Your search keyword '"Pustelny, S."' showing total 34 results

1. Constraints on exotic spin-dependent interactions between electrons from helium fine-structure spectroscopy

Author

Ficek, F, Kimball, DFJ, Kozlov, MG, Leefer, N, Pustelny, S, and Budker, D

Subjects

physics.atom-ph, hep-ph

Abstract

Agreement between theoretical calculations of atomic structure and spectroscopic measurements is used to constrain possible contribution of exotic spin-dependent interactions between electrons to the energy differences between states in helium-4. In particular, constraints on dipole-dipole interactions associated with the exchange of pseudoscalar bosons (such as axions or axion-like particles) with masses 10-2"m"104eV are improved by a factor of ∼100. The first atomic-scale constraints on several exotic velocity-dependent dipole-dipole interactions are established as well.

Published

2017

2. Characterization of high-temperature performance of cesium vapor cells with anti-relaxation coating

Author

Li, W, Balabas, M, Peng, X, Pustelny, S, Wickenbrock, A, Guo, H, and Budker, D

Subjects

physics.atom-ph, Applied Physics, Mathematical Sciences, Physical Sciences, Engineering

Abstract

Vapor cells with antirelaxation coating are widely used in modern atomic physics experiments due to the coating's ability to maintain the atoms' spin polarization during wall collisions. We characterize the performance of vapor cells with different coating materials by measuring longitudinal spin relaxation and vapor density at temperatures up to 95 °C. We infer that the spin-projection-noise-limited sensitivity for atomic magnetometers with such cells improves with temperature, which demonstrates the potential of antirelaxation coated cells in applications of future high-sensitivity magnetometers.

Published

2017

3. Magnetic shielding and exotic spin-dependent interactions

Author

Jackson Kimball, DF, Dudley, J, Li, Y, Thulasi, S, Pustelny, S, Budker, D, and Zolotorev, M

Subjects

physics.ins-det, hep-ph

Abstract

Experiments searching for exotic spin-dependent interactions typically employ magnetic shielding between the source of the exotic field and the interrogated spins. We explore the question of what effect magnetic shielding has on detectable signals induced by exotic fields. Our general conclusion is that for common experimental geometries and conditions, magnetic shields should not significantly reduce sensitivity to exotic spin-dependent interactions, especially when the technique of comagnetometry is used. However, exotic fields that couple to electron spin can induce magnetic fields in the interior of shields made of a soft ferromagnetic or ferrimagnetic material. This induced magnetic field must be taken into account in the interpretation of experiments searching for new spin-dependent interactions and raises the possibility of using a flux concentrator inside magnetic shields to amplify exotic spin-dependent signals.

Published

2016

4. Magnetic shielding and exotic spin-dependent interactions

Author

Kimball, DF Jackson, Dudley, J, Li, Y, Thulasi, S, Pustelny, S, Budker, D, and Zolotorev, M

Subjects

physics.ins-det, hep-ph, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Quantum Physics, Nuclear & Particles Physics

Abstract

Experiments searching for exotic spin-dependent interactions typically employ magnetic shielding between the source of the exotic field and the interrogated spins. We explore the question of what effect magnetic shielding has on detectable signals induced by exotic fields. Our general conclusion is that for common experimental geometries and conditions, magnetic shields should not significantly reduce sensitivity to exotic spin-dependent interactions, especially when the technique of comagnetometry is used. However, exotic fields that couple to electron spin can induce magnetic fields in the interior of shields made of a soft ferromagnetic or ferrimagnetic material. This induced magnetic field must be taken into account in the interpretation of experiments searching for new spin-dependent interactions and raises the possibility of using a flux concentrator inside magnetic shields to amplify exotic spin-dependent signals.

Published

2016

5. Vector light shift averaging in paraffin-coated alkali vapor cells

Author

Zhivun, E, Wickenbrock, A, Sudyka, J, Patton, B, Pustelny, S, and Budker, D

Subjects

physics.atom-ph, Optics, Optical Physics, Communications Technologies, Electrical and Electronic Engineering

Abstract

Light shifts are an important source of noise and systematics in optically pumped magnetometers. We demonstrate that the long spin-coherence time in paraffin-coated cells leads to spatial averaging of the vector light shift over the entire cell volume. This renders the averaged vector light shift independent, under certain approximations, of the light-intensity distribution within the sensor cell. Importantly, the demonstrated averaging mechanism can be extended to other spatially varying phenomena in anti-relaxation-coated cells with long coherence times.

