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219 results on '"Equbal, Asif"'

1. Role of Quantum Coherence in Chirped Dynamic Nuclear Polarization

Author

Jhamnani, Mayur, Sadasivan, Sajith V, Jain, Sheetal Kumar, and Equbal, Asif

Subjects
Quantum Physics
Abstract

Dynamic Nuclear Polarization (DNP) is transforming NMR and MRI by significantly enhancing sensitivity through the transfer of polarization from electron spins to nuclear spins via microwave irradiation. However, the use of monochromatic continuous-wave (CW) irradiation limits the efficiency of DNP for systems with heterogeneous broad EPR lines. Broad-band techniques such as chirp irradiation offer a solution, particularly for Solid Effect (SE) DNP in such cases. Despite its widespread use, the role of quantum coherence generated during chirp irradiation remains unclear, even though it is a key factor in determining the maximum achievable DNP efficiency. In this work, we use density matrix formalism to provide a comprehensive understanding of the quantum coherence generated during electron-nucleus double-quantum (DQ) and zero-quantum (ZQ) SE transitions and their impact on Integrated Solid Effect (ISE) DNP under chirp irradiation. Our analysis employs fictitious product-operator bases to trace the evolution of electron-nucleus coherence leading to integrated or differentiated SE. We also explore the previously unexamined role of decoherence in optimizing chirped DNP. These findings provide new insights into low-temperature DNP and triplet DNP using photoexcited electrons.

Published
2024

3. Dipolar Order Induced Electron Spin Hyperpolarization.

Author

Equbal, Asif, Ramanathan, Chandrasekhar, and Han, Songi

Abstract

The structure of coupled electron spin systems is of fundamental interest to many applications, including dynamic nuclear polarization (DNP), enhanced nuclear magnetic resonance (NMR), the generation of electron spin qubits for quantum information science (QIS), and quantitative studies of paramagnetic systems by electron paramagnetic resonance (EPR). However, the characterization of electron spin coupling networks is nontrivial, especially at high magnetic fields. This study focuses on a system containing high concentrations of trityl radicals that give rise to a DNP enhancement profile of 1H NMR characteristic of the presence of electron spin clusters. When this system is subject to selective microwave saturation through pump-probe ELectron DOuble Resonance (ELDOR) experiments, electron spin hyperpolarization is observed. We show that the generation of an out-of-equilibrium longitudinal dipolar order is responsible for the transient hyperpolarization of electron spins. Notably, the coupled electron spin system needs to form an AX-like system (where the difference in the Zeeman interactions of two spins is larger than their coupling interaction) such that selective microwave irradiation can generate signatures of electron spin hyperpolarization. We show that the extent of dipolar order, as manifested in the extent of electron spin hyperpolarization generated, can be altered by tuning the pump or probe pulse length, or the interpulse delay in ELDOR experiments that change the efficiency to generate or readout longitudinal dipolar order. Pump-probe ELDOR with selective saturation is an effective means for characterizing coupled electron spins forming AX-type spin systems that are foundational for DNP and quantum sensing.

Published
2024

4. P1 center electron spin clusters are prevalent in type Ib diamond

Author

Bussandri, Santiago, Shimon, Daphna, Equbal, Asif, Ren, Yuhang, Takahashi, Susumu, Ramanathan, Chandrasekhar, and Han, Songi

