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AWG for atomic experiments | Spectrum

Removing single atoms

The University of Stuttgart’s Physics Department is researching in the field of single, solid-state defects with a particular focus on Nitrogen-Vacancy (NV) centres in diamond, which are formed by removing a carbon atom and replacing it with a nitrogen atom to form an NV pair.

Experiment Setup at UniversityThe NV defect centres can be used as an atom-sized magnetic field sensor – effectively a nano-scale Nuclear Magnetic Resonance (NMR) device as it can detect the interaction of the NV’s spin with tiny local magnetic fields detecting both strength and frequency. For example, measuring the magnetic field strength of the tiny read/write heads on hard disk drives so that they can be characterised. The nano-scale NMR function could also be used for structural analysis of a single protein or thin films as only a few spins are needed to measure these small samples unlike a normal size NMR.

NVs can also be used as a qubit for processing functions in quantum computing by using two spin states and superpositions between them. This is of particular interest because they have stable spin states at room temperature unlike similar options that require ultra low temperatures and pressures.

Several NVs are created typically 5nm within the diamond at a depth that depends on the energy used to implant the nitrogen atom into the diamond lattice. The aim is to be able to implant them one at a time so that arrays can be created for quantum computing.

An Arbitrary Waveform Generator is needed

The NV centre is manipulated with sequences of optical excitation pulses as well as microwave and radiofrequency pulses. This requires extremely precise sequences of very short pulses to be created. One of Spectrum’s latest generation Arbitrary Waveform Generators (AWG) was selected to provide the input for this as Spectrum was able to modify it to provide the required ten output channels (four analog and 6 digital channels). Spectrum’s modular design philosophy enabled the company to add six more additional digital marker channels to the standard four by the addition of a daughterboard on the motherboard to provide the extra connections. The AWG model used is a DN2.663-04 netboxgeneratorNETBOX, which is a standalone unit that connects through Ethernet to a controlling PC.

The AWG with cabelingThe AWG controls the LASER, the microwave signal using IQ modulation, generation of radiofrequency pulses and triggering data acquisition devices to determine the spin state. “Effectively it runs the whole experiment thanks to its large number of output channels,” explained Thomas Oeckinghaus, the experimental physicist who is doing his PhD on this research. “The key factor in selecting the Spectrum AWG was its speed as our experiments require very short pulses down to between 10 to 20 nanoseconds. At 1.25GHz, it can control these with a very high temporal resolution.”

The new piece of equipment

Using a new piece of equipment, especially one that provides a high level of flexibility, can always be challenging but he found that the documentation was very good which made setup straightforward. Only one problem was encountered and Spectrum provided a new driver with a fix the next day. “Post sales support can often be ignored in the checklist when selecting a new piece of equipment,” he concluded. “I was really impressed to have a fix the next day. That gives me confidence that if I ever have a problem, Spectrum will quickly sort it.”
Each channel of Spectrum’s AWG has a 16-bit digital-to-analog converter (DAC) that can generate precise and flexible wave shapes with frequency content from DC to 400 MHz to emulate real world signals. To allow the generation of long and complex waveforms, the AWG has a number of operating modes such as Single-Shot, Loop, FIFO, Gating and Sequence Replay. In FIFO mode, the instruments can stream data continuously from PC memory to the AWG’s 4GB of memory over the PXIe interface. The AWG can even output signals while new waveform data is being sent to the on-board memory.

Copyright (text & photos): Thomas Oeckinghaus & Universität Stuttgart & Spectrum Instrumentation