Published

2016

6. Dichroic atomic vapor laser lock with multi-gigahertz stabilization range.

Author

Pustelny, S, Schultze, V, Scholtes, T, and Budker, D

Subjects

physics.ins-det, physics.atom-ph, physics.optics, Applied Physics, Engineering, Physical Sciences, Chemical Sciences

Abstract

A dichroic atomic vapor laser lock (DAVLL) system exploiting buffer-gas-filled millimeter-scale vapor cells is presented. This system offers similar stability as achievable with conventional DAVLL system using bulk vapor cells, but has several important advantages. In addition to its compactness, it may provide continuous stabilization in a multi-gigahertz range around the optical transition. This range may be controlled either by changing the temperature of the vapor or by application of a buffer gas under an appropriate pressure. In particular, we experimentally demonstrate the ability of the system to lock the laser frequency between two hyperfine components of the (85)Rb ground state or as far as 16 GHz away from the closest optical transition.

Published

2016

7. Efficient polarization of high-angular-momentum systems

Author

Rochester, S, Pustelny, S, Szymański, K, Raizen, M, Auzinsh, M, and Budker, D

Subjects

physics.atom-ph

Abstract

We present a novel technique of efficient optical pumping of open, high-angular-momentum systems. The method combines two well-established approaches of population manipulation (conventional optical pumping and coherent population transfer), offering the ability to achieve higher population of a sublevel with the highest or lowest quantum number m (the "end state") than obtainable with either of the techniques. To accomplish this task, we propose to use coherent-population-transfer technique (e.g., adiabatic fast passage) to arrange the system in such a way that spontaneously emitted photon (conventional optical pumping) carries away more entropy than in conventional schemes. This enables reduction of a number of spontaneous decays Nsd required to pump the system with the total angular momentum J from Nsd = J decays in the conventional scheme to Nsd ≤ log2(2J) decays in the proposed scheme. Since each spontaneous-emission event is potentially burdened with a loss of population (population is transferred to a dark state), this enables increasing population accumulated in the "end state", which is important for many applications.

Published

2016

8. Production and detection of atomic hexadecapole at Earth's magnetic field

Author

Acosta, V. M, Auzinsh, M., Gawlik, W., Grisins, P., Higbie, J. M, Jackson Kimball, D. F, Krzemien, L., Ledbetter, M. P, Pustelny, S., Rochester, S. M, Yashchuk, V. V, and Budker, D.

Subjects

BRII recipient: Budker

Abstract

Optical magnetometers measure magnetic fields with extremely high precision and without cryogenics. However, at geomagnetic fields, important for applications from landmine removal to archaeology, they suffer from nonlinear Zeeman splitting, leading to systematic dependence on sensor orientation. We present experimental results on a method of eliminating this systematic error, using the hexadecapole atomic polarization moment. In particular, we demonstrate selective production of the atomic hexadecapole moment at Earth’s magnetic field and verify its immunity to nonlinear Zeeman splitting. This technique promises to eliminate directional errors in all-optical atomic magnetometers, potentially improving their measurement accuracy by several orders of magnitude.

Published

2008

9. Zero-field nuclear magnetic resonance spectroscopy of viscous liquids

Author

Shimizu, Y., Blanchard, J.W., Pustelny, S., Saielli, G., Bagno, A., Ledbetter, M.P., Budker, D., and Pines, A.

Published

2015

10. Magnetometry based on nonlinear magneto-optical rotation with amplitude-modulated light.

Author

Pustelny, S., Wojciechowski, A., Gring, M., Kotyrba, M., Zachorowski, J., and Gawlik, W.