Subjects
Physics - Chemical Physics, Quantum Physics
Abstract

Understanding the spatial distribution of P1 centers is crucial for diamond-based sensors and quantum devices. P1 centers serve as a polarization source for DNP quantum sensing and play a significant role in the relaxation of NV centers. Additionally, the distribution of NV centers correlates with the distribution of P1 centers, as NV centers are formed through the conversion of P1 centers. We utilized dynamic nuclear polarization (DNP) and pulsed electron paramagnetic resonance (EPR) techniques that revealed strong clustering of a significant population of P1 centers that exhibit exchange coupling and produce asymmetric lineshapes. The $^{13}$C DNP frequency profile at high magnetic field revealed a pattern that requires an asymmetric EPR lineshape of the P1 clusters with electron-electron (e-e) coupling strengths exceeding the $^{13}$C nuclear Larmor frequency. EPR and DNP characterization at high magnetic fields was necessary to resolve energy contributions from different e-e couplings. We employed a two-frequency pump-probe pulsed Electron Double Resonance (ELDOR) technique to show crosstalk between the isolated and clustered P1 centers. This finding implies that the clustered P1 centers affect all P1 populations. Direct observation of clustered P1 centers and their asymmetric lineshape is a novel and crucial insight into understanding magnetic noise sources for quantum information applications of diamonds and for designing diamond-based polarizing agents with optimized DNP efficiency for $^{13}$C and other nuclear spins of analytes. We propose that room temperature $^{13}$C DNP at high field, achievable through straightforward modifications to existing solution-state NMR systems, is a potent tool for evaluating and controlling diamond defects.

Published
2023

5. Direct Sensing of Remote Nuclei: Expanding the Reach of Cross-Effect Dynamic Nuclear Polarization

Author

Javed, Amaria and Equbal, Asif

Subjects
Physics - Chemical Physics
Abstract

Dynamic Nuclear Polarization (DNP) has revolutionized the field of solid-state NMR spectroscopy by significantly enhancing the sensitivity of nuclear magnetic resonance experiments. Conventionally, cross effect DNP relies on biradicals to transfer polarization from coupled electron spins to nearby nuclear spins and subsequent relay to target nuclei via spin diffusion mechanism. However, the direct transfer of polarization to distant nuclei remains a significant challenge, limiting its applicability in various contexts. In this work, we propose a novel biradical design concept that involves a very strong electron-electron coupling, with a magnitude of hundreds of MHz, which enables efficient direct polarization transfer from electron spins to nuclear spins over much longer distances, exceeding 2.0 nm. We discuss the potential of this tailored biradicals in scenarios where conventional spin diffusion mechanisms are inefficient or when direct nuclear spin sensing through electron spin interactions is desired. Our study presents a promising avenue for expanding the scope of cross effect DNP in solid-state NMR spectroscopy and opens new opportunities for investigating a wide range of biological and material systems. Our research also provides insight into the DNP buildup time of commercially available biradicals.

Published
2023

6. Magic-NOVEL: Suppressing electron–electron coupling effects in pulsed DNP.

Author

Javed, Amaria, Ghazi, Marwa Yaser, SubbaRao Redrouthu, Venkata, and Equbal, Asif

Subjects
POLARIZATION (Nuclear physics), NUCLEAR spin, NUCLEAR magnetic resonance, ELECTRON spin, POLARIZED electrons
Abstract

Pulsed dynamic nuclear polarization (DNP) enhances the nuclear magnetic resonance sensitivity by coherently transferring electron spin polarization to dipolar coupled nuclear spins. Recently, many new pulsed DNP techniques such as NOVEL, TOP, XiX, TPPM, and BEAM have been introduced. Despite significant progress, numerous challenges remain unsolved. The electron–electron (e–e) interactions in these sequences can severely disrupt the efficiency of electron–nuclear (e–n) polarization transfer. In order to tackle this issue, we propose the magic-NOVEL DNP method, utilizing Lee–Goldburg decoupling to counteract e–e coupling effects. Our theoretical analysis and quantum mechanical simulations reveal that magic-NOVEL significantly improves the transfer efficiency of DNP, even at shorter e–e distances. This method offers a new perspective for advancing pulsed DNP techniques in systems with dense electron spin baths. Furthermore, we demonstrate the effectiveness of phase-modulated Lee–Goldburg sequences in improving pulsed DNP transfer. [ABSTRACT FROM AUTHOR]

Published
2025
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12. Electron spin density matching for cross-effect dynamic nuclear polarization

Author

Li, Yuanxin, Equbal, Asif, Tagami, Kan, and Han, Songi

Subjects
Chemical Sciences, Organic Chemistry, Chemical sciences, Engineering
Abstract

A new design principle for a mixed broad (TEMPO) and narrow (Trityl) line radical to boost the dynamic nuclear polarization efficiency is electron spin density matching, suggesting a polarizing agent of one Trityl tethered to at least two TEMPO moieties.

