Kelly A. Cantwell scite author profile

We use microwave-induced dynamic nuclear polarization (DNP) of the substitutional nitrogen defects (P1 centers) in diamond to hyperpolarize bulk 13 C nuclei in both single crystal and powder samples at room temperature at 3.34 T. The large (>100-fold) enhancements demonstrated correspond to a greater than 10 000-fold improvement in terms of signal averaging of the 1% abundant 13 C spins. The DNP was performed using low-power solid state sources under static (nonspinning) conditions. The DNP spectrum (DNP enhancement as a function of microwave frequency) of diamond powder shows features that broadly correlate with the EPR spectrum. A well-defined negative Overhauser peak and two solid effect peaks are observed for the central ( m I = 0) manifold of the 14 N spins. Previous low temperature measurements in diamond had measured a positive Overhauser enhancement in this manifold. Frequency-chirped millimeter-wave excitation of the electron spins is seen to significantly improve the enhancements for the two outer nuclear spin manifolds ( m I = ±1) and to blur some of the sharper features associated with the central manifold. The outer lines are best fit using a combination of the cross effect and the truncated cross effect, which is known to mimic features of an Overhauser effect. Similar features are also observed in experiments on single crystal samples. The observation of all of these mechanisms in a single material system under the same experimental conditions is likely due to the significant heterogeneity of the high pressure, high temperature (HPHT) type Ib diamond samples used. Large room temperature DNP enhancements at fields above a few tesla enable spectroscopic studies with better chemical shift resolution under ambient conditions.

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Room temperature DNP of diamond powder using frequency modulation

Shimon

Cantwell

Joseph

et al. 2022

Solid State Nuclear Magnetic Resonance

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Electron Microburst Precipitation in Earth’s Magnetosphere

Millan

Sample

Sotirelis

et al. 2021

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Large Room Temperature Bulk DNP of $^{13}$C via P1 Centers in Diamond

Shimon¹,

Cantwell²,

Joseph³

et al. 2022

Preprint

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We use microwave-induced dynamic nuclear polarization (DNP) of the substitutional nitrogen defects (P1 centers) in diamond to hyperpolarize bulk 13 C nuclei in both single crystal and powder samples at room temperature at 3.34 T. The large (> 100-fold) enhancements demonstrated correspond to a greater than 10,000 fold improvement in terms of signal averaging of the 1% abundant 13 C spins. The DNP was performed using low-power solid state sources under static (non-spinning) conditions. The DNP spectrum (DNP enhancement as a function of microwave frequency) of diamond powder shows features that broadly correlate with the EPR spectrum. A well-defined negative Overhauser peak and two solid effect peaks are observed for the central (mI = 0) manifold of the 14 N spins. Previous low temperature measurements in diamond had measured a positive Overhauser enhancement in this manifold. Frequency-chirped millimeter-wave excitation of the electron spins is seen to significantly improve the enhancements for the two outer nuclear spin manifolds (mI = ±1) and to blur some of the sharper features associated with the central manifolds. The outer lines are best fit using a combination of the cross effect and a truncated cross effect -which is known to mimic features of an Overhauser effect. Similar features are also observed in experiments on single crystal samples. The observation of all of these mechanisms in a single material system under the same experimental conditions is likely due to the significant heterogeneity of the high pressure, high temperature (HPHT) type Ib diamond samples used. Large room temperature DNP enhancements at fields above a few Tesla enable spectroscopic studies with better chemical shift resolution under ambient conditions.

show abstract

Room Temperature DNP of Diamond Powder Using Frequency Modulation

Shimon¹,

Cantwell²,

Joseph³

et al. 2022

Preprint

View full text Add to dashboard Cite

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Kelly A. Cantwell

Large Room Temperature Bulk DNP of ¹³C via P1 Centers in Diamond

Room temperature DNP of diamond powder using frequency modulation

Electron Microburst Precipitation in Earth’s Magnetosphere

Large Room Temperature Bulk DNP of $^{13}$C via P1 Centers in Diamond

Room Temperature DNP of Diamond Powder Using Frequency Modulation

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Resources

About

Kelly A. Cantwell

Large Room Temperature Bulk DNP of 13C via P1 Centers in Diamond

Room temperature DNP of diamond powder using frequency modulation

Electron Microburst Precipitation in Earth’s Magnetosphere

Large Room Temperature Bulk DNP of $^{13}$C via P1 Centers in Diamond

Room Temperature DNP of Diamond Powder Using Frequency Modulation

Contact Info

Product

Resources

About

Large Room Temperature Bulk DNP of ¹³C via P1 Centers in Diamond