Subjects

*MAGNETIC properties, *AMPLITUDE modulation, *MAGNETOMETERS, *MAGNETIC fields, *PHYSICS

Abstract

We report on an all-optical magnetometric technique based on nonlinear magneto-optical rotation with amplitude-modulated light. The method enables sensitive magnetic field measurements in a broad dynamic range. We demonstrate the sensitivity of [formula] at 10 mG and the magnetic field tracking in a range of 40 mG. The fundamental limits of the method sensitivity and factors determining current performance of the magnetometer are discussed. [ABSTRACT FROM AUTHOR]

Published

2008

11. Limitations of rotating-wave approximation in magnetic resonance: characterization and elimination of the Bloch–Siegert shift in magneto-optics.

Author

Sudyka, J I, Pustelny, S, and Gawlik, W

Subjects

*MAGNETIC resonance, *MAGNETOOPTICS, *MAGNETIC fields, *QUANTUM information science, *MAGNETICS, *QUBITS

Abstract

We present investigations of radio-frequency (RF) resonances observed in an optically pumped rubidium vapor. By measuring the systematic shifts (the Bloch–Siegert shifts) of RF resonances in low magnetic fields, we demonstrate limitations of the rotating-wave approximation in the case of angular momentum F ≥ 1. The resonance shifts and deformations are characterized in a wide range of parameters and it is shown that the observed behavior is far more complex than in a standard two-level system. It is also demonstrated that the shifts can be controllably turned on or off by switching between the oscillating and rotating magnetic field. Experimental results are supported with numerical calculations, reproducing all features of the observed signals. Besides fundamental aspect of the research, application of rotating magnetic field helps to suppress/evaluate spectroscopic-measurement and precise-metrology systematic errors. The reported study has also important implications for quantum metrology and information processing beyond RWA and standard two-state qubit dynamics. [ABSTRACT FROM AUTHOR]

Published

2019

12. System for control of polarization state of light and generation of light with continuously rotating linear polarization.

Author

Włodarczyk, P., Pustelny, S., and Budker, D.

Subjects

*ARBITRARY constants, *OPTICAL polarization, *OPTICAL interference, *INTERFEROMETERS, *ACOUSTO-optic materials, *MAGNETOMETERS

Abstract

We present a technique for generating light in an arbitrary polarization state. The technique is based on interference of two orthogonally polarized light beams, whose amplitudes and phases are controlled with a Mach-Zehnder inteferometer with acousto-optic modulators (AOMs) placed in each arm. We demonstrate that via control over amplitudes, phases, and frequencies of acoustic waves driving the AOMs, any polarization state can be synthesized. In particular, we demonstrate generation of linearly polarized light, whose polarization plane continuously rotates at a rate from 1 kHz to 1 MHz. Such light finds applications in science (e.g., investigations of Bloch-Siegert effect) and technology (optically pumped magnetometers). [ABSTRACT FROM AUTHOR]

Published

2019

13. Characterization of the global network of optical magnetometers to search for exotic physics (GNOME).

Author

Afach, S., Budker, D., DeCamp, G., Dumont, V., Grujić, Z.D., Guo, H., Jackson Kimball, D.F., Kornack, T.W., Lebedev, V., Li, W., Masia-Roig, H., Nix, S., Padniuk, M., Palm, C.A., Pankow, C., Penaflor, A., Peng, X., Pustelny, S., Scholtes, T., and Smiga, J.A.

Abstract

Abstract The Global Network of Optical Magnetometers to search for Exotic physics (GNOME) is a network of geographically separated, time-synchronized, optically pumped atomic magnetometers that is being used to search for correlated transient signals heralding exotic physics. The GNOME is sensitive to nuclear- and electron-spin couplings to exotic fields from astrophysical sources such as compact dark-matter objects (for example, axion stars and domain walls). Properties of the GNOME sensors such as sensitivity, bandwidth, and noise characteristics are studied in the present work, and features of the network's operation (e.g., data acquisition, format, storage, and diagnostics) are described. Characterization of the GNOME is a key prerequisite to searches for and identification of exotic physics signatures. [ABSTRACT FROM AUTHOR]

Published

2018

14. Detecting Domain Walls of Axionlike Models Using Terrestrial Experiments.

Author

Pospelov, M., Pustelny, S., Ledbetter, M. P., Kimball, D. F. Jackson, Gawlik, W., and Budker, D.

