High-Field EPR Identification of a Spin "Clock Transition"

Published October 14, 2024

Quantized energy levels associated with the coupled electron and nuclear states of the PrII ion as a function of magnetic field.

Previous work at the MagLab demonstrated that it is possible to design molecules containing a LuII ion such that its lone unpaired electron is shielded against harmful magnetic noise, giving rise to a prototype molecular spin qubit with enhanced coherence. The present investigation extends this strategy to other members of the lanthanide series, such as PrII, which also has a lone unpaired electron in the 5d shell, while its two unpaired f-electrons are non magnetic.

What did scientists discover?

In its 2+ oxidation state, the lutetium ion (LuII) has a filled (non-magnetic) f-shell and a single unpaired (magnetic) electron in the 5d shell. Previous research at the MagLab showed that it's possible to design molecules with a LuII ion where the unpaired electron is protected from harmful magnetic noise, creating a prototype molecular spin qubit with better stability. This new investigation applies the same approach to other lanthanides like PrII, which also has a single unpaired electron in the 5d shell, while its two unpaired f-electrons are non-magnetic.

Why is this important?

This new approach to designing molecular spin qubits with improved stability allows scientists to explore more elements in the periodic table. This opens up possibilities for creating molecular systems with extra features, like optical activity and unique nuclear properties, which differ between elements and isotopes. This will enable the development of future molecular qubits with more advanced quantum capabilities.

Who did the research?

Patrick W. Smith¹, Jakub Hrubý², William J. Evans³, Stephen Hill^2,4, Stefan G. Minasian¹

¹Lawrence Berkeley National Lab; ²National MagLab – Tallahassee; ³University of California – Irvine; ⁴Florida State University, Physics

Why did they need the MagLab?

Initial low-field EPR studies of the [K(crypt)]+[Cp_3^′PrII]- complex produced complicated spectra that were difficult to interpret due to many magnetic variables of the PrII ion. In contrast, the high-field EPR spectra obtained at the MagLab were much clearer and easier to analyze. Although the spin coherence of PrII wasn't better at high fields, the analysis helped identify a "clock transition" at low magnetic fields, where the coherence properties significantly improved. A "clock transition" is a specific point in an atomic or molecular system where the energy levels become less sensitive to external disturbances, such as magnetic field fluctuations.

Details for scientists

View or download the expert-level Science Highlight, High-Field EPR Identification of a Spin Clock Transition in the [Cp′₃Pr^II]– Qubit with a 4f²5d¹ Configuration
Read the full-length publication, Identification of an X-band Clock Transition in Cp′₃Pr - Enabled by a 4f²5d¹ Configuration, in Journal of the American Chemical Society

Funding

This research was funded by the following grants: K. M. Amm (NSF DMR-2128556); W. J. Evans (NSF CHE-2154255); S. G. Minasian (DOE BES DE-AC02-05CH11231)

For more information, contact Stephen Hill.