%0 Journal Article %J Magnetic Resonance Imaging %D 2007 %T Dispersion measurements using time-of-flight remote detection MRI %A Granwehr, J. %A Harel, E. %A Hilty, C. %A Garcia, S. %A Chavez, L. %A Pines, A. %A Sen, P. N. %A Song, Y. Q. %K flow %X

Remote detection nuclear magnetic resonance and magnetic resonance imaging can be used to study fluid flow and dispersion in a porous medium from a purely Eulerian point of view (i.e., in a laboratory frame of reference). Information about fluid displacement is obtained on a macroscopic scale in a long-time regime, while local velocity distributions are averaged out. It is shown how these experiments can be described using the common flow propagator formalism and how experimental data can be analyzed to obtain effective porosity, flow velocity inside the porous medium, fluid dispersion and flow tracing of fluid. (C) 2007 Elsevier Inc. All rights reserved.

%B Magnetic Resonance Imaging %V 25 %P 449-452 %8 May %@ 0730-725X %G English %U ://WOS:000246425100004 %N 4 %M WOS:000246425100004 %! Dispersion measurements using time-of-flight remote detection MRI %R Doi 10.1016/J.Mri.2006.11.011 %0 Journal Article %J Journal of Magnetic Resonance %D 2006 %T Auxiliary probe design adaptable to existing probes for remote detection NMR, MRI, and time-of-flight tracing %A Han, S. I. %A Granwehr, J. %A Garcia, S. %A McDonnell, E. E. %A Pines, A. %K flow %X

A versatile, detection-only probe design is presented that can be adapted to any existing NMR or MRI probe with the purpose of making the remote detection concept generally applicable. Remote detection suggests freeing the NMR experiment from the confinement of using the same radio frequency (RF) coil and magnetic field for both information encoding and signal detection. Information is stored during the encoding step onto a fluid sensor medium whose magnetization is later measured in a different location. The choice of an RF probe and magnetic field for encoding can be made based solely on the size and characteristics of the sample and the desired information quality without considering detection sensitivity, as this aspect is dealt with by a separate detector. While early experiments required building probes that included two resonant circuits, one for encoding and one for detection, a modular approach with a detection-only probe as presented here can be used along with any existing NMR probe of choice for encoding. The design of two different detection-only probes is presented, one with a saddle coil for milliliter-sized detection volumes, and the other one with a microsolenoid coil for sub-microliter fluid quantities. As example applications, we present time-of-flight (TOF) tracing of hyperpolarized Xe-129 spins in a gas mixture through coiled tubing using the microsolenoid coil detector and TOF flow imaging through a nested glass container where the gas flow changes its direction twice between inlet and outlet using the saddle coil detector. (c) 2006 Elsevier Inc. All rights reserved.

%B Journal of Magnetic Resonance %V 182 %P 260-272 %8 Oct %@ 1090-7807 %G English %U ://WOS:000241203900010 %N 2 %M WOS:000241203900010 %! Auxiliary probe design adaptable to existing probes for remote detection NMR, MRI, and time-of-flight tracing %R Doi 10.1016/J.Jmr.2006.06.024 %0 Journal Article %J Nature Materials %D 2006 %T Multiphase imaging of gas flow in a nanoporous material using remote-detection NMR %A Harel, E. %A Granwehr, J. %A Seeley, J. A. %A Pines, A. %K visualization %X

Pore structure and connectivity determine how microstructured materials perform in applications such as catalysis, fluid storage and transport, filtering or as reactors. We report a model study on silica aerogel using a time-of-flight magnetic resonance imaging technique to characterize the flow field and explain the effects of heterogeneities in the pore structure on gas flow and dispersion with Xe-129 as the gas-phase sensor. The observed chemical shift allows the separate visualization of unrestricted xenon and xenon confined in the pores of the aerogel. The asymmetrical nature of the dispersion pattern alludes to the existence of a stationary and a flow regime in the aerogel. An exchange time constant is determined to characterize the gas transfer between them. As a general methodology, this technique provides insights into the dynamics of flow in porous media where several phases or chemical species may be present.

%B Nature Materials %V 5 %P 321-327 %8 Apr %@ 1476-1122 %G English %U ://WOS:000236530400024 %N 4 %M WOS:000236530400024 %! Multiphase imaging of gas flow in a nanoporous material using remote-detection NMR %R Doi 10.1038/Nmat1598 %0 Journal Article %J Proceedings of the National Academy of Sciences of the United States of America %D 2005 %T Microfluidic gas-flow profiling using remote-detection NMR %A Hilty, C. %A McDonnell, E. E. %A Granwehr, J. %A Pierce, K. L. %A Han, S. I. %A Pines, A. %K mri %X

We have used nuclear magnetic resonance (NMR) to obtain spatially and temporally resolved profiles of gas flow in microfluidic devices. Remote detection of the NMR signal both overcomes the sensitivity limitation of NMR and enables time-of-flight measurement in addition to spatially resolved imaging. Thus, detailed insight is gained into the effects of flow, diffusion, and mixing in specific geometries. The ability for noninvasive measurement of microfluidic flow, without the introduction of foreign tracer particles, is unique to this approach and is important for the design and operation of microfluidic devices. Although here we demonstrate an application to gas flow, extension to liquids, which have higher density, is implicit.

