was driven through a DC adapter which converted the 240 V AC mains supply to a 9 V DC supply of less than 1.2 A, through a switch to control power to the entire device. The five illuminated fibers are driven by blue laser diodes which are directly coupled and provided as a complete unit from World Star Tech. These were connected electrically in parallel through separate FETs to a buck voltage/current converter, which scaled the input current to that accepted by the fibers. The Arduino was powered directly from the input 9 V supply and was programmed to accept four input signals (four switches) and respond accordingly. Five outputs from the Arduino were used to gate the FETs allowing the fibers to illuminate with respect to the input signals. The Arduino outputs were also programmed to give the fibers a pulsing effect when illuminated.

Figure 1.

A simplified diagram showing the layout of the circuit for operating the Demonstrator. The system is driven by a 9 V DC, 1 A power supply which powers the Arduino Uno microcontroller and Buck voltage/current converter. The Arduino is controlled by switches connected to its digital input ports, which are fed from a 5V output on the Arduino board itself. The switches turn each channel on and off, and also simulate H or V polarisation of light. This also powers the fan used to cool the laser diodes. The Buck converter converts the input supply to provide up to 2.5A of current to drive the laser diodes. The output from this is connected in parallel with the five laser diodes through five transistors (FETs). The FETs are gated by the digital outputs from the Arduino.

The two rack mount units were assembled and attached together. The electrical components were installed in the lower of the two units, shown in figure (2c). An electrical port and a switch was installed on the rear of the unit for connection to the 9 V DC power supply. A USB port was also installed and connected internally to the Arduino to allow reprogramming without requiring disassembly of the unit. The four switches for control of the device were installed on the front panel of the lower unit. LEDs were also installed on this front panel to indicate when the circuit was activated, and were wired into the switches. The front and back panels are shown in figure (2b).

Figure 2.

Collection of images showing the construction of the Demonstrator. Fig (a) shows the parts layed out prior to assembly. Fig (b) show the front (top) and back (bottom) of the assembled unit prior to electronics installation. Fig (c) shows the installation of the electronics in the lower rack unit, with diode coupled illuminated fibers on the left, Arduino at the centre bottom, and the FETs and Buck converter centre top. Video (d) shows the completed Demonstrator unit in operation. https://doi.org/10.1117/12.2321079.1

The parts of the illuminated fibers which housed the laser diodes were also installed in the lower unit. A block of aluminium was machined to hold these five components and to act as a heat sink. A small fan was fixed inside the casing next to this block to ensure constant airflow and cooling of the diodes when under operation. The illuminated fibers were then fed through holes into the unit above.

The front panel of the top unit was machined to hold four cable glands, which the illuminated fibers can pass out of for demonstrations. The top unit was also filled with a soft black foam to protect the fibers which lay on top of it. The holes which the fibers pass through from the lower unit were covered with small die-cast boxes which were patterned and labelled as ‘beamsplitter’ and ‘polarising beamsplitter’ to indicate the two fiber components used in the real Entangler device. The fibers then fed out of small holes drilled in the sides of these boxes. The top unit was capped with a piece of Perspex cut to size, to protect the fibers within and allow viewing. Both front panels of the top and bottom unit were engraved with a CO₂ laser, labeling the function of the switches, inputs and outputs, and including the NQIT logo. Figures (2a to c) show the assembly of the unit and figure (2d) shows the completed device in operation.

3.1.2

Operation

The Demonstrator was designed to mimic the real-world Entangler unit that accepts photons from two separate ion traps. Figure (3) shows a schematic of the device operation. The switches to control the channels ‘Ion 1’ and ‘Ion 2’ are designed to mimic inputs from two Ion traps which are individually controlled. These switches primarily control the illumination of fibers 1, 2 and 3. They also control the illumination of fibers 4 and 5, however which of these fibers illuminates is controlled by the other switches with positions labeled ‘H’ and ‘V’ to denote the polarisation of the photons as either horizontal or vertical.

Figure 3.

Schematic of the Demonstrator operation. This shows how the illuminated fibers are routed out of the beamsplitter (BS) and polarising beamsplitter (PBS), and the way in which they will light up depending on the switches. The lower image is of the switches on the front panel.

The best way of understanding how the Demonstrator works is by considering one channel at a time. For instance with the ‘Ion 1’ switch activated fiber 1 will be illuminated. This passes into the first black box which is presented as a beamsplitter. A beamsplitter would take the light from an input and split the light 50/50 into two outputs. As both outputs of the beamsplitter would be illuminated whether ‘Ion 1’ or ‘Ion 2’ is activated, we use only fiber 3 in a loop between the two black boxes to give the impression of two output fibers. The second black box is presented as a polarising beamsplitter. This directs the light into an output depending on what polarisation it is, horizontal or vertical. The polarisation of the light is controlled by the ‘H’ and ‘V’ switch. For instance, if the switch is set to ‘H’ then fiber 4 will illuminate. If the switch is set to ‘V’ then fiber 5 illuminates.