Published
2019

13. Tuning nuclear depolarization under MAS by electron T 1e

Author

Lund, Alicia, Equbal, Asif, and Han, Songi

Subjects
Chemical Physics
Abstract

The Cross-Effect (CE) Dynamic Nuclear Polarization (DNP) mechanism under Magic Angle Spinning (MAS) induces depletion or "depolarization" of the NMR signal, in the absence of microwave irradiation. In this study, the role of T1e on nuclear depolarization under MAS was tested experimentally by systematically varying the local and global electron spin concentration using mono-, bi- and tri-radicals. These spin systems show different depolarization effects that systematically tracked with their different T1e rates, consistent with theoretical predictions. In order to test whether the effect of T1e is directly or indirectly convoluted with other spin parameters, the tri-radical system was doped with different concentrations of GdCl3, only tuning the T1e rates, while keeping other parameters unchanged. Gratifyingly, the changes in the depolarization factor tracked the changes in the T1e rates. The experimental results are corroborated by quantum mechanics based numerical simulations which recapitulated the critical role of T1e. Simulations showed that the relative orientation of the two g-tensors and e-e dipolar interaction tensors of the CE fulfilling spin pair also plays a major role in determining the extent of depolarization, besides the enhancement. This is expected as orientations influence the efficiency of the various level anti-crossings or the "rotor events" under MAS. However, experimental evaluation of the empirical spectral diffusion parameter at static condition showed that the local vs. global e-e dipolar interaction network is not a significant variable in the commonly used nitroxide radical system studied here, leaving T1e rates as the major modulator of depolarization.

Published
2018

14. Truncated Cross Effect Dynamic Nuclear Polarization: An Overhauser Effect Doppelgänger.

Author

Equbal, Asif, Li, Yuanxin, Leavesley, Alisa, Huang, Shengdian, Rajca, Suchada, Rajca, Andrzej, and Han, Songi

Abstract

The discovery of a truncated cross-effect (CE) in dynamic nuclear polarization (DNP) NMR that has the features of an Overhauser-effect DNP (OE-DNP) is reported here. The apparent OE-DNP, where minimal μw power achieved optimum enhancement, was observed when doping Trityl-OX063 with a pyrroline nitroxide radical that possesses electron-withdrawing tetracarboxylate substituents (tetracarboxylate-ester-pyrroline or TCP) in vitrified water/glycerol at 6.9 T and at 3.3 to 85 K, in apparent contradiction to expectations. While the observations are fully consistent with OE-DNP, we discover that a truncated cross-effect ( tCE) is the underlying mechanism, owing to TCPs shortened T1e. We take this observation as a guideline and demonstrate that a crossover from CE to tCE can be replicated by simulating the CE of a narrow-line (Trityl-OX063) and a broad-line (TCP) radical pair, with a significantly shortened T1e of the broad-line radical.

Published
2018

18. A critical review on electro-discharge machining of non-conductive materials.

Author

Equbal, Azhar, Equbal, Asif, VMS, Hussain, Equbal, Israr, Badruddin, Irfan Anjum, Kamangar, Sarfaraz, Edacherian, Abhilash, and Khan, Abdul Azeem

Subjects
*MACHINING, *MANUFACTURING processes, *MACHINE tools, *BRITTLE materials, *RESEARCH personnel
Abstract

Electrical discharge machining (EDM) is a nontraditional machining process known for processing of hard, brittle and difficult-to-machine materials. EDM is precisely known for machining of conductive materials, but recent advancements in material processing techniques and machining technology have shown that there is a great possibility in the machining of non-conductive materials using EDM. Existing researches proposed important processing methods for EDM of non-conductive materials. However, there is a need for a collective study showing the ease, merits and limitations of suggested methods. In a similar direction, this article is aimed at presenting a critical insight on machining of non-conductive materials using EDM. This article is devoted toward exploring the several possibilities of machining non-conductive materials by EDM. Research survey was carried out by collecting research papers using "EDM" and "Non-conductive" materials as the keywords. Research papers were collected from Scopus and web of science from 2008 to 2023. The presented study is expected to help the researchers and practitioners to choose the machining method wisely and effectively to satisfy the EDM of non-conductive materials. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Dynamic Nuclear Polarization Using Electron Spin Cluster

