Publications

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Droplets, Turbulence, Mixing, and Clouds

Chandrakar, K. K., W. Cantrell, S. Krueger, R. A. Shaw, and S. Wunsch: Supersaturation fluctuations in moist turbulent Rayleigh-Bénard convection: a two-scalar transport problem. Journal of Fluid Mechanics, accepted. in review [first reviews received, minor revisions].

Chandrakar, K. K., I. Saito, F. Yang, W. Cantrell, T. Gotoh, and R. A. Shaw: Functional form of droplet size-distributions in turbulent clouds: experimental evaluation of theoretical distributions. Quarterly Journal of the Royal Meteorological Society, in review.

Chandrakar, K. K. and R. A. Shaw: In-situ and laboratory measurements of cloud microphysical properties. Chapter in Fast Physics in Large Scale Atmospheric Models, Editors Y. Liu, P. Kollias, and L. Donner, in review.

Glienke, S., A. B. Kostinski, R. A. Shaw, M. L. Larsen, J. P. Fugal, O. Schlenczek, and S. Borrmann: Holographic observations of centimeter-scale nonuniformities within marine stratocumulus clouds. Journal of the Atmospheric Sciences, accepted. in review [first reviews received, minor revisions].

Niedermeier, D., J. Voigtländer, S. Schmalfuss, J. Schumacher, R. A. Shaw, and F. Stratmann: Characterization and first results from LACIS-T: a moist-air wind tunnel to study aerosol-cloud-turbulence interactions. Atmospheric Measurement Techniques, in review [discussion paper available at https://www.atmos-meas-tech-discuss.net/amt-2019-343/ ].

Prabhakaran, P., G. Kinney, W. Cantrell, R. A. Shaw, and E. Bodenschatz: Ice nucleation observed in the wake of warm hydro-meteors. In review.

Siebert, H., K. Szodry, U. Egerer, B. Wehner, S. Henning, K. Chevalier, J. Lückerath, O. Welz, K. Weinhold, F. Lauermann, M. Gottschalk, A. Ehrlich, M. Wendisch, P. Fialho, S. Viviani, G. Roberts, N. Allwayin, S. Schum, R. A. Shaw, C. Mazzoleni, L. Mazzoleni, J. L. Nowak, S. Malinowski, K. Karpinska, W. Kumala, D. Czyzewska, P. Kollias, E. P. Luke, and R. Wood. Aerosols, clouds, turbulence and radiation at the marine boundary layer top over the Northern Atlantic Ocean: The ACORES campaign. Bulletin of the American Meteorological Society, in review.

Yang, F., W. H. Cantrell, A. B. Kostinski, R. A. Shaw, and A. M. Vogelmann, 2020: Is contact nucleation caused by pressure perturbation? Atmosphere, 11, 1; doi:10.3390/atmos11010001.

Albrecht, B., V. Ghate, J. Mohrmann, R. Wood, P. Zuidema, C. Bretherton, C. Schwartz, E. Eloranta, S. Glienke, S. Donaher, M. Sarkar, J. McGibbon, A. D. Nugent, R. A. Shaw, J. Fugal, P. Minnis, R. Paliknoda, L. Lussier, J. Jensen, J. Vivekanandan, S. Ellis, P. Tsai, R. Rilling, J. Haggerty, T. Campos, M. Stell, M. Reeves, S. Beaton, J. Allison, G. Stossmeister, S. Hall, and S. Schmidt, 2019: Cloud System Evolution in the Trades (CSET): Following the evolution of boundary layer cloud systems with the NSF-NCAR GV. Bulletin of the American Meteorological Society, 100, 93-121.

Bhandari, J., S. China, K. K. Chandrakar, G. Kinney, W. Cantrell, R. A. Shaw, L. R. Mazzoleni, G. Girotto, N. Sharma, K. Gorkowski, S. Gilardoni, S. Decesari, M. C. Facchini, N. Zanca, G. Pavese, F. Esposito, M. K. Dubey, A. C. Aiken, R. K. Chakrabarty, H. Moosmüller, T. B. Onasch, R. A. Zaveri, B. V. Scarnato, P. Fialho, and C. Mazzoleni, 2019: Extensive soot compaction by cloud processing from laboratory and field observations. Scientific Reports, 9, 11824.