Subjects

*SOLAR-terrestrial physics, *TOPOLOGICAL defects (Physics), *DARK energy, *GRAVITATIONAL fields, *COSMOCHRONOLOGY

Abstract

Stable topological defects of light (pseudo)scalar fields can contribute to the Universe's dark energy and dark matter. Currently, the combination of gravitational and cosmological constraints provides the best limits on such a possibility. We take an example of domain walls generated by an axionlike field with a coupling to the spins of standard-model particles and show that, if the galactic environment contains a network of such walls, terrestrial experiments aimed at the detection of wall-crossing events are realistic. In particular, a geographically separated but time-synchronized network of sensitive atomic magneto­meters can detect a wall crossing and probe a range of model parameters currently unconstrained by astrophysical observations and gravitational experiments. [ABSTRACT FROM AUTHOR]

Published

2013

15. Liquid-State Nuclear Spin Comagnetometers.

Author

Ledbetter, M. R., Pustelny, S., Budker, D., Romalis, M. V., Blanchard, J. W., and Pines, A.

Subjects

*NUCLEAR spin, *MAGNETOMETERS, *NUCLEAR magnetic resonance, *FLUORINE isotopes, *SOLVENTS, *SENSITIVITY analysis, *QUANTUM interference, *DIPOLE moments

Abstract

We discuss nuclear spin comagnetometers based on ultralow-field nuclear magnetic resonance in mixtures of miscible solvents, each rich in a different nuclear spin. In one version thereof, Larmor precession of protons and 19F nuclei in a mixture of thermally polarized pentane and hexafluorobenzene is monitored via a sensitive alkali-vapor magnetometer. We realize transverse relaxation times in excess of 20 s and suppression of magnetic field fluctuations by a factor of 3400. We estimate it should be possible to achieve single-shot sensitivity of about 5 X 10-9 Hz, or about 5 X 10-11 Hz in = 1 day of integration. In a second version, spin precession of protons and 129Xe nuclei in a mixture of pentane and hyper-polarized liquid xenon is monitored using superconducting quantum interference devices. Application to spin-gravity experiments, electric dipole moment experiments, and sensitive gyroscopes is discussed. [ABSTRACT FROM AUTHOR]

Published

2012

16. Room temperature femtotesla radio-frequency atomic magnetometer.

Author

Chalupczak, W., Godun, R. M., Pustelny, S., and Gawlik, W.

Subjects

MAGNETOMETERS, RADIO frequency, LASERS, CESIUM, MAGNETIC instruments

Abstract

A radio-frequency tunable atomic magnetometer with a sensitivity of about 1 fT/Hz1/2 in a range of 10-500 kHz is demonstrated. The magnetometer is operated in the orientation configuration in which atoms are pumped to the stretched atomic state by a scheme based on indirect optical pumping using only one unmodulated, low-power laser. The magnetometer operates with cesium atoms, which have sufficient vapor pressure near room temperature to enable high magnetometric sensitivities. The technique enables a compact and robust module to be constructed that could become an in-the-field device. [ABSTRACT FROM AUTHOR]

Published

2012

17. Experimental and Theoretical Study of Light Propagation in Suspended-Core Optical Fiber.

Author

GRABK, M., WAJNCHOLD, B., PUSTELNY, S., GAWLIK, W., SKORUPSKI2, K., and MERGO, P.

Subjects

FIBER optics, COUPLING constants, PARTICLES (Nuclear physics), OPTICAL fibers, COMPUTER simulation, MICROSTRUCTURE

Abstract

We analyze coupling and propagation of light through a suspended-core microstructured optical fiber. It is experimentally demonstrated that light-coupling efficiency and mode distribution strongly depend on relative position of the fiber's core and a light beam and light polarization. The experimental results are supported with numerical simulations. The developed numerical model confirmed all the observed dependences. [ABSTRACT FROM AUTHOR]

Published

2010

18. Nonlinear magneto-optical rotation with amplitude modulated light.

Author

Gawlik, W., Krzemień, L., Pustelny, S., Sangla, D., Zachorowski, J., Graf, M., Sushkov, A. O., and Budker, D.

