Room Temperature DNP of Diamond Powder Using Frequency Modulation

TL;DR

This study demonstrates that frequency modulation of microwave irradiation can significantly enhance room-temperature DNP signals in diamond powders, enabling selective control over different polarization transfer mechanisms.

Contribution

It is the first to analyze the effects of frequency modulation on multiple DNP mechanisms, including OE and tCE, at room temperature in diamond powders.

Findings

Frequency modulation improves DNP enhancement compared to monochromatic irradiation.

Modulation parameters can selectively enhance or suppress specific DNP mechanisms.

Room-temperature DNP in diamond powders can involve multiple simultaneous mechanisms.

Abstract

Dynamic nuclear polarization (DNP) is a method of enhancing NMR signals via the transfer of polarization from electron spins to nuclear spins using on-resonance microwave (MW) irradiation. In most cases, monochromatic continuous-wave (MCW) MW irradiation is used. Recently, several groups have shown that the use of frequency modulation of the MW irradiation can result in an additional increase in DNP enhancement above that obtained with MCW. The effect of frequency modulation on the solid effect (SE) and the cross effect (CE) has previously been studied using the stable organic radical 4-hydroxy TEMPO (TEMPOL) at temperatures under 20 K. Here, in addition to the SE and CE, we discuss the effect of frequency modulation on the Overhauser effect (OE) and the truncated CE (tCE) in the room-temperature $^{13}$C-DNP of diamond powders. We recently showed that diamond powders can exhibit multiple DNP mechanisms simultaneously due to the heterogeneity of P1 (substitutional nitrogen) environments within diamond crystallites. We explore the enhancement obtained via the two most important parameters for frequency modulation 1) Modulation frequency, $f_{m}$ (how fast the modulation frequency is varied) and 2) Modulation amplitude, $\Delta\omega$ (the magnitude of the change in microwave frequency) influence the enhancement obtained via each mechanism. Frequency modulation during DNP not only allows us to improve DNP enhancement, but also gives us a way to control which DNP mechanism is most active. By choosing the appropriate modulation parameters, we can selectively enhance some mechanisms while simultaneously suppressing others.