%B Proceedings of the National Academy of Sciences of the United States of America %V 102 %P 14960-14963 %8 Oct 18 %@ 0027-8424 %G English %U ://WOS:000232811800006 %N 42 %M WOS:000232811800006 %! Microfluidic gas-flow profiling using remote-detection NMR %R Doi 10.1073/Pnas.0507566102 %0 Journal Article %J Journal of Magnetic Resonance %D 2005 %T NMR detection using laser-polarized xenon as a dipolar sensor %A Granwehr, J. %A Urban, J. T. %A Trabesinger, A. H. %A Pines, A. %K dynamics %X

Hyperpolarized Xe-129 can be used as a sensor to indirectly detect NMR spectra of heteronuclei that are neither covalently bound nor necessarily in direct contact with the Xe atoms, but coupled through long-range intermolecular dipole-dipole interactions. To reintroduce long-range dipolar couplings the sample symmetry has to be broken. This can be done either by using an asymmetric sample arrangement, or by breaking the symmetry of the spin magnetization with field gradient pulses. Experiments are performed where only a small fraction of the available Xe-129 magnetization is used for each point, so that a single batch of xenon suffices for the point-by-point acquisition of a heteronuclear NMR spectrum. Examples with H-1 as the analyte nucleus show that these methods have the potential to obtain spectra with a resolution that is high enough to determine homonuclear J couplings. The applicability of this technique with remote detection is discussed. Published by Elsevier Inc.

%B Journal of Magnetic Resonance %V 176 %P 125-139 %8 Oct %@ 1090-7807 %G English %U ://WOS:000232425800001 %N 2 %M WOS:000232425800001 %! NMR detection using laser-polarized xenon as a dipolar sensor %R Doi 10.1016/J.Jmr.2005.05.013 %0 Journal Article %J Physical Review Letters %D 2005 %T Time-of-flight flow imaging using NMR remote detection %A Granwehr, J. %A Harel, E. %A Han, S. %A Garcia, S. %A Pines, A. %A Sen, P. N. %A Song, Y. Q. %K mri %X

A time-of-flight imaging technique is introduced to visualize fluid flow and dispersion through porous media using NMR. As the fluid flows through a sample, the nuclear spin magnetization is modulated by rf pulses and magnetic field gradients to encode the spatial coordinates of the fluid. When the fluid leaves the sample, its magnetization is recorded by a second rf coil. This scheme not only facilitates a time-dependent imaging of fluid flow, it also allows a separate optimization of encoding and detection subsystems to enhance overall sensitivity. The technique is demonstrated by imaging gas flow through a porous rock.

%B Physical Review Letters %V 95 %8 Aug 12 %@ 0031-9007 %G English %U ://WOS:000231247300028 %N 7 %M WOS:000231247300028 %! Time-of-flight flow imaging using NMR remote detection %R Doi 10.1103/Physrevlett.95.075503 %0 Journal Article %J Physical Review Letters %D 2004 %T Hyperpolarized xenon nuclear spins detected by optical atomic magnetometry %A Yashchuk, V. V. %A Granwehr, J. %A Kimball, D. F. %A Rochester, S. M. %A Trabesinger, A. H. %A Urban, J. T. %A Budker, D. %A Pines, A. %K mri %X

We report the use of an atomic magnetometer based on nonlinear magneto-optical rotation with frequency-modulated light to detect nuclear magnetization of xenon gas. The magnetization of a spin-exchange-polarized xenon sample (1.7 cm(3) at a pressure of 5 bars, natural isotopic abundance, polarization 1%), prepared remotely to the detection apparatus, is measured with an atomic sensor. An average magnetic field of similar to10 nG induced by the xenon sample on the 10 cm diameter atomic sensor is detected with signal-to-noise ratio similar to10, limited by residual noise in the magnetic environment. The possibility of using modern atomic magnetometers as detectors of nuclear magnetic resonance and in magnetic resonance imaging is discussed. Atomic magnetometers appear to be ideally suited for emerging low-field and remote-detection magnetic resonance applications.

%B Physical Review Letters %V 93 %8 Oct 15 %@ 0031-9007 %G English %U ://WOS:000224533300012 %N 16 %M WOS:000224533300012 %! Hyperpolarized xenon nuclear spins detected by optical atomic magnetometry %R Doi 10.1103/Physrevlett.93.160801