Subjects

NONLINEAR optics, MAGNETOOPTICS, OPTICS, MAGNETIC fields, RESONANCE, SEMICONDUCTORS

Abstract

The technique of nonlinear magneto-optical rotation with amplitude modulated light is developed. The technique is an alternative to its counterpart with frequency modulated light and can be applied to sensitive measurements of magnetic fields ranging from microgauss to the Earth-field level. The rotation signals exhibit nontrivial features such as narrowed non-Lorentzian line shapes and multicomponent resonances. [ABSTRACT FROM AUTHOR]

Published

2006

19. Modeling an optical magnetometer with electronic circuits — analysis and optimization.

Author

Włodarczyk, P., Pustelny, S., Zachorowski, J., and Lipiński, M.

Published

2012

20. Long-Lived Heteronuclear Spin-Singlet States in Liquids at a Zero Magnetic field.

Author

Emondts, M., Ledbetter, M. P., Pustelny, S., Theis, T., Patton, B., Blanchard, J. W., Butler, M. C., Budker, D., and Pines, A.

Subjects

*HETERONUCLEAR diatomic molecules, *SINGLET state (Quantum mechanics), *MAGNETIC fields, *FORMIC acid, *SPIN-orbit interactions

Abstract

We report an observation of long-lived spin-singlet states in a 13C-1 H spin pair in a zero magnetic field. In 13C-labeled formic acid, we observe spin-singlet lifetimes as long as 37 s, about a factor of 3 longer than the T1 lifetime of dipole polarization in the triplet state. In contrast to common high-field experiments, the observed coherence is a singlet-triplet coherence with a lifetime T2 longer than the T1 lifetime of dipole polarization in the triplet manifold. Moreover, we demonstrate that heteronuclear singlet states formed between a 1H and a 13C nucleus can exhibit longer lifetimes than the respective triplet states even in the presence of additional spins that couple to the spin pair of interest. Although long-lived homonuclear spin-singlet states have been extensively studied, this is the first experimental observation of analogous singlet states in heteronuclear spin pairs. [ABSTRACT FROM AUTHOR]

Published

2014

21. Superluminal light propagation in a three-level ladder system.

Author

Gładysz P, Pustelny S, and Słowik K

Abstract

Superluminal light propagation is typically accompanied by significant absorption that might prevent its observation in realistic samples. We propose an all-optical implementation exploiting the two-photon resonance in three-level media to overcome this problem. With several computational methods, we analyze three possible configurations of optically-dressed systems and identify an optimal configuration for superluminal propagation. Due to the far-detuned operating regime with low absorption, this scenario avoids the usual need for population inversion, gain assistance or nonlinear optical response. Our analysis covers a broad parameter space and aims for the identification of conditions where significant pulse advancement can be achieved at high transmission levels. In this context, a figure of merit is introduced accounting for a trade-off between the desired group-index values and transmission level. This quantity helps to identify the optimal characteristics of the dressing beam., (© 2024. The Author(s).)

Published

2024

22. Author Correction: Response of atomic spin-based sensors to magnetic and nonmagnetic perturbations.

Author

Padniuk M, Kopciuch M, Cipolletti R, Wickenbrock A, Budker D, and Pustelny S

Published

2023

23. Author Correction: Zero- to low-field relaxometry of chemical and biological fluids.

Author

Alcicek S, Put P, Kubrak A, Alcicek FC, Barskiy D, Gloeggler S, Dybas J, and Pustelny S

Published

2023

24. Zero- to low-field relaxometry of chemical and biological fluids.

Author

Alcicek S, Put P, Kubrak A, Alcicek FC, Barskiy D, Gloeggler S, Dybas J, and Pustelny S

