ARTICLE

Received 6 Dec 2013 | Accepted 17 Apr 2014 | Published 20 May 2014

Ricardo Jimnez-Martnez1,2, Daniel J. Kennedy3,4, Michael Rosenbluh5, Elizabeth A. Donley1,

Svenja Knappe1, Scott J. Seltzer3,4, Hattie L. Ring3,4, Vikram S. Bajaj3,4 & John Kitching1

Optically hyperpolarized 129Xe gas has become a powerful contrast agent in nuclear magnetic resonance (NMR) spectroscopy and imaging, with applications ranging from studies of the human lung to the targeted detection of biomolecules. Equally attractive is its potential use to enhance the sensitivity of microuidic NMR experiments, in which small sample volumes yield poor sensitivity. Unfortunately, most 129Xe polarization systems are large and non-portable. Here we present a microfabricated chip that optically polarizes 129Xe gas. We

have achieved 129Xe polarizations 40.5% at ow rates of several microlitres per second, compatible with typical microuidic applications. We employ in situ optical magnetometry to sensitively detect and characterize the 129Xe polarization at magnetic elds of 1 mT. We construct the device using standard microfabrication techniques, which will facilitate its integration with existing microuidic platforms. This device may enable the implementation of highly sensitive 129Xe NMR in compact, low-cost, portable devices.

DOI: 10.1038/ncomms4908

Optical hyperpolarization and NMR detection of 129Xe on a microuidic chip

1 National Institute of Standards and Technology, 325 Broadway, Boulder, Colorado 80305, USA. 2 Department of Physics, University of Colorado at Boulder, Boulder, Colorado 80309, USA. 3 Materials Science Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720-7300, USA. 4 Department of Chemistry, University of California at Berkeley, Berkeley, California 94720, USA. 5 The Jack and Pearl Resnick Institute for Advanced Technology, Department of Physics, Bar-Ilan University, Ramat-Gan IL-52900, Israel. Correspondence and requests for materials should be addressed to V.S.B. (email: mailto:[email protected]

Web End [email protected] mailto:[email protected]

Web End =) or to J.K. (email:mailto:[email protected]

Web End [email protected] ).

NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 1

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4908

Owing to the ease with which it may be placed in a non-equilibrium spin polarization state, 129Xe gas has found extensive use in recent nuclear magnetic resonance (NMR) spectroscopy and magnetic reso

nance imaging (MRI) experiments, greatly enhancing the resultant NMR signal1. Furthermore, 129Xe is extremely sensitive to its physiochemical environment, making it a valuable probe on length scales ranging from nanometres to metres2. It has enabled new applications ranging from the targeted detection of biomolecules3,4 to perfusion imaging of the human lung5. However, the large-scale and non-portable nature of 129Xe hyperpolarization hardware precludes its integration into microuidic platforms, such as have found utility in the miniaturization of numerous analytical techniques6. Most 129Xe optical polarizers have been designed to produce litre-sized volumes of polarized gas7,8. These systems, designed for clinical magnetic resonance imaging or the large-scale imaging of materials, are necessarily bulky, expensive and non-portable.

Here, we present the fabrication and operation of a micro-fabricated source of hyperpolarized 129Xe, suitable for the low-cost, power-efcient production of polarized gases and integration with microuidic systems6,9,10. Our device uses an effective pumping volume of 25 ml and 8 mW of pumping light to achieve

129Xe polarizations 40.5% at gas ow rates of 5 ml s 1, in the absence of any superconducting magnet. This represents a signal enhancement of B200 over the room temperature thermal equilibrium polarizations achievable at the highest commercially available magnetic eld of 23.5 T. Our device requires only standard microfabrication techniques11, beneting from some of the known strengths of this technology12, and employs

concurrent high-sensitivity optical magnetometry13 to detect the

129Xe NMR signal. Our results are relevant in light of recent innovations in NMR14, which include sensitivity enhancement through the use of optically hyperpolarized 129Xe gas2 and optical magnetometry15, and the development of microuidic NMR methods16. Our device combines all of these technologies in a single chip and may enable the implementation of fully integrated

129Xe NMR instrumentation in low-cost, portable and sensitive lab-on-a-chip devices.