Chandrakar, K. K., I. Saito, F. Yang, W. Cantrell, T. Gotoh, and R. A. Shaw, 2019: Droplet size distributions in turbulent clouds: experimental evaluation of theoretical distributions. Quarterly Journal of the Royal Meteorological Society, https://doi.org/10.1002/qj.3692.

Desai, N., K. K. Chandrakar, G. Kinney, W. Cantrell, and R. A. Shaw, 2019: Aerosol mediated glaciation and persistence of mixed-phase clouds: steady-state laboratory experiments. Geophysical Research Letters, 46.

Desai, N., S. Glienke, J. Fugal, and R. A. Shaw, 2019: Search for microphysical signatures of stochastic condensation in marine boundary layer clouds using airborne digital holography. Journal of Geophysical Research, 124, 2739-2752. https://doi.org/10.1029/2018JD029033.

Karpinska, K., J. F. E. Bodenschatz, S. P. Malinowski, J. L. Nowak, S. Risius, T. Schmeissner, R. A. Shaw, H. Siebert, H. Xi, H. Xu, E. Bodenschatz, 2019: Turbulence induced cloud voids: observation and interpretation. Atmospheric Chemistry and Physics, 19, 4991-5003.

Packard, C. D., M. L. Larsen, W. H. Cantrell, and R. A. Shaw, 2019: Light scattering in a spatially-correlated particle field: role of the radial distribution function. Journal of Quantitative Spectroscopy and Radiative Transfer, 236, 106601.

Thomas, S., M. Ovchinnikov, F. Yang, D. van der Voort, W. Cantrell, S. K. Krueger, and R. A. Shaw, 2019: Scaling of an atmospheric model to simulate turbulence and cloud microphysics in the Pi Chamber. Journal of Advances in Modeling Earth Systems, 11, 1981-1994, https://doi.org/10.1029/2019MS001670.

Chandrakar, K. K., W. Cantrell, A. B. Kostinski, and R. A. Shaw, 2018: Dispersion aerosol indirect effect in turbulent clouds: Laboratory measurements of effective radius. Geophysical Research Letters, 45, 10738-10745. https://doi.org/10.1029/2018GL079194.

Chandrakar, K. K., W. Cantrell, and R. A. Shaw, 2018: Influence of turbulent fluctuations on cloud droplet size dispersion and aerosol indirect effects. Journal of the Atmospheric Sciences, 75, 3191-3209.

Desai, N., K. K. Chandrakar, K. Chang, W. Cantrell, and R. A. Shaw, 2018: Influence of microphysical variability on stochastic condensation in a turbulent laboratory cloud. Journal of the Atmospheric Sciences, 75, 189-201.

Kumar, B., P. Goetzfried, N. Suresh, J. Schumacher, and R. A. Shaw, 2018: Scale-dependence of cloud microphysical response to turbulent entrainment and mixing. Journal of Advances in Modeling Earth Systems, 10, 2777-2785.

Larsen, M. L., and R. A. Shaw, 2018: A method for computing the three-dimensional radial distribution function of cloud particles from holographic images. Atmospheric Measurement Techniques, 11, 4261-4272.

Larsen, M. L., R. A. Shaw, A. B. Kostinski, and S. Glienke, 2018: Fine-scale droplet clustering in atmospheric clouds: 3D radial distribution function from airborne digital holography. Physical Review Letters, 121, 204501.

Thomas, S., M. Ovchinnikov, F. Yang, D. van der Voort, W. Cantrell, S. K. Krueger, and R. A. Shaw, 2019: Scaling of an atmospheric model to simulate turbulence and cloud microphysics in the Pi Chamber. Journal of Advances in Modeling Earth Systems, 11, 1981-1994, https://doi.org/10.1029/2019MS001670.

Niedermeier, D., K. Chang, W. Cantrell, K. K. Chandrakar, D. Ciochetto, and R. A. Shaw, 2018: Observation of a link between energy dissipation rate and oscillation frequency of the large-scale circulation in dry and moist Rayleigh-Bénard turbulence. Physical Review Fluids, 3, 083501.

Packard, C. D., R. A. Shaw, W. H. Cantrell, G. M. Kinney, M. C. Roggemann, and J. R. Valenzuela, 2018: Measuring the detector-observed impact of optical blurring due to aerosols in a laboratory cloud chamber. Journal of Applied Remote Sensing, 12, 042404.