Abstract

Nuclear magnetic resonance (NMR) relaxometry is an analytical method that provides information about molecular environments, even for NMR "silent" molecules (spin-0), by analyzing the properties of NMR signals versus the magnitude of the longitudinal field. Conventionally, this technique is performed at fields much higher than Earth's magnetic field, but our work focuses on NMR relaxometry at zero and ultra-low magnetic fields (ZULFs). Operating under such conditions allows us to investigate slow (bio)chemical processes occurring on a timescale from milliseconds to seconds, which coincide with spin evolution. ZULFs also minimize T 2 line broadening in heterogeneous samples resulting from magnetic susceptibility. Here, we use ZULF NMR relaxometry to analyze (bio)chemical compounds containing 1 H- 13 C, 1 H- 15 N, and 1 H- 31 P spin pairs. We also detected high-quality ULF NMR spectra of human whole-blood at 0.8 μT, despite a shortening of spin relaxation by blood proteomes (e.g., hemoglobin). Information on proton relaxation times of blood, a potential early biomarker of inflammation, can be acquired in under a minute using inexpensive, portable/small-size NMR spectrometers based on atomic magnetometers., (© 2023. Springer Nature Limited.)

Published

2023

25. Detection of pyridine derivatives by SABRE hyperpolarization at zero field.

Author

Put P, Alcicek S, Bondar O, Bodek Ł, Duckett S, and Pustelny S

Abstract

Nuclear magnetic resonance (NMR) spectroscopy is a powerful analytical tool used in modern science and technology. Its novel incarnation, based on measurements of NMR signals without external magnetic fields, provides direct access to intramolecular interactions based on heteronuclear scalar J-coupling. The uniqueness of these interactions makes each zero-field NMR spectrum distinct and useful in chemical fingerprinting. However, the necessity of heteronuclear coupling often results in weak signals due to the low abundance of certain nuclei (e.g., 15 N). Hyperpolarization of such compounds may solve the problem. In this work, we investigate molecules with natural isotopic abundance that are polarized using non-hydrogenative parahydrogen-induced polarization. We demonstrate that spectra of hyperpolarized naturally abundant pyridine derivatives can be observed and uniquely identified whether the same substituent is placed at a different position of the pyridine ring or different constituents are placed at the same position. To do so, we constructed an experimental system using a home-built nitrogen vapor condenser, which allows for consistent long-term measurements, crucial for identifying naturally abundant hyperpolarized molecules at a concentration level of ~1 mM. This opens avenues for future chemical detection of naturally abundant compounds using zero-field NMR., (© 2023. The Author(s).)

Published

2023

26. Response of atomic spin-based sensors to magnetic and nonmagnetic perturbations.

Author

Padniuk M, Kopciuch M, Cipolletti R, Wickenbrock A, Budker D, and Pustelny S

Abstract

Searches for pseudo-magnetic spin couplings require implementation of techniques capable of sensitive detection of such interactions. While Spin-Exchange Relaxation Free (SERF) magnetometry is one of the most powerful approaches enabling the searches, it suffers from a strong magnetic coupling, deteriorating the pseudo-magnetic coupling sensitivity. To address this problem, here, we compare, via numerical simulations, the performance of SERF magnetometer and noble-gas-alkali-metal co-magnetometer, operating in a so-called self-compensating regime. We demonstrate that the co-magnetometer allows reduction of the sensitivity to low-frequency magnetic fields without loss of the sensitivity to nonmagnetic couplings. Based on that we investigate the responses of both systems to the oscillating and transient spin perturbations. Our simulations reveal about five orders of magnitude stronger response to the neutron pseudo-magnetic coupling and about three orders of magnitude stronger response to the proton pseudo-magnetic coupling of the co-magnetometer than those of the SERF magnetometer. Different frequency responses of the co-magnetometer to magnetic and nonmagnetic perturbations enables differentiation between these two types of interactions. This outlines the ability to implement the co-magnetometer as an advanced sensor for the Global Network of Optical Magnetometer for Exotic Physics searches (GNOME), aiming at detection of ultra-light bosons (e.g., axion-like particles)., (© 2022. The Author(s).)

Published

2022

27. Zero-Field NMR of Urea: Spin-Topology Engineering by Chemical Exchange.

Author

Alcicek S, Put P, Barskiy D, Kontul V, and Pustelny S

Subjects

Deuterium Oxide chemistry, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Water chemistry, Urea chemistry

Abstract

Well-resolved and information-rich J -spectra are the foundation for chemical detection in zero-field NMR. However, even for relatively small molecules, spectra exhibit complexity, hindering the analysis. To address this problem, we investigate an example biomolecule with a complex J -coupling network─urea, a key metabolite in protein catabolism─and demonstrate ways of simplifying its zero-field spectra by modifying spin topology. This goal is achieved by controlling pH-dependent chemical exchange rates of 1 H nuclei and varying the composition of the D 2 O/H 2 O mixture used as a solvent. Specifically, we demonstrate that by increasing the proton exchange rate in the [ 13 C, 15 N 2 ]-urea solution, the spin system simplifies, manifesting through a single narrow spectral peak. Additionally, we show that the spectra of 1 H/D isotopologues of [ 15 N 2 ]-urea can be understood easily by analyzing isolated spin subsystems. This study paves the way for zero-field NMR detection of complex biomolecules, particularly in biofluids with a high concentration of water.

Published

2021

28. Zero- to Ultralow-Field NMR Spectroscopy of Small Biomolecules.

Author

Put P, Pustelny S, Budker D, Druga E, Sjolander TF, Pines A, and Barskiy DA

Subjects

Magnetic Resonance Spectroscopy, Magnetic Fields

Abstract

Nuclear magnetic resonance (NMR) spectroscopy is a well-established analytical technique used to study chemicals and their transformations. However, high-field NMR spectroscopy necessitates advanced infrastructure, and even cryogen-free benchtop NMR spectrometers cannot be readily assembled from commercially available components. We demonstrate construction of a portable zero-field NMR spectrometer employing a commercially available magnetometer and investigate its applications in analytical chemistry. In particular, J -spectra of small representative biomolecules [ 13 C]-formic acid, [1- 13 C]-glycine, [2,3- 13 C]-fumarate, and [1- 13 C]-d-glucose were acquired, and an approach relying on the presence of a transverse magnetic field during the detection was investigated for relaxometry purposes. We found that the water relaxation time strongly depends on the concentration of dissolved d-glucose in the range of 1-10 mM suggesting opportunities for indirect assessment of glucose concentration in aqueous solutions. Extending analytical capabilities of zero-field NMR to aqueous solutions of simple biomolecules (amino acids, sugars, and metabolites) and relaxation studies of aqueous solutions of glucose highlights the analytical potential of noninvasive and portable ZULF NMR sensors for applications outside of research laboratories.

Published

2021

29. Zero-Field NMR J -Spectroscopy of Organophosphorus Compounds.

Author

Alcicek S, Put P, Kontul V, and Pustelny S

Abstract

Organophosphorus compounds are a wide and diverse class of chemicals playing a crucial role in living organisms. This aspect has been often investigated using nuclear magnetic resonance (NMR), which provides information about molecular structure and function. In this paper, we report the results of theoretical and experimental studies on basic organophosphorus compounds using zero-field NMR, where spin dynamics are investigated in the absence of a magnetic field with the dominant heteronuclear J -coupling. We demonstrate that the zero-field NMR enables distinguishing the chemicals owing to their unique electronic environment even though their spin systems have the same alphabetic designation. Such information can be obtained just in a single measurement, while amplitudes and widths of observed low-field NMR resonances enable the study of processes affecting spin dynamics. An excellent agreement between simulations and measurements of the spectra, particularly in the largest frequency J -couplings range ever reported in zero-field NMR, is demonstrated.

Published

2021

30. Search for topological defect dark matter with a global network of optical magnetometers.

Author

Afach S, Buchler BC, Budker D, Dailey C, Derevianko A, Dumont V, Figueroa NL, Gerhardt I, Grujić ZD, Guo H, Hao C, Hamilton PS, Hedges M, Jackson Kimball DF, Kim D, Khamis S, Kornack T, Lebedev V, Lu ZT, Masia-Roig H, Monroy M, Padniuk M, Palm CA, Park SY, Paul KV, Penaflor A, Peng X, Pospelov M, Preston R, Pustelny S, Scholtes T, Segura PC, Semertzidis YK, Sheng D, Shin YC, Smiga JA, Stalnaker JE, Sulai I, Tandon D, Wang T, Weis A, Wickenbrock A, Wilson T, Wu T, Wurm D, Xiao W, Yang Y, Yu D, and Zhang J

Abstract

Ultralight bosons such as axion-like particles are viable candidates for dark matter. They can form stable, macroscopic field configurations in the form of topological defects that could concentrate the dark matter density into many distinct, compact spatial regions that are small compared with the Galaxy but much larger than the Earth. Here we report the results of the search for transient signals from the domain walls of axion-like particles by using the global network of optical magnetometers for exotic (GNOME) physics searches. We search the data, consisting of correlated measurements from optical atomic magnetometers located in laboratories all over the world, for patterns of signals propagating through the network consistent with domain walls. The analysis of these data from a continuous month-long operation of GNOME finds no statistically significant signals, thus placing experimental constraints on such dark matter scenarios., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2021.)

Published

2021

31. Different sensitivities of two optical magnetometers realized in the same experimental arrangement.

Author

Put P, Popiołek K, and Pustelny S

Abstract

In this article, operation of optical magnetometers detecting static (DC) and oscillating (AC) magnetic fields is studied and comparison of the devices is performed. To facilitate the comparison, the analysis is carried out in the same experimental setup, exploiting nonlinear magneto-optical rotation. In such a system, a control over static-field magnitude or oscillating-field frequency provides detection of strength of the DC or AC fields. Polarization rotation is investigated for various light intensities and AC-field amplitudes, which allows to determine optimum sensitivity to both fields. With the results, we demonstrate that under optimal conditions the AC magnetometer is about ten times more sensitive than its DC counterpart, which originates from different response of the atoms to the fields. Bandwidth of the magnetometers is also analyzed, revealing its different dependence on the light power. Particularly, we demonstrate that bandwidth of the AC magnetometer can be significantly increased without strong deterioration of the magnetometer sensitivity. This behavior, combined with the ability to tune the resonance frequency of the AC magnetometer, provide means for ultra-sensitive measurements of the AC field in a broad but spectrally-limited range, where detrimental role of static-field instability is significantly reduced.

Published

2019

32. Invited Review Article: Instrumentation for nuclear magnetic resonance in zero and ultralow magnetic field.

Author

Tayler MCD, Theis T, Sjolander TF, Blanchard JW, Kentner A, Pustelny S, Pines A, and Budker D

Abstract

We review experimental techniques in our laboratory for nuclear magnetic resonance (NMR) in zero and ultralow magnetic field (below 0.1 μT) where detection is based on a low-cost, non-cryogenic, spin-exchange relaxation free 87 Rb atomic magnetometer. The typical sensitivity is 20-30 fT/Hz 1/2 for signal frequencies below 1 kHz and NMR linewidths range from Hz all the way down to tens of mHz. These features enable precision measurements of chemically informative nuclear spin-spin couplings as well as nuclear spin precession in ultralow magnetic fields.

Published

2017

33. Adsorption of cationic organic dyes in suspended-core fibers.

Author

Wajnchold B, Grabka M, Umińska A, Ryguła A, Kotas D, Gołuński M, Pustelny S, and Gawlik W

Abstract

We report on the absorption measurements of the liquid-filled pure-silica microstructured optical fibers. The measurements concentrate on spectroscopic analysis of the water solutions of a cationic dye, oxazine 725 perchlorate which, when filling the fiber, demonstrates much stronger absorption signals than observed in bulk with regular cuvettes. The effect is also seen in another cationic dye, but not in anionic dyes. Our investigations reveal that the effect originates from the adsorption of the dye molecules on the fiber inner walls. This effect also significantly enhances the sensitivity of spectroscopic measurements enabling the detection of molecules at very low concentrations. In particular, the detection of a 1 nM concentration of oxazine 725 perchlorate was demonstrated.

Published

2015

34. Application of continuous wavelet transform for determination of fiber birefringence.

Author

Grabka M, Pustelny S, Mergo P, and Gawlik W

Subjects

Birefringence, Computer Simulation, Models, Theoretical, Optical Fibers, Refractometry methods, Wavelet Analysis

Abstract

Measurements of the group-birefringence dispersion of a microstructured optical fiber using the wavelength-scanning technique are reported. Resulting interferograms are processed using the continuous wavelet transform. We discuss application of this approach for determination of birefringence of few-mode fibers and show that with careful analysis it is possible to determine birefringence dispersion of the higher-order modes in optical fibers.

Published

2012