Author

Chaklashiya, Raj K., primary, Equbal, Asif, additional, Shernyukov, Andrey, additional, Li, Yuanxin, additional, Tsay, Karen, additional, Stern, Quentin, additional, Tormyshev, Victor, additional, Bagryanskaya, Elena, additional, and Han, Songi, additional

Published
2024
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22. Hyperpolarisation techniques

Author

Hodgkinson, Paul, Sauri, Josep, Equbal, Asif, Mewis, Ryan E, Hodgkinson, Paul, Sauri, Josep, Equbal, Asif, and Mewis, Ryan E

Abstract

This chapter focuses on the literature published in 2023 covering hyperpolarisation techniques associated with NMR. The literature reviewed relates to the hyperpolarisation techniques of Dynamic Nuclear Polarisation (DNP), Spin-Exchange Optical Pumping (SEOP), Parahydrogen Induced Polarisation (PHIP) and Signal Amplification by Reversible Exchange (SABRE). In addition to reviewing studies that have been conducted using these techniques, a number of reports are discussed that relate to advances in associated hardware and instrumentation.

Published
2024

34. Hyperpolarisation Techniques

Author

Hodgkinson, Paul, Sauri, Josep, Equbal, Asif, Mewis, Ryan, Hodgkinson, Paul, Sauri, Josep, Equbal, Asif, and Mewis, Ryan

Abstract

This chapter focuses on the literature published in 2022, covering hyperpolarisation techniques associated with NMR. The literature reviewed relates to the hyperpolarisation techniques of dynamic nuclear polarisation (DNP), spin-exchange optical pumping (SEOP), parahydrogen induced polarisation (PHIP) and signal amplification by reversible exchange (SABRE). In addition to reviewing studies that have been conducted using these techniques, a number of reports are discussed that relate to advances in associated hardware and instrumentation.

Published
2023

49. A unified heteronuclear decoupling picture in solid-state NMR under low radio-frequency amplitude and fast magic-angle-spinning frequency regime.

Author

Sharma, Kshama, Equbal, Asif, Nielsen, Niels Chr., and Madhu, P. K.

Subjects
*RADIO frequency, *NUCLEAR spin, *MAGIC angle spinning, *COMPUTER simulation
Abstract

Heteronuclear spin decoupling is a highly important component of solid-state NMR experiments to remove undesired coupling interactions between unlike spins for spectral resolution. Recently, experiments using a unification strategy of standard decoupling schemes were presented for high radio-frequency (RF) amplitudes and slow-intermediate magic-angle-spinning (MAS) frequencies, in the pursuit of deeper understanding of spin decoupling under phase-modulated RF irradiation [A. Equbal et al., J. Chem. Phys. 142, 184201 (2015)]. The approach, unified two-pulse heteronuclear decoupling (UTPD), incorporates the simultaneous time- and phase-modulation strategies, commonly used in solid-state NMR. Here, the UTPD based decoupling scheme is extended to the experimentally increasingly important regime of low RF amplitudes and fast MAS frequencies. The unified decoupling approach becomes increasingly effective in identifying the deleterious dipole-dipole and, in particular, J recoupling conditions which become critical for the low-amplitude RF regime. This is because J coupling is isotropic and therefore not averaged out by sample spinning unlike the anisotropic dipole-dipole coupling. Numerical simulations and analytic theory are used to understand the effects of various nuclear spin interactions on the decoupling performance of UTPD, in particular, the crucial difference between the low-phase and high-phase UTPD conditions with respect to J coupling. In the UTPD scheme, when the cycle-frequency of the pulse-sequence is comparable to the RF nutation frequency, the existence of a non-zero effective rotation in the basic two-pulse scheme becomes an essential feature for the efficient and robust averaging out of the scalar J coupling. This broad viewpoint is expected to bring different optimum low-power decoupling pulse schemes under a common footing. [ABSTRACT FROM AUTHOR]

Published
2019
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