Large quantum dot energy level shifts in anomalous photon-assisted tunneling
Jared Benson, C. E. Sturner, A. R. Huffman, Sanghyeok Park, Valentin John + 10 more
TLDR
Ge/SiGe double quantum dots show surprising singlet-triplet splitting dependence on top gate voltages, leading to anomalous photon-assisted tunneling.
Key contributions
- Discovered strong, unexpected dependence of singlet-triplet splittings on top gate voltages in Ge/SiGe DQDs.
- Observed anomalous photon-assisted tunneling measurements due to these gate-voltage dependent splittings.
- Developed a model combining PAT and pulsed-gate data to describe the linear gate-voltage dependence.
- Showed similar linear gate-voltage dependence for ST splittings in two dots, even with varied ratios.
Why it matters
This paper challenges the assumption that quantum dot energy splittings are negligible with gate voltage changes, which is critical for hole spin qubit operation. The strong dependence found impacts qubit control and design, necessitating a re-evaluation of current effective theories.
Original Abstract
Orbital energy splittings are important quantum dot parameters for the operation of hole spin qubits. They are known to depend on the lateral confinement of the quantum dots. However, when changing top, plunger gate voltages, which are the typical control parameter for qubit applications, such energy splitting changes are typically negligible, both as measured in experiment and as assumed in effective theories. Here, we study the singlet-triplet (ST) splittings, which depend on the orbital splittings, of a double quantum dot (DQD) in a Ge/SiGe heterostructure using photon-assisted tunneling (PAT) and pulsed-gate spectroscopy. We find that the ST splittings have a surprising, strong dependence on the top gate voltages, leading to anomalous PAT measurements. We combine data from both measurements in a model that well describes the linear gate-voltage dependence of the ST splittings. Finally, we show that the ST splittings of the two dots exhibit similar linear gate-voltage dependences when the device is retuned such that their ratio is significantly different.
📬 Weekly AI Paper Digest
Get the top 10 AI/ML arXiv papers from the week — summarized, scored, and delivered to your inbox every Monday.