Kan Tagami scite author profile

The blinking and photobleaching dynamics of alizarin (1,2dihydroxyanthraquinone) and purpurin (1,2,4-trihydroxyanthraquinone) are investigated using single-molecule spectroscopy. The time-dependent emission of alizarin and purpurin on glass under N 2 is analyzed using the change point detection (CPD) method to compile on-and off-event distributions. The number of distinct emissive events per molecule is about four times higher for alizarin relative to purpurin, consistent with an excited-state intramolecular proton transfer (ESIPT) process to populate an emissive tautomer state. To elucidate the mechanism for blinking (i.e., switching between on and off events), maximum likelihood estimation (MLE), goodness-of-fit tests based on the Kolmogorov−Smirnov (KS) statistic, and the loglikelihood ratio (LLR) tests are used to establish the best fits to the on-and offinterval probability distributions. For both alizarin and purpurin the on intervals are log-normally distributed, and off intervals are Weibull distributed, consistent with a dispersive electron-transfer (ET) kinetics model for blinking (i.e., involving Gaussian-like distributions of activation barriers to ET). Further analysis of the blinking dynamics reveals that ET to a long-lived dark state most often precedes molecular photobleaching, where extended residency in the dark state increases the probability of photobleaching. Based on these findings, mechanisms for the blinking and photobleaching of alizarin and purpurin are proposed. The ability of alizarin to undergo ESIPT enables fast excited-state decay and decreases the probability of ET. In contrast, purpurin exhibits faster injection and slower back ET relative to alizarin, leading to increased photobleaching via a dark radical cation state.

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Balancing dipolar and exchange coupling in biradicals to maximize cross effect dynamic nuclear polarization

Equbal

Tagami

Han

2020

Phys. Chem. Chem. Phys.

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Biradical rotamer states tune electron J coupling and MAS dynamic nuclear polarization enhancement

Tagami

Equbal

Kaminker

et al. 2019

Solid State Nuclear Magnetic Resonance

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Role of electron spin dynamics and coupling network in designing dynamic nuclear polarization

Equbal

Jain

Tagami

et al. 2021

Progress in Nuclear Magnetic Resonance Spectroscopy

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Pulse-Shaped Dynamic Nuclear Polarization under Magic-Angle Spinning

Equbal

Tagami

Han

2019

J. Phys. Chem. Lett.

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Dynamic nuclear polarization (DNP) under magic-angle spinning (MAS) is transforming the scope of solid-state NMR by enormous signal amplification through transfer of polarization from electron spins to nuclear spins. Contemporary MAS-DNP exclusively relies on monochromatic continuous-wave (CW) irradiation of the electron spin resonance. This limits control on electron spin dynamics, which renders the DNP process inefficient, especially at higher magnetic fields and non cryogenic temperatures. Pulse-shaped microwave irradiation of the electron spins is predicted to overcome these challenges but hitherto has never been implemented under MAS. Here, we debut pulse-shaped microwave irradiation using arbitrary-waveform generation (AWG) which allows controlled recruitment of a greater number of electron spins per unit time, favorable for MAS-DNP. Experiments and quantum mechanical simulations demonstrate that pulse-shaped DNP is superior to CW-DNP for mixed radical system, especially when the electron spin resonance is heterogeneously broadened and/or when its spin−lattice relaxation is fast compared to the MAS rotor period, opening new prospects for MAS-DNP.

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Electron spin density matching for cross-effect dynamic nuclear polarization

2019

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Design of a cryogen-free high field dual EPR and DNP probe

Tagami

Thicklin

Jain

et al. 2023

Journal of Magnetic Resonance

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Pulse Shaped Dynamic Nuclear Polarization Under Magic Angle Spinning

Equbal¹,

Tagami²,

Han

2019

Preprint

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In this paper, we report on an entirely novel way of improving the MAS-DNP efficiency by shaped μw pulse train irradiation for fast and broad-banded (FAB) saturation of the electron spin resonance. FAB-DNP achieved with Arbitrary Wave Generated shaped μw pulse trains facilitates effective and selective saturation of a defined fraction of the total electron spins, and provides superior control over the DNP efficiency under MAS. Experimental and quantum-mechanics based numerically simulated results together demonstrate that FAB-DNP significantly outperforms CW-DNP when the EPR-line of PAs is broadened by conformational distribution and exchange coupling. We demonstrate that the maximum benefit of FAB DNP is achieved when the electron spin-lattice relaxation is fast relative to the MAS frequency, i.e. at higher temperatures and/or when employing metals as PAs. Calculations predict that under short T<sub>1e </sub>conditions AWG-DNP can achieve as much as ~4-fold greater enhancement compared to CW-DNP.

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Kan Tagami

Contributions from Excited-State Proton and Electron Transfer to the Blinking and Photobleaching Dynamics of Alizarin and Purpurin

Balancing dipolar and exchange coupling in biradicals to maximize cross effect dynamic nuclear polarization

Biradical rotamer states tune electron J coupling and MAS dynamic nuclear polarization enhancement

Role of electron spin dynamics and coupling network in designing dynamic nuclear polarization

Pulse-Shaped Dynamic Nuclear Polarization under Magic-Angle Spinning

Electron spin density matching for cross-effect dynamic nuclear polarization

Design of a cryogen-free high field dual EPR and DNP probe

Pulse Shaped Dynamic Nuclear Polarization Under Magic Angle Spinning

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