Wood, R., K.-T. O, C. S. Bretherton, J. Mohrmann, B. A. Albrecht, P. Zuidema, V. Ghate, C. Schwartz, E. Eloranta, S. Glienke, R. A. Shaw, J. Fugal, and P. Minnis, 2018: Ultraclean layers and optically thin clouds in the stratocumulus-to-cumulus transition. Part I: Observations. Journal of the Atmospheric Sciences, 75, 1631-1652.

Yang, F., O. Cruikshank, W. He, A. Kostinski, and R. A. Shaw, 2018: Non-thermal ice nucleation observed at distorted contact lines of supercooled water drops. Physical Review E, 97, 023103.

Yang, F., P. Kollias, R. A. Shaw, and A. M. Vogelmann, 2018: Cloud droplet size distribution broadening during diffusional growth: ripening amplified by deactivation and reactivation. Atmospheric Chemistry and Physics, 18, 7313-7328.

Chandrakar, K. K., W. Cantrell, D. Ciochetto, S. Karki, G. Kinney, and R. A. Shaw, 2017: Aerosol removal and cloud collapse accelerated by supersaturation fluctuations in turbulence. Geophysical Research Letters, 44, doi:10.1002/2017GL072762.

Glienke, S., A. Kostinski, J. Fugal, R. A. Shaw, S. Borrmann, and J. Stith, 2017: Cloud droplets to drizzle: contribution of transition drops to microphysical and optical properties of marine stratocumulus clouds. Geophysical Research Letters, 44, doi: 10.1002/2017GL074430.

Goetzfried, P., B. Kumar, R. A. Shaw, J. Schumacher, 2017: Droplet dynamics and fine-scale structure in a shearless turbulent mixing layer with phase changes. Journal of Fluid Mechanics, 814, 452-483.

Siebert, H., and R. A. Shaw, 2017: Supersaturation fluctuations during the early stage of cumulus formation. Journal of the Atmospheric Sciences, 74, 975-988.

Chandrakar, K. K., W. Cantrell, K. Chang, D. Ciochetto, D. Niedermeier, M. Ovchinnikov, R. A. Shaw, and F. Yang, 2016: Aerosol indirect effect from turbulence-induced broadening of droplet size distributions. Proceedings of the National Academy of Sciences of the USA113, 14243-14248.

Chang, K., J. Bench, M. Brege, W. Cantrell, K. Chandrakar, D. Ciochetto, C. Mazzoleni, L. Mazzoleni, D. Niedermeier, and R. A. Shaw, 2016: A laboratory facility to study gas-aerosol-cloud interactions in a turbulent environment: The chamber. Bulletin of the American Meteorological Society, 97, 2343-2358.

Yang, F., R. A. Shaw, H. Xue, 2016: Conditions for super-adiabatic droplet growth after entrainment mixing. Atmospheric Chemistry and Physics, 16, 9421-9433.

Shaw, R. A., 2015: Review of “Physical Hydrodynamics” by Guyon et al. American Journal of Physics, 83, 1061-1062.

Beals, M. J., J. P. Fugal, R. A. Shaw, J. Lu, S. M. Spuler, and J. L. Stith, 2015: Holographic measurements of inhomogeneous cloud mixing at the centimeter scale. Science350, 87-90.

Lu, J., and R. A. Shaw, 2015: Charged particle dynamics in turbulence: theory and direct numerical simulations. Physics of Fluids27, 065111.

Chang, K., B. J. Malec, and R. A. Shaw, 2015: Turbulent pair dispersion in the presence of gravity. New Journal of Physics17, 033010.

Schmeissner, T., R. A. Shaw, J. Ditas, F. Stratmann, M. Wendisch, and H. Siebert, 2015: Turbulent mixing in shallow trade wind cumuli: dependence on cloud life cycle. Journal of the Atmospheric Sciences72, 1447–1465.

Katzwinkel, J., H. Siebert, T. Heus, and R. A. Shaw, 2014: Measurements of turbulent mixing and subsiding shells in trade wind cumuli. Journal of the Atmospheric Sciences71, 2810-2822.