ResultsMicrofabricated source of hyperpolarized 129Xe. The chip, fabricated from silicon and glass, consists of four chambers 1 mm thick and several millimetres wide connected by micro-channels, as shown in Fig. 1a. A fraction of the 129Xe atoms in the pump chamber (see Fig. 1a) becomes polarized through spin exchange collisions with optically pumped 87Rb atoms at a pumping rate proportional to the 87Rb polarization, PRb, and the spin-exchange rate, Rse nRbgse ,with nRb being the alkali atomic number den

sity and gse the 87Rb-129Xe spin-exchange rate coefcient17. Under gas ow, polarized 129Xe atoms exit the pump chamber and move through the connecting channel into the probe chamber. Except where stated otherwise, both larger 87Rb atomic density and stronger laser illumination in the pump chamber ensure that the pumping rate of 129Xe in the pump chamber is much larger than that in the probe chamber.

Optical detection of polarized 129Xe. Using the ensemble of

87Rb atoms in the pump and probe chambers as

a

Probe light

Probe chamber

Xe out

Xe in

z x y

Pump light

Pump chamber

b c

87Rb

Bz

129Xe

129Xe

Bz

129Xe Bx

[afii9843]/2 rotation

Pumping

Precession

Figure 1 | The microuidic chip 129Xe polarizer. (a) A gas mixture containing 400 Torr N2 and 200 Torr Xe in natural isotopic abundance (26.4% 129Xe content) ows from a bulk gas manifold into the inlet chamber, through the pump and probe chambers, and out of the outlet chamber. The chipis loaded with 2 mg of 87Rb metal (see Methods). Unpolarized 129Xe atoms entering the pump chamber become polarized through spin exchange with optically pumped 87Rb. The 129Xe then moves downstream, passes through a microchannel into the probe chamber and eventually exits the device through the output chamber. Optical characterization of the 129Xe polarization in the pump and probe chambers is carried out using the ensemble of 87Rb atoms in each chamber as in situ magnetometers. (b) The silicon chip footprint is 3 cm 1 cm, with a thickness of 1 mm. The dimensions of the pump and

probe chambers are 5 mm 5 mm 1 mm and 3 mm 3 mm 1 mm, respectively, whereas the channel connecting the pump and probe chambers is

1 mm 0.3 mm 0.3 mm. Two tall, narrow grooves are etched from the middle of the chip to provide thermal isolation between the two sides of the

device. (c) Pumping and probing sequence for 129Xe. Pumping is carried out continually in the pump chamber in the presence of a longitudinaleld of Bz 0.8 mT. Every 1020 s, a transverse DC eld of magnitude 5.3 mT is switched on for 4 ms to tip the 129Xe atoms onto the x-y plane and initiate

the 129Xe precession about the longitudinal axis.

2 NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4908 ARTICLE

magnetometers13,18,19 sensitive to magnetic elds along the y-axis as dened in Fig. 1a, we detected the 129Xe magnetization, and thus its polarization20, in each chamber as a function of the experimental conditions. The magnitude of the eld BRb sensed by 87Rb due to 129Xe magnetization MXe is approximately20

BRb

2

3 m0k0MXe 1

where m0 is the vacuum permeability, MXe mXePXenXe with mXe,

PXe and nXe being the 129Xe nuclear magnetic moment, polarization and atomic density, respectively. Here, k0 represents the enhancement factor due to the Fermi-contact interaction between the valence electron of 87Rb and the 129Xe nuclear spin13,1821, previously measured to be k0E500 (ref. 22). Measurement of the

129Xe free-induction decay (FID) in each chamber is made with the magnetometers after rotating the 129Xe longitudinal polarization along the z-axis into the transverse x-y plane with a transverse DC magnetic eld pulse, as shown in Fig. 1c.

Figure 2 demonstrates the efcient transport of polarized 129Xe from the pump chamber to the probe chamber while the gas is owing. Figure 2a shows the measured FID in the pump chamber, obtained by monitoring the transmitted power in the pump beam after the transverse eld pulse. Figure 2b shows the measured FID in the probe chamber recorded with the pump beam blocked, so

that there is no ow of polarized 129Xe into the probe chamber. Under these conditions we observe a weak probe FID with amplitude of 1 nT, which we attribute to weak spin-exchange optical pumping (SEOP) of 129Xe by the polarized 87Rb in the probe chamber. Figure 2c shows that the probe FID changes signicantly when the pump beam is unblocked; its amplitude increases and its phase changes by 180 to correspond to the amplitude and phase in the pump chamber observed in Fig. 2a. This indicates that the detected 129Xe was polarized in the pump chamber and transported to the probe chamber by the ow of gas.

Characterization of 129Xe polarization. Next, we characterized the 129Xe polarization in the pump and probe chambers as a function of total gas ow rate, alkali atomic density and pumping power. Figure 3a shows the amplitude of the FIDs and the corresponding 129Xe polarization in the pump and probe chambers, which is estimated using k0 500 (ref. 22) in equation (1), as a

function of total gas ow rate. We observe that the polarization in the pump chamber decreases with ow, while in the probe chamber it builds up, peaks at a ow rate at which the inux of polarized 129Xe is comparable with its spin-relaxation rate, and then follows the pump polarization.

The dependence of the 129Xe polarization in the pump chamber on the alkali atomic density, without gas ow, is shown in Fig. 3b. In our device, relaxation due to 129Xe collisions with the glass walls is much faster than relaxation from spin-exchange collisions. Thus, equation (2.1) (see Methods) predicts a linear relationship between 129Xe polarization and the 87Rb-129Xe spin-exchange rate, which is proportional to the 87Rb atomic density. This relationship, and a constant 87Rb polarization, can explain the linear behavior of the 129Xe polarization for low alkali atomic densities. At higher alkali densities the ensemble becomes optically thick and, given a nite amount of pumping power, the alkali polarization decreases. As a result the 129Xe polarization no longer increases linearly with alkali density. This limitation can be observed in Fig. 3c, which shows the 129Xe polarization in the pump chamber as a function of pumping power for low and high values of the optical depth OD0. At low optical thickness the

129Xe polarization saturates, whereas for the larger optical depth it remains unsaturated at the highest applied optical powers. These results suggest that larger 129Xe polarizations can be achieved by increasing both the 87Rb density and pumping rate.

DiscussionThe current polarizations achieved in our device are much lower than the near unity polarizations achieved in some large-scale polarizers8,23. However, as can be extrapolated from Fig. 3b and Fig. 3c, larger polarizations are in principle achievable in our device. We note that the 129Xe relaxation of 1.6 s (see Supplementary Fig. 1 and Supplementary Note 1) observed in our system is 3 to 10 times faster than previously measured in sealed microfabricated cells with 1 mm3 volume24,25. In this previous work, 129Xe polarizations on the order of 5% were achieved using similar 87Rb densities and slightly larger light intensities than those used in our device. These observations suggest room for improvement in future designs and motivate further study of the limitations of SEOP in microfabricated connement volumes (see Supplementary Note 2). The combination of higher 87Rb density, greater optical pumping power and improved relaxation times may allow for 129Xe polarizations 45%. The current experiment is designed to produce a large magnetization signal at the expense of polarization through the use of a high 129Xe partial pressure; the use of lower partial pressures is expected to trade off magnetization signal for increased polarization. An important

a

10

5

Amplitude (nT)

0

5

10

b

10

Amplitude (nT)

5

0

5

10

c

10

Amplitude (nT)

5

0

5

10

0 0.5 1 1.5 2 2.5 3 3.5

Time (s)

Figure 2 | Transport of polarized 129Xe. (a) Free-induction decay (FID) of the transverse 129Xe polarization in the pump chamber at a total gas ow rate of 3 ml s 1. (b) FID of polarized 129Xe in the probe chamber with the pump light turned off. (c) FID of polarized 129Xe in the probe chamber with

the pump light turned on. Note that for this particular experiment the FID obtained in b is 180 degrees out of phase with that obtained in the pump chamber (a), due to the use of opposite-handed polarizing photons in the pump and probe chambers.

NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 3

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4908

gure of merit of a polarizers performance is its spin-transfer efciency1; for our device, the spin-transfer efciency is B0.0038, competitive with previous polarizers23, and only one order of magnitude smaller than the largest possible efciency (see Supplementary Note 3). Another gure of merit is the ratio of the polarized atom ow rate to the optical pumping power. We obtain 0.45 ml s 1 W 1 for our device, again comparable to this quantity in large-scale polarizers23 (see Supplementary Table 1).

In this work, we employ the 87Rb atoms as in situ detectors13,18,19 of the 129Xe magnetization and take advantage of the Fermi-contact interaction13,1821 to enhance the detection sensitivity to 129Xe by a factor of B500. This approach represents an important feature of our device that can be used to detect or monitor the 129Xe polarization with high sensitivity at low magnetic elds in cases where the polarized gas can be cleanly

extracted from the sample region. If the polarized gas cannot be extracted, as may occur if the gas has been dissolved in a liquid, for example, our device can be easily integrated with microfabricated magnetometers26 placed outside of the pump and probe chambers. Microfabricated magnetometers have demonstrated sensitivities of 5 fT/OHz over bandwidths of 100 Hz26, enough to detect the magnetic elds due to the currently produced 129Xe polarization, and have been used to detect low-eld NMR in microuidics27. This approach may be useful for applications that are not compatible with the presence of alkali atoms in the microuidic channels.

We note that conventional glassblowing could also be used to make a compact system capable of producing small quantities of hyperpolarized gas. Compared with the microfabricated silicon-based system we describe here, we expect such a system to be somewhat larger and to require a higher pumping power, but likely to produce larger quantities of more highly polarized gas, due to the weaker wall relaxation and larger pumping volume. While the microfabricated chip described here is not particularly complicated to fabricate, requiring only simple lithography, etching and bonding, a compact glass-blown system may be simpler to implement in a laboratory setting to carry out scientic experiments on microuidic systems. However, the microfabricated platform will likely be easier to integrate with other silicon-based microuidic systems due to the common platform material. Microfabrication is likely to be most advantageous in an industrial setting where large numbers of devices might be manufactured. The possibility for large-scale parallel fabrication of devices would likely lead to lower production costs and higher reliability compared with conventional glass-blown systems.

Our device, the rst to hyperpolarize 129Xe atoms in one chamber of a microfabricated device and optically interrogate them in another, will enable several new NMR applications without the need for immobile and expensive laboratory-scale instrumentation. We envision the development of portable high-density microuidic arrays of xenon biosensors for the analysis of complex mixtures4,16,28 in conned spaces such as micro-scale chemical reactors, or where access to hyperpolarized 129Xe produced by large-scale polarizers is impractical, such as in eld

a

24

0.84

21

0.74

18

0.64

FID amplitude (nT)

15

0.52

12

0.42

9

0.32

6

0.20

3

0.10

0 0 5 10 15 20 25 30

0

Total gas flow rate ( l s1)

P Xe(%)

P Xe(%)P Xe(%)

b

27

0.96

24

0.84

21

0.74

FID amplitude (nT)

18

0.64

15

0.52

12

0.42

Figure 3 | Device characterization. (a) 129Xe free-induction decay (FID) amplitude as a function of total gas ow rate in the pump chamber (blue circles), in the probe chamber with the pump light on (magenta squares), and with the pump light off (black squares). The solid line corresponds to a t of the data using equation (2.1) with RPuse as a free parameter and with

PPuRb0:36 and RPuwall1:6 s 1 (for details see Supplementary Note 1). From the obtained value for RPuse0:012 s 1and for a 87Rb atomic density of

6 1013 atoms cm 3 in the pump chamber, which is estimated from the

measured on-resonance optical depth (Methods), we estimate gse

1.7 10 16 cm3 s 1, in agreement with reported values for the spin-

exchange rate coefcient due to 87Rb-129Xe binary collisions17. The dashed line corresponds to the evaluation of equation (2.2) using the tted value for PPuXe and RPrwall1:6 s 1; this expression ignores 87Rb-129Xe spin

exchange and neglects the effects of diffusion, which can explain the discrepancy between the estimated line and the data at low ow rates. (b) Pump FID amplitude with no gas ow as a function of 87Rb atomic

density and (c) as a function of optical pumping power for nRb 6 1013 atoms cm 3 (blue circles) and nRb 1 1013 atoms cm 3 (black triangles).

In c the solid lines correspond to ts to the data using equation (1) and equation (2.1) with RPuse as a tting parameter and using RPuwall1:6 s 1. The

dependence of the Rb polarization was extracted from a t to the measured shift in the 129Xe Larmor frequency due to the 87Rb magnetization as a function of pumping power (Supplementary Note 1). Error bars are given by 3s uncertainty in the t for the FID amplitude.

9

0.32

6

0.20

3

0.10

0 0 1 2 3 4 5 6

0

87Rb density (1013 atoms cm3)

c

27

0.96

24

0.84

21

0.74

FID amplitude (nT)

18

0.64

15

0.52

12

0.42

9

0.32

6

0.20

3

0.10

0 0 1 2 3 4 5 6 7 8 9

Pumping power (mW)

0

4 NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4908 ARTICLE

applications. In such applications, our device would produce hyperpolarized 129Xe for dissolution into a liquid through use of a microuidic gas-liquid mixer29. The NMR-encoded 129Xe might be removed from the liquid through a microuidic analogue of a superhydrophobic thin lm30 and then detected in situ with our integrated magnetometer, enabling extremely high chemical sensitivity, or detected ex situ with a physically separate chip-scale atomic magnetometer. Additional experiments suggested for large-scale 129Xe polarizers14 might also benet from implementation on our portable, inexpensive device.

Methods

Microuidic chip fabrication. The device consists of a 3 cm 1 cm 1 mm sili

con chip. Deep reactive-ion etching (DRIE) is used to etch four holes of 1 mm depth to form the input, pump, probe and output chambers, as well as the channels connecting the input and output chambers to the pump and probe chambers, respectively. The channel connecting the pump and probe chamber is etched in a subsequent DRIE step. The device is sealed by anodically bonding two slides of borosilicate glass onto the top and bottom surfaces of the silicon chip. The lateral dimensions of the pump and probe chambers are 5 mm 5 mm and 3 mm

3 mm, respectively; they are connected by a 1 mm long 300 mm wide 300 mm

deep channel. Before being bonded to the chip, one of the glass slides is drilled with holes situated in line with the input and output chambers, through which gas enters and exits the cell. Two 1/800 VCR glands are glued onto the glass slide above the holes to allow connection of the cell to a gas manifold. The chip is lled with isotopically enriched 87Rb vapour, produced by the chemical reaction of barium azide and 87Rb chloride31 within the input and output chambers as described in Supplementary Note 4.

Experimental setup. The chip is placed inside a two-layer magnetic shield and attached to a gas manifold as shown in Supplementary Fig. 2. Fine control of the gas ow rate through the chip is achieved by a leak valve placed downstream from the chip. Two independently controlled laser beams, tuned to the D1 optical transition of 87Rb at 794.7 nm, irradiate the pump and probe chambers. A distributed feedback laser provides the pump laser beam, whereas light produced by a vertical-cavity surface-emitting laser is used as the probe laser beam. For most of the experiments, the optical power of the pump laser beam was 8 mW, while that in the probe was 100 mW. A set of Helmholtz coils is used to provide transverse magnetic elds in the x and y directions, and a solenoid is used to provide a longitudinal magnetic eld in the z-direction. The pump and probe chambers are AC heated using two independent sets of surface mount resistors attached to the cell. The temperature at the input and output chamber is measured using two thermistors that are in close contact with the windows of those chambers. The device operates over a range of temperatures from 120 to 150 C. The 87Rb atomic density in each chamber is characterized by measuring the optical absorption of the laser beams as their wavelengths are scanned across the D1 optical line of 87Rb. From the measured on-resonance optical depth OD0, we calculate the atomic density using OD0 s0nRbl with l 1 mm being the length of the beam path inside

the pump chamber and s0 2recf/Du being the on-resonance optical cross section

where re 2.8 10 13 cm is the classical electron radius, c is the speed of light in

vacuum, f 1=3 is the oscillator strength of the D1 resonance and Du 8 GHz is

the full-width at half-maximum of the optical line obtained from the tted optical absorption spectrum.

Model for the 129Xe polarization. The measurements of the 129Xe polarization in the pump PPuXe and probe PPrXe chambers can be interpreted in light of a modelof the form

PPuXe

RPuse

p , respectively, with a bandwidth of 40 Hz that is limited by the response of the lock-in ampliers. This corresponds to a single-shot detection limit of a polarized ensemble of B5 1011

129Xe atoms in each chamber. On resonance, the magnetometers respond linearly to magnetic elds along the y axis that are smaller than the resonance line-width (DvHWHM 1 mT at zero-light levels dominated by collisions with Xe atoms, and

twice or larger with optical pumping). For each change in the device parameters, the linear response of the magnetometers was obtained by extracting the on-resonance slope of the magnetic response acquired by scanning the magnetic eld along the y axis. We then used this slope to calibrate the amplitude of the FIDs in magnetic eld units. We t the FID signal in the pump chamber to a single exponentially decaying sinusoid, from which we extracted the amplitude, decay time constant and Larmor precession frequency of 129Xe. We obtained estimates for the FID amplitude in the probe chamber by measuring the amplitude of the rst peak and valley in the probe FID signal. Because transverse polarization is transferred from pump to probe chambers as the FID signals are being taken, nonexponential decay of the probe FID can occur, preventing the simple analysis of the data with a single time constant.

Hz

References

1. Walker, T. G. & Happer, W. Spin-exchange optical pumping of noble-gas nuclei. Rev. Mod. Phys. 69, 629642 (1997).

2. Goodson, B. M. Nuclear magnetic resonance of laser-polarized noblegases in molecules, materials, and organisms. J. Magn. Reson. 155, 157216 (2002).

3. Schrder, L., Lowery, T. J., Hilty, C., Wemmer, D. E. & Pines, A. Molecular imaging using a targeted magnetic resonance hyperpolarized biosensor. Science 314, 446449 (2006).

4. Schrder, L. Xenon for NMR biosensing- inert but alert. Phys. Med. 29, 316 (2013).

5. Mugler, J. & Altes, T. Hyperpolarized Xe MRI of the human lung. J. Magn. Reson. Imaging 37, 313331 (2013).

6. Whitesides, G. The origins and the future of microuidics. Nature 442, 368373 (2006).

7. Driehuys, B. et al. High volume production of laser polarized 129Xe. Appl. Phys. Lett. 69, 16681670 (1996).

8. Ruset, I. C., Ketel, S. & Hersman, F. W. Optical pumping system design for large production of hyperpolarized 129Xe. Phys. Rev. Lett. 96, 053002 (2006).

9. Dittrich, P. S. & Manz, A. Lab-on-a-chip: microuidics in drug discovery. Nat. Rev. Drug Discov. 5, 210218 (2006).

10. Yager, P. et al. Microuidic diagnostic technologies for global public health. Nature 442, 412418 (2006).

11. Knappe, S. et al. Microfabricated atomic clocks and magnetometers. J. Opt. A, Pure Appl. Opt. 8, S318S322 (2006).

12. Madou, M. J. Fundamentals of Microfabrication: The Science of Miniaturization

2nd edn (CRC Press, 2002).

13. Savukov, I. M. & Romalis, M. V. NMR detection with an atomic magnetometer. Phys. Rev. Lett. 94, 123001 (2005).

14. Harel, E., Schrder, L. & Xu, S. Novel detection schemes of nuclear magnetic resonance and magnetic resonance imaging: applications from analytical chemistry to molecular sensors. Ann. Rev. Anal. Chem. 1, 133163 (2008).

15. Ledbetter, M. P., Savukov, I., Seltzer, S. J. & Budker, D. Detection of nuclear magnetic resonance with atomic magnetometers. in Optical Magnetometry (eds Budker, D. & Kimball, J.) Chapter 14 (Cambridge University Press, 2013).

16. Bajaj, V. S., Paulsen, J., Harel, E. & Pines, A. Zooming in on microscopic ow by remotely detected MRI. Science 330, 10781081 (2010).

17. Jau, Y.-Y., Kizma, N. N. & Happer, W. Measurement of 129Xe-Cs binary spin-exchange rate coefcient. Phys. Rev. A 69, 061401 (2004).

18. Grover, B. C. Noble-gas NMR detection through noble-gas-rubidium hyperne contact interaction. Phys. Rev. Lett. 40, 391392 (1978).

19. Volk, C. H., Kwon, T. M. & Mark, J. G. Measurement of the 87Rb-129Xe spin-exchange cross section. Phys.Rev. A 21, 15491555 (1980).

20. Schaefer, S. R. et al. Frequency shifts of the magnetic-resonance spectrum of mixtures of nuclear spin-polarized noble gases and vapors of spin-polarized alkali-metal atoms. Phys. Rev. A 39, 56135623 (1989).

21. Herman, R. M. Theory of spin exchange between optically pumped rubidium and foreign gas nuclei. Phys. Rev. 137, A1062A1065 (1965).

22. Ma, Z. L., Sorte, E. G. & Saam, B. Collisional He and Xe frequency shifts in Rb-noble-gas mixtures. Phys. Rev. Lett. 106, 193005 (2011).

RPu

se

RPuwall RPuflow

PPuRb 2:1

RPrflow

RPr

se

PPuXe 2:2

where the superscripts Pu and Pr indicate the pump and probe chambers, respectively, Rwall is the 129Xe spin-destruction rate due to collisions with the chamber walls and Row is the inverse of the 129Xe transit time through the chamber. These equations are useful for understanding some characteristics of our device and guide future designs. We note, though, that they neglect diffusion, which limits the estimates of equation (2.2) at low ow rates. For example, Fig. 3a demonstrates that, when no gas is owing, the polarization in the probe chamber is larger when the pump laser is on than when it is off. We have performed experiments, which are described in Supplementary Note 5, indicating that this is due to the transport of polarized 129Xe through diffusion (see Supplementary Figs 35). Diffusion is expected to be a uniquely important process for polarization transport in microuidic systems such as those described here, for which the diffusion length is considerably larger than the characteristic size of the chip.

Atomic magnetometer response and FID estimates. The optically pumped 87Rb magnetometers utilized here are very similar to those discussed in refs 18 and 19. The magnetometers are implemented by introducing a radio-frequency eld with 7 kHz modulation frequency and 1 mT amplitude along the y-axis. The signals of the magnetometers are extracted by lock-in detection of the transmitted laser intensity at the modulation frequency. The measured noise oors for the pump and probe magnetometers were 5 pT=

Hz

p and 16 pT=

PPrXe

RPrwall RPrflow

NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 5

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4908

23. Nikolau, P. et al. Near-unity nuclear polarization with an open-source 129Xe hyperpolarizer for NMR and MRI. Proc. Natl Acad. Sci. USA 110, 1415014155 (2013).

24. Donley, E. A. et al. Nuclear quadrupole resonances in compact vapor cells: the crossover between the NMR and the nuclear quadrupole resonance interaction regimes. Phys. Rev. A 79, 013420 (2009).

25. Donley, E. et al. Microfabricated nuclear magnetic resonance gyroscopes: experimental results from three different instruments with varying levels of miniaturization. Proceedings of the 2009 GOMACTech Conference (2009).

26. Grifth, W. C., Knappe, S. & Kitching, J. Femtotesla atomic magnetometry in a microfabricated vapor cell. Opt. Express 18, 2716727172 (2010).

27. Ledbetter, M.P. et al. Zero-eld remote detection of NMR with a microfabricated atomic magnetometer. Proc. Natl Acad. Sci. USA 105, 22862290 (2008).

28. Moule, A. J. et al. Amplication of xenon NMR and MRI by remote detection. Proc. Natl Acad. Sci. USA 100, 91229127 (2003).

29. de Jong, J., Geerken, M. J., Lammertink, R. G. H. & Wessling, M. Porous microuidic devices fabrication and applications. Chem. Eng. Tech. 30, 309315 (2007).

30. Levkin, P. A., Svec, F. & Frchet, M. J. Porous polymer coatings: a versatile approach to superhydrophobic surfaces. Adv. Funct. Mat. 19, 1993 (2009).

31. Knappe, S. et al. Atomic vapor cells for chip-scale atomic clocks with improved long-term frequency stability. Opt. Lett. 30, 23512353 (2005).

Acknowledgements

We thank S. Schima for help with the fabrication of the device, E. Pratt and K. Stupic for useful comments on the manuscript, A. Pines for helpful discussions and L. Jimnez for help in the preparation of Fig. 1. This work is a contribution of the National Institute of Standards and Technology (NIST), an agency of the U.S. government, and is not subject to copyright. Research was supported by the U.S. Department of Energy, Ofce of Basic Energy Sciences, Division of Materials Science and Engineering under contract No. DEAC02-05CH11231 (D.J.K., S.J.S., H.L.R. and V.S.B.). R.J.M. was supported in part by the Roberto Rocca Education Program.

Author contributions

All authors contributed extensively to the work presented in this paper.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/naturecommunications

Web End =http://www.nature.com/ http://www.nature.com/naturecommunications

Web End =naturecommunications

Competing nancial interests: The authors declare no competing nancial interests.

Reprints and permission information is available online at http://npg.nature.com/reprintsandpermissions/

Web End =http://npg.nature.com/ http://npg.nature.com/reprintsandpermissions/

Web End =reprintsandpermissions/

How to cite this article: Jimnez-Martnez, R. et al. Optical hyperpolarization and NMR detection of 129Xe on a microuidic chip. Nat. Commun. 5:3908 doi: 10.1038/ncomms4908 (2014).

6 NATURE COMMUNICATIONS | 5:3908 | DOI: 10.1038/ncomms4908 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.