This is similar to the outcome when the ‘Ion 2’ switch is activated, with fiber 2 instead of fiber 1 illuminated. With both ‘Ions’ activated fibers 1, 2 & 3 will illuminate and fibers 4 & 5 are controlled by the two ‘H’ and ‘V’ switches. The Arduino handles all of these switch inputs and activates the fibers accordingly.

3.2

Supporting software

The Demonstrator works well to show the function of the device in terms of how different inputs affect the outputs, however the real Entangler operates at the single photon level. To describe the function of the Demonstrator in terms of single photons some supporting software was developed using National Instruments LabVIEW. The resulting GUI is shown in figure (4).

Figure 4.

Video of the LabVIEW developed software to support the Demonstrator. The design mimics the experimental setup, with two ion traps emitting photons which enter the fiber optic circuit. The buttons at the bottom of the image select different entanglement scenarios which are then played out by the blue circular ‘photons’ over the diagram. https://doi.org/10.1117/12.2321079.2

The software was designed to mirror the Demonstrator design, with different cases for H and V entanglement for the different Ions, and a graphic representation of the fibers and beamsplitters. When one of the buttons at the bottom is pressed, two ‘photons’ labelled ‘H’ or ‘V’ travel from the ‘ion traps’ at the far left of the image towards the first ‘beamsplitter’. Here they interact depending on the button selected before propagating to the ‘polarising beamsplitter’ to interact again. They then move onwards to the ‘detectors’ which flash depending on how many ‘photons’ are detected. Whilst supporting the Demonstrator, the software is targeted at explaining the function of the Entangler to a technical audience. The means that it may not be suitable for all engagement audiences and there are some scenarios when the Demonstrator alone would be most suitable.

5.1

Lessons learned

The initial concept of the Demonstrator was to construct a replica of the Entangler that would be used in experiments in the NQIT hub. This replica was to be used to explain the function of the real world device and help to explain the importance of photonics to quantum research and the NQIT hub. Upon construction it was realised that, while the Demonstrator showed the general concept of the device, it did not do well explaining the science on a single photon level in which the real world Entangler would be operating. For this reason some software was developed to be exhibited alongside the Demonstrator which would show the different means of operation for single photons. However, the combination of the Demonstrator and software make this quite a ‘high level’ engagement tool. This worked well for the UK Quantum Technologies Showcase and the Innovation South Showcase, which were targeted at company representatives, academics and government officials, however this did not work well as an engagement tool for the general public. Therefore a handout was developed for the Quantum City stand to inform about the use of the entangler and the importance of photonics for quantum technology. The Demonstrator was also intended to be interactive, with people encouraged to try out the switches and use the software to explore the device operation. However, it often resulted in the person exhibiting the device operating both switches and software whilst explaining the function. Due to the delicate nature of the illuminated fibers this was also exhibited as a ‘hands-off’ device to the public, which was not the original intention. The construction of the device, whilst not costing a large amount, could prove costly to replicate on a minimal budget. The Demonstrator was also time consuming to construct and therefore could be inaccessible for many people to replicate. The following section discusses an alternative option for demonstrating quantum entanglement in a ‘hands-on’ way that would prove cheap and quick to implement.

5.2

Hands-on entanglement

A concept for an interactive, hands-on method for describing photon entanglement which could be exhibited on its own or alongside the Demonstrator is introduced here and shown in figure (7). The general principle behind the real world Entangler is that photons emitted by two different ions are brought together at a beamsplitter to achieve entanglement. An important aspect of entanglement is that you must not know which photon came from which ion, otherwise you will know which state each ion is in thus breaking the quantum entanglement. The simplest way to demonstrate this concept would be through the use of coloured or numbered tokens being selected from two separate containers, or even dispensed by two ‘bingo ball’ machines. For instance, assuming the use of red and blue balls to signify the different photon states, two buckets to hold a mixture of the balls representing the ions, and an opaque bag to represent the beamsplitter, the following could be a demonstration of entanglement:

Figure 7.

Example of a simple scheme for demonstrating entanglement. In step one a ‘photon’ from each ‘Ion’ is selected blindly and at random, and placed into the ‘beamsplitter’. In step 2 the ‘photons’ are measured. If the ‘photons’ match we know the state of the ‘Ions’ and do not achieve entanglement. If they do not match we can’t tell from which ‘Ion’ each ‘photon’ came and entanglement is achieved.

If the balls are both red (blue) we know that both buckets produced a red (blue) ball, therefore we know which state each ion is in and so they are not entangled. If one ball is red and the other is blue then we know that each bucket must have produced a red or blue ball, but we don’t know which. In this case we can say that the buckets are in a state of entanglement. This method is hands-on, simple to explain, and is easy to implement for a low cost.

The Demonstrator and software will feature again at the UK Quantum Technologies Showcase 2018, and will play a part in any engagement the Optical Engineering & Quantum Photonics group undertakes. The Quantum City stand will appear at several more events over the next year, with the intention that the Demonstrator will be featured at some of the events. A simple hands-on demonstration like that discussed above will accompany the Demonstrator at these events.