Kumar, B., J. Schumacher, and R. A. Shaw, 2014: Lagrangian mixing dynamics at the cloudy-clear air interface. Journal of the Atmospheric Sciences71, 2564-2580.

Werner, F., F. Ditas, H. Siebert, M. Simmel, B. Wehner, P. Pilewskie, T. Schmeissner, R. A. Shaw, S. Hartmann, H. Wex, G. C. Roberts, and M. Wendisch, 2014: Twomey effect observed from collocated microphysical and remote sensing measurements over shallow cumulus. Journal of Geophysical Research119, 1534-1545.

Siebert, H., M. Beals, J. Bethke, E. Bierwirth, T. Conrath, K. Dieckmann, F. Ditas, A. Ehrlich, D. Farrell, S. Hartmann, M. A. Izaguirre, J. Katzwinkel, L. Nuijens, G. Roberts, M. Schaefer, R. A. Shaw, T. Schmeissner, I. Serikov, B. Stevens, F. Stratmann, B. Wehner, M. Wendisch, F. Werner, and H. Wex, 2013: The fine-scale structure of the trade wind cumuli over Barbados – an introduction to the CARRIBA project. Atmospheric Chemistry and Physics13, 10061-10077.

Bordás, R., Ch. Roloff, D. Thévenin, and R. A. Shaw, 2013: Experimental determination of droplet collision rates in turbulence. New Journal of Physics15, 045010.

Kumar, B., J. Schumacher, and R. A. Shaw, 2013: Cloud microphysical effects of turbulent mixing and entrainment. Theoretical and Computational Fluid Dynamics27, 361-376.

Kumar, B., F. Janetzko, J. Schumacher, and R. A. Shaw, 2012: Extreme responses of a coupled scalar-particle system during turbulent mixing. New Journal of Physics14, 115020.

Saw, E.-W., J. P. L. C. Salazar, L. R. Collins, and R. A. Shaw, 2012: Spatial clustering of polydisperse inertial particles in turbulence: I. Comparing simulation with theory. New Journal of Physics14, 105030.

Saw, E.-W., J. P. L. C. Salazar, L. R. Collins, and R. A. Shaw, 2012: Spatial clustering of polydisperse inertial particles in turbulence: II. Comparing simulation with experiment. New Journal of Physics14, 105031.

Katzwinkel, J., H. Siebert, and R. A. Shaw, 2012: Observation of a self-limiting, shear-induced turbulent inversion layer above marine stratocumulus. Boundary Layer Meteorology145, 131-143.

Ditas, F., R. A. Shaw, H. Siebert, M. Simmel, B. Wehner, and A. Wiedensohler, 2012: Aerosols-cloud microphysics-thermodynamics-turbulence: evaluating supersaturation in a marine stratocumulus cloud. Atmospheric Chemistry and Physics12, 2459-2468.

Lu, J., H. Nordsiek, and R. A. Shaw, 2010: Clustering of settling charged particles in turbulence: Theory and experiment. New Journal of Physics12, 123030.

Lu, J., H. Nordsiek, E. W. Saw, and R. A. Shaw, 2010: Clustering of charged inertial particles in turbulence. Physical Review Letters104, 184505.

Bodenschatz, E., S. P. Malinowski, R. A. Shaw, and F. Stratmann, 2010: Can we understand clouds without turbulence? Science327, 970-971.

Siebert, H., R. A. Shaw, and Z. Warhaft, 2010: Statistics of small-scale velocity fluctuations and internal intermittency in marine stratocumulus clouds. Journal of the Atmospheric Sciences67, 262-273.

Siebert, H., S. Gerashchenko, A. Gylfason, K. Lehmann, L. R. Collins, R. A. Shaw, and Z. Warhaft, 2010: Towards understanding the role of turbulence on droplets in clouds: In situ and laboratory measurements. Atmospheric Research97, 426-437.

Kostinski, A. B., and R. A. Shaw, 2009: Raindrops, large and small. Nature Physics5, 624-625.

Montero-Martínez, G., A. B. Kostinski, R. A. Shaw, and F. García-García, 2009: Do all raindrops fall at terminal speed? Geophysical Research Letters36, doi:10.1029/2008GL037111.

Lehmann, K., H. Siebert, and R. A. Shaw, 2009: Homogeneous and inhomogeneous mixing in cumulus clouds: Dependence on local turbulence structure. Journal of the Atmospheric Sciences66, 3641-3659.

Saw, E. W., R. A. Shaw, S. Ayyalasomayajula, P. Y. Chuang, and A. Gylfason, 2008: Inertial clustering of particles in high-Reynolds-number turbulence. Physical Review Letters100, 214501.

Lehmann, K., H. Siebert, M. Wendisch, and R. A. Shaw, 2007: Evidence for inertial droplet clustering in weakly turbulent clouds. Tellus59B, 57-65.

Siebert, H., H. Franke, K. Lehmann, R. Maser, E. W. Saw, D. Schell, R. A. Shaw, and M. Wendisch, 2006: Probing fine-scale dynamics and microphysics of clouds with helicopter-borne measurements. Bulletin of the American Meteorological Society87, 1727-1738.

Kostinski, A. B., and R. A. Shaw, 2005: Fluctuations and luck in droplet growth by coalescence. Bulletin of the American Meteorological Society86, 235-244.

Shaw, R. A., 2003: Particle-turbulence interactions in atmospheric clouds. Annual Review of Fluid Mechanics35, 183-227.

Shaw, R. A., A. B. Kostinski, and D. D. Lanterman, 2002: Super-exponential extinction of radiation in a negatively-correlated random medium. Journal of Quantitative Spectroscopy and Radiative Transfer75, 13-20.

Shaw, R. A., A. B. Kostinski, and M. L. Larsen, 2002: Towards quantifying droplet clustering in clouds. Quarterly Journal of the Royal Meteorological Society128, 1043-1057.

Kostinski, A. B., and R. A. Shaw, 2001: Scale-dependent droplet clustering in turbulent clouds. Journal of Fluid Mechanics , 434, 389-398.

Shaw, R. A., and S. P. Oncley, 2001: Acceleration intermittency and enhanced collision kernels in turbulent clouds. Atmospheric Research59-60, 77-87.

Shaw, R. A., 2000: Supersaturation intermittency in turbulent clouds. Journal of the Atmospheric Sciences57, 3452-3456.

Shaw, R. A., W. C. Reade, L. R. Collins, and J. Verlinde, 1999: Reply to comments. Journal of the Atmospheric Sciences56, 1437-1441.

Shaw, R. A., W. C. Reade, L. R. Collins, and J. Verlinde, 1998: Preferential concentration of cloud droplets by turbulence: Effects on the early evolution of cumulus cloud droplet spectra. Journal of the Atmospheric Sciences, 55, 1965-1976.

Ice, Water, and Nucleation

Prabhakaran, P., G. Kinney, W. Cantrell, R. A. Shaw, and E. Bodenschatz: Ice nucleation observed in the wake of warm hydro-meteors. In review.

Yang, F., O. Cruikshank, W. He, A. Kostinski, and R. A. Shaw, 2018: Non-thermal ice nucleation observed at distorted contact lines of supercooled water drops. Physical Review E, 97, 023103.

Wehner, B., F. Werner, F. Ditas, R. A. Shaw, M. Kulmala, and H. Siebert, 2015: Observations of new particle formation in enhanced UV irradiance zones near cumulus clouds. Atmospheric Chemistry and Physics15, 11701-11711.

Yang, F., R. A. Shaw, C. W. Gurganus, S. K. Chong, and Y. K. Yap, 2015: Ice nucleation at the contact line triggered by transient electrowetting fields. Applied Physics Letters107, 264101.

Yang, F., M. Ovchinnikov, and R. A. Shaw, 2015: Long-lifetime ice particles in mixed-phase stratiform clouds: Quasi-steady and recycled growth. Journal of Geophysical Research120, 11617-11635.

Gurganus, C. W., J. C. Charnawskas, A. B. Kostinski, and R. A. Shaw, 2014: Nucleation at the contact line observed on nanotextured surfaces. Physical Review Letters113, 235701.

Yang, F., M. Ovchinnikov, and R. A. Shaw, 2014: Microphysical consequences of the spatial distribution of ice nucleation in mixed-phase stratiform clouds. Geophysical Research Letters41, 5280-5287.

Yang, F., M. Ovchinnikov, and R. A. Shaw, 2013: Minimalist model of ice microphysