博文

【Science 催化文章】NMR Imaging of Catalytic Hydrogenation in Microreactors with the U

已有 5985 次阅读 2008-1-25 14:12 |个人分类:催化资源收藏

Science 25 January 2008:
Vol. 319. no. 5862, pp. 442 - 445
DOI: 10.1126/science.1151787

Reports

NMR Imaging of Catalytic Hydrogenation in Microreactors with the Use of para-Hydrogen

Louis-S. Bouchard,¹^* Scott R. Burt,¹ M. Sabieh Anwar,² Kirill V. Kovtunov,³ Igor V. Koptyug,³ Alexander Pines¹^*
Catalysis is vital to industrial chemistry, and the optimizationof catalytic reactors attracts considerable resources. It hasproven challenging to correlate the active regions in heterogeneouscatalyst beds with morphology and to monitor multistep reactionswithin the bed. We demonstrate techniques, using magnetic resonanceimaging and para-hydrogen (p-H₂) polarization, that allow directvisualization of gas-phase flow and the density of active catalystin a packed-bed microreactor, as well as control over the dynamicsof the polarized state in space and time to facilitate the studyof subsequent reactions. These procedures are suitable for characterizingreactors and reactions in microfluidic devices where low sensitivityof conventional magnetic resonance would otherwise be the limitingfactor.¹ Materials Sciences Division, Lawrence Berkeley National Laboratory and Department of Chemistry, University of California, Berkeley, CA 94720, USA.
² School of Science and Engineering, Lahore University of Management & Sciences, Opposite Sector U, D.H.A., Lahore 54792, Pakistan.
³ International Tomography Center, 3A Institutskaya Street, Novosibirsk 630090, Russia.

科学网pdf全文链接

Imaging of Catalytic Hydrogenation in Microreactors with the Use of para-Hydrogen

To whom correspondence should be addressed. E-mail: louis.bouchard@gmail.com (L.-S.B.); pines@berkeley.edu (A.P.)

Catalysis is a fundamental component to many industrial processesand, consequently, the optimization of catalytic reactions andreactors attracts considerable technological effort and financialcommitments. An important aspect of this optimization is tocorrelate the spatial distribution of the reactive conversioninside the reactor with the morphology and packing of the catalyst.Here, we describe a spectroscopic method for this purpose basedon magnetic resonance imaging (MRI) (1) that uses hyperpolarizedspins derived from p-H₂ (2, 3). Specifically, we achieve high-resolution,spatially resolved profiles of heterogeneous hydrogenation reactionstaking place at a solid-gas interface inside a microreactor.We demonstrate strongly enhanced nuclear magnetic resonance(NMR) signal intensities in the gas phase as well as precisecontrol over the spatiotemporal dynamics of the polarization.The enhanced sensitivity is particularly important for trackinggases and products in small volumes [e.g., in microfluidic devices(4, 5) or the limited void space of a tightly packed catalystbed]. Moreover, the controlled delivery of p-H₂–inducednuclear spin polarization acts as a spin label that can transportpolarization to remote regions in the reactor. This work hasimplications for studying kinetics and mechanisms of multistepheterogeneously catalyzed reactions and fluid-flow transport,as well as mass and heat transfer. Such characterization shouldfacilitate improved reactor and catalyst design.

Methods to optimize microreactors would be welcome in the contextof microfluidic (lab-on-a-chip) technology. In recent years,the compelling advantages of microfluidic technology (4, 5)in biopharmaceutical applications, chemical analysis (6), organicsynthesis (7, 8), and industrial catalysis have been recognizedand demonstrated (9, 10). These include smaller volumes andsubstantial economic savings, precise control of reactant delivery,improved fluid transport and heat dispersion, control of reactionrates, enhanced safety of highly exothermic or explosive processes,and the possibility of faster reactions, improved yield, andchemoselectivity. Recent developments in microfluidic technologyalso provide powerful means for performing complex reactions,such as multistep transformations (9) or multiphase reactions(10). Furthermore, the use of catalysts immobilized on solidsupports in flow-mode microreactors has recently been shownto result in highly efficient reactions (10, 11).

One important characterization for the optimization of catalystbed reactors is the flow map. Knowledge of the velocity distributionof the reaction product enables study of transport phenomenawithin a microreactor (12–14) and optimization of thecatalyst packing and reactor geometry. High flow uniformityin a catalytic converter is crucial for avoiding non-uniformdeactivation of the catalyst caused by both chemical and thermalaging. With the increasing sophistication of mathematical modeling,such systems are routinely characterized by computational fluiddynamics. However, the relevance of such models is in doubtuntil they are validated against real measurements (15). Thisis particularly difficult in packed-bed microreactors wherethe methods available are limited to tracers and bulk (average)properties of temperature, conversion, and velocity. Despitethe need for validation, the spatiotemporal distribution ofreactants and products in heterogeneous systems has been seldomvisited by chemical engineering researchers in recent years,owing to the substantial difficulties with performing quantitativemeasurements in situ (15).

Various techniques have been used to study the motion of fluidsin catalytic processes. For example, capacitance (16), single-photonemission–computed tomography (17), and positron emissiontomography (18) are used to monitor gas-liquid distributionsin multiphase reactors. But these methods measure average flowproperties and have limited spatial resolution. The use of MRIto characterize microreactors is advantageous because the techniqueis noninvasive, can probe optically opaque media, and is appealingfor catalysis because of the variety of molecular parametersthat can be mapped with considerable chemical and spatial selectivity(19). Specifically, flow maps and local density profiles canbe generated, molecular mobility can be tracked, and chemicalreaction mechanisms can be probed with spin-labeled nuclei (20).Previous applications of MRI to heterogeneous catalysis includedstudies of hydrogenation processes without p-H₂ (21, 22), catalystmorphologies and synthesis techniques (23, 24), and fluid flowthrough the catalyst bed (25), as well as monitoring of esterificationreactions (12, 13) in situ. All of these applications were basedon the NMR signal detection of the liquid phase and thus offera sensitivity that is three orders of magnitude larger as comparedwith gases, resulting from the difference in density. The sensitivityenhancement offered by p-H₂–induced polarization (PHIP)is essential for the application of MRI to heterogeneous chemicalreactions in the gas phase.

p-H₂ (2, 3, 26) is characterized by a singlet nuclear spin wavefunction and is relatively easy to prepare in quantum-stateensembles of very high purity. The total nuclear spin angularmomentum of this state is zero, resulting in no observable NMRsignal. However, if the protons participate in pairwise hydrogenationin which they become magnetically inequivalent, strong observablemagnetization can be produced (2, 3, 26) with a signal enhancementfactor typically on the order of 10⁴. For instance, if p-H₂is used in the hydrogenation of propylene into propane (27,28), the p-H₂– derived protons will be in the singletstate immediately after the transformation of the substratemolecule into the product molecule. Typically, the molecularadditions occur at randomly distributed times, and the resultis an incoherent but highly polarized nuclear spin state. Applicationof suitable radio-frequency (rf) pulses results in a hyperpolarizedNMR signal (29). However, if an isotropic mixing sequence isapplied during the course of the reaction, not only is a coherentsinglet state preserved, but the lifetime of this state is alsoincreased (30). As we demonstrate below, this effect allowsone to create a relatively long-lived, coherent packet of polarizedproduct molecules, which augments the versatility of this techniquebeyond hydrogenation reactions.

To demonstrate the effectiveness of heterogeneously catalyzedPHIP in microreactors, we use two model catalytic reactors (29)(Fig. 1). In both cases, propylene and p-H₂ gases are flowedthrough the catalyst bed and react to form propane. The firstreactor (reactor 1) contains a tightly packed bed of the silicagel–immobilized Wilkinson's catalyst located between twolayers of glass beads. This reactor is used to produce a highlypolarized product (propane) and illustrates the ability to resolveflow maps, active regions in the catalyst bed, and controlledtransport of polarization out of the catalyst bed. The secondreactor (reactor 2) comprises powdered Wilkinson's catalystloosely packed with some small ( $~$ 2-mm) air gaps. This secondreactor further demonstrates the control of a polarized outstreamand applications to a more heterogeneous packing.

Fig. 1. Schematic of the microreactors. The two model catalytic reactors consist of catalyst layers sandwiched between layers of glass beads for stability. Reactor 1 contains a thin layer of silica gel–supported Wilkinson's catalyst (orange). Reactor 2 contains powdered Wilkinson's catalyst (red) arrayed in variously sized clumps to demonstrate a more heterogeneous scenario. [View Larger Version of this Image (78K GIF file)]

The PHIP signal in these experiments is larger than the correspondingthermal signal by a factor of 300 (29). This enhancement iscrucial in light of the coil-sample arrangement. The ratio ofthe rf coil volume occupied by the microchannel to the rf coilvolume is less than 0.01: a situation that is unfavorable interms of detection sensitivity. Furthermore, the presence ofcatalyst powder occludes the space inside the microchannel.This sensitivity loss, combined with the low density of thegas, leads to a million-fold loss in sensitivity relative tostandard liquid-state NMR. Our experimental results show thatPHIP can, to a large extent, circumvent the problem of low sensitivitiesin gas-phase microreactors.

An image of the first reactor is shown in Fig. 2. The spatialdistribution of reactant (propylene) is barely resolved (Fig. 2A),whereas the polarized product (propane) shows a strongly enhancedsignal (Fig. 2B). We also compare a spectrum from the reactor(fig. S2A) and localized spectra from upstream of (fig. S2B)and in (fig. S2C) the catalyst bed. The use of a hyperpolarizedsubstance was also necessary for producing the high-resolutiongas-phase flow map shown in Fig. 2C (29). This example revealsheterogeneous flow patterns in the catalyst bed, which are consistentwith a non-uniform packing of the catalyst (29), that are notapparent in Fig. 2B. Flow imaging at the same resolution andsensitivity would not be possible with the exceedingly weakthermal signals.

Fig. 2. Density of active catalyst and flow map imaging. MRI images [field of view (FOV) (x to z): 2.3 mm by 7.0 mm; pixel size: 20 µm by 60 µm] of a tightly packed catalyst bed (catalyst layer thickness is $~$ 5 mm) are shown. (A) Thermally polarized propylene. The approximate position of the imaging FOV is indicated by the dashed red lines in the inset. (B) p-H₂–polarized propane. The signal-to-noise ratio (SNR) of this image is a factor of 300 larger than that of the thermally polarized propylene image. (C) Flow map in the xz plane with the use of polarized propane. The orientation of the arrows represents direction of the velocity, and their length represents its magnitude. The SNR of thermally polarized propylene was insufficient to generate a velocity map. The resolution of the flow map is intentionally decreased by retaining only 1 of every 16 arrows to avoid excessive overlap of the arrows. [View Larger Version of this Image (58K GIF file)]

As illustrated in Fig. 3A, the residence time inside the tightlypacked region leads to nearly complete magnetic relaxation,and no polarized product is observed beyond the catalyst bed.Although this outcome is ideal for imaging the active regionsof the catalyst bed, the polarized spins cannot be used forsubsequent reactions. Isotropic mixing sequences have been shownto prolong the lifetime of the nuclear spin-singlet state (30).Thus, the use of an isotropic mixing sequence (31) applied fora sufficiently long duration T_m allows the polarized productto escape the catalyst bed (the optimal T_m will depend on theaverage flow velocity v). This period is followed by a delayT_d, allowing the singlet state to travel a distance x = v xT_d, during which the singlet state evolves into a state observableby NMR. By varying T_d, we control the distance traveled beforethe polarization is released. Figure 3, B and C, demonstratesthe delivery of polarized product beyond the catalyst bed fortwo values of T_d.

Fig. 3. Controlled transport of polarized product. MRI images [FOV (x to z): 8.5 mm by 23 mm; pixel size: 0.5 mm by 1 mm] for different travel times after an isotropic mixing sequence are shown. (A) No isotropic mixing: The polarized product is observed only in the catalyst layer. The approximate position of the imaging FOV is indicated by the dashed red lines in the inset. (B) Ten milliseconds after isotropic mixing, the polarized product travels 5 mm. (C) Forty milliseconds after isotropic mixing, the product has traveled 10 mm. [View Larger Version of this Image (32K GIF file)]

Imaging of the second reactor (Fig. 4A) further demonstratesthe usefulness of controlling the polarized outstream. In contrastwith the packing in reactor 1, the looser packing in reactor2 results in a polarized product that can be seen escaping thefirst catalyst layer and flowing to the second layer in theabsence of singlet state preservation (T_m = 0 ms, T_d = 0 ms).Although this situation is desirable when the polarized productis to be used in subsequent reactions, it is problematic asa means for imaging the catalyst layer because of poor contrastand blurring from the uncontrolled flow of polarized product.This drawback can be remedied by controlling the singlet stateas follows. For short values of T_d (1 ms), no polarized productcan be seen between the catalyst layers, because the singletstate has not yet evolved into an observable state. At longertime intervals (T_d = 100 ms), the polarized product has traversedlonger distances and evolved into an observable polarized product.A photograph of the reactor (Fig. 4B) provides a comparisonof the distribution of catalyst in the reactor with the structuralmorphology observed in the MRI images.

Fig. 4. Imaging heterogeneous distributions of catalyst. (A) MRI images [FOV (x to z): 2 mm by 15 mm; pixel size: 0.4 mm by 0.9 mm] of the heterogeneous packing, acquired without isotropic mixing (T_m = 0 ms, T_d = 0 ms) and for two different travel time intervals (T_d = 1 and 100 ms) after 54 ms of isotropic mixing. (B) Catalytic reactor containing a heterogeneous packing of Wilkinson's catalyst powder mixed with glass beads. An enlarged view of the catalyst packing is shown in the inset. The dashed red lines indicate the approximate location of the FOV for the images in (A). [View Larger Version of this Image (59K GIF file)]

Regardless of the packing, singlet state preservation providesa distinctive method for controlled delivery of polarization.Combined with knowledge of the local flow velocity, the timedrelease of polarization can be performed in remote parts ofa microreactor. Thus, in multistep reactions, the polarizedproduct can be used as a spin label to elucidate subsequentstages of a reaction (20).

These experiments can be extended by means of a variety of polarizationtransfer and spin manipulation methods to move the enhancedsignal to other NMR-active nuclei on the substrate moleculeor onto the catalyst itself (14, 20). Transfer of polarizationto heteronuclei yields a larger range of chemical shifts ascompared with that of protons (14). The highly polarized spinproduct also makes it possible to image flows (32) and reactions(33) in precisely engineered microchannels noninvasively, openingthe way for a variety of microfluidic applications.

There are still many challenges to address before these resultscan be extended to a wider range of hydrogenation reactionsand conditions of industrial catalytic processes. In particular,it remains to be seen to what extent the polarization lifetimesand the NMR linewidths of the reaction products are affectedby the presence of metal catalyst surfaces, microscopic gradientsof magnetic susceptibility, high temperatures, paramagneticcatalysts and impurities, liquid films, and other complicationsthat can be expected under conditions encountered in practice.To this end, recent results (34) that demonstrate PHIP in heterogeneoushydrogenations catalyzed by supported metal catalysts (Pt/Al₂O₃and Pd/Al₂O₃) are encouraging.

References and Notes

1. P. C. Lauterbur, Nature 242, 190 (1973). [CrossRef]
2. J. Natterer, J. Bargon, Prog. Nucl. Magn. Reson. Spectrosc. 31, 293 (1997). [CrossRef]
3. C. R. Bowers, D. P. Weitekamp, Phys. Rev. Lett. 57, 2645 (1986). [CrossRef] [ISI] [Medline]
4. G. M. Whitesides, Nature 442, 368 (2006). [CrossRef] [Medline]
5. H. Craighead, Nature 442, 387 (2006). [CrossRef] [Medline]
6. D. Belder, Anal. Bioanal. Chem. 385, 416 (2006). [CrossRef] [ISI] [Medline]
7. P. Watts, S. J. Haswell, Chem. Eng. Technol. 28, 290 (2005). [CrossRef]
8. S. J. Haswell et al., Chem. Commun. 2001, 391 (2001).
9. B. Ahmed-Omer, J. C. Brandt, T. Wirth, Org. Biomol. Chem. 5, 733 (2007). [CrossRef] [ISI] [Medline]
10. J. Kobayashi et al., Science 304, 1305 (2004).[Abstract/Free Full Text]
11. A. R. Bogdan, B. P. Mason, K. T. Sylvester, D. T. McQuade, Angew. Chem. Int. Ed. 46, 1698 (2007). [CrossRef]
12. E. H. L. Yuen, A. J. Sederman, L. F. Gladden, Appl. Catal. Gen. 232, 29 (2002). [CrossRef]
13. M. Küppers, C. Heine, S. Han, S. Stapf, B. Blümich, Appl. Magn. Reson. 22, 235 (2002).
14. M. Haake, J. Natterer, J. Bargon, J. Am. Chem. Soc. 118, 8688 (1996). [CrossRef] [ISI]
15. D. Tayebi, H. F. Svendsen, H. A. Jakobsen, A. Grislingås, Chem. Eng. Comm. 186, 56 (2001). [CrossRef]
16. D. Mewes, T. Loser, M. Millies, Chem. Eng. Sci. 54, 4729 (1999). [CrossRef]
17. T. Bauer, S. Roy, R. Lange, M. Al-Dahhan, Chem. Eng. Sci. 60, 3101 (2005). [CrossRef]
18. D. J. Parker, P. A. McNeil, Meas. Sci. Technol. 7, 287 (1996). [CrossRef] [ISI]
19. P. T. Callaghan, Principles of Nuclear Magnetic Resonance Microscopy (Oxford Univ. Press, New York, 1993).
20. M. S. Anwar et al., Anal. Chem. 79, 2806 (2007). [Medline]
21. I. V. Koptyug, A. A. Lysova, R. Z. Sagdeev, V. N. Parmon, Catal. Today 126, 37 (2007). [CrossRef]
22. A. J. Sederman, M. D. Mantle, C. P. Dunckley, Z. Huang, L. F. Gladden, Catal. Lett. 103, 1 (2005). [CrossRef]
23. I. V. Koptyug, D. R. Sagdeev, E. Gerkema, H. Van As, H. R. Z. Sagdeev, J. Magn. Reson. 175, 21 (2005). [CrossRef] [ISI] [Medline]
24. A. A. Lysova et al., J. Am. Chem. Soc. 127, 11916 (2005). [CrossRef] [ISI] [Medline]
25. A. A. Lysova et al., Chem. Eng. J. 130, 101 (2007). [CrossRef]
26. C. R. Bowers, in Encyclopedia of Nuclear Magnetic Resonance, D. M. Grant, R. K. Harris, Eds. (Wiley, Chichester, UK, vol. 9, 2002), pp. 750–770.
27. I. V. Koptyug et al., J. Am. Chem. Soc. 129, 5580 (2007). [CrossRef] [ISI] [Medline]
28. L.-S. Bouchard et al., Angew. Chem. Int. Ed. 46, 4064 (2007). [CrossRef]
29. Materials and methods are available as supporting material on Science Online.
30. M. Carravetta, O. G. Johannessen, M. H. Levitt, Phys. Rev. Lett. 92, 153003 (2004). [CrossRef] [Medline]
31. A. J. Shaka, C. J. Lee, A. Pines, J. Magn. Reson. 77, 274 (1988). [ISI]
32. S. Ahola et al., Lab Chip 6, 90 (2006). [CrossRef] [ISI] [Medline]
33. L. Ciobanu, D. A. Jayawickrama, X. Zhang, A. G. Webb, J. V. Sweedler, Angew. Chem. Int. Ed. 42, 4669 (2003). [CrossRef]
34. K. V. Kovtunov, I. E. Beck, V. I. Bukhtiyarov, I. V. Koptyug, Angew. Chem. Int. Ed., in press (10.1002/anie.200704881).
35. This work was supported by the Director, Office of Science, Office of Basic Energy Sciences, Materials Sciences and Engineering Division, of the U.S. Department of Energy (DOE) under contract no. DE-AC03-76SF00098 and was partially supported by grants from the Russian Foundation for Basic Research (05-03-32472 and 07-03-12147), Siberian Branch of the Russian Academy of Sciences (integration grant no. 11), and Russian Academy of Sciences (5.1.1 and 5.2.3). S.R.B. thanks the U.S. Department of Homeland Security for support through a graduate fellowship, administered by the Oak Ridge Institute for Science and Education under the DOE contract number DE-AC05-06OR23100. I.V.K. thanks the Russian Science Support Foundation for financial support. The authors acknowledge R. Bergman, D. Wemmer, D. Budker, and J. Reimer for useful discussions and critical reading of the manuscript.

Supporting Online Materialwww.sciencemag.org/cgi/content/full/319/5862/442/DC1NMR Imaging of Catalytic Hydrogenation in Microreactors with the Use of para-Hydrogen

转载本文请联系原作者获取授权，同时请注明本文来自戴启广科学网博客。
链接地址：https://blog.sciencenet.cn/blog-3913-14939.html

上一篇：2008年Wolf化学奖颁发，Allen Bard 和William Moerner获奖（与催化相关）
下一篇：催化剂的发现

收藏 IP: .*| 热度|

当前推荐数：0

发表评论评论 (0 个评论)

数据加载中...

返回顶部

博文发布时间已经超过87600小时，评论已关闭。

戴启广

扫一扫，分享此博文

催化中国，中国催化分享 http://blog.sciencenet.cn/u/catachina 化学家（www.chemj.cn）

博文

【Science 催化文章】NMR Imaging of Catalytic Hydrogenation in Microreactors with the U

Reports

NMR Imaging of Catalytic Hydrogenation in Microreactors with the Use of para-Hydrogen

当前推荐数：0

发表评论评论 (0 个评论)

戴启广

全部作者的精选博文

全部作者的其他最新博文

全部精选博文导读

相关博文

催化中国， 中国催化分享 http://blog.sciencenet.cn/u/catachina 化学家（www.chemj.cn）

博文

【Science 催化文章】NMR Imaging of Catalytic Hydrogenation in Microreactors with the U

Reports

NMR Imaging of Catalytic Hydrogenation in Microreactors with the Use of para-Hydrogen

当前推荐数：0

发表评论 评论 (0 个评论)

戴启广

全部作者的精选博文

全部作者的其他最新博文

全部精选博文导读

相关博文

催化中国，中国催化分享 http://blog.sciencenet.cn/u/catachina 化学家（www.chemj.cn）

发表评论评论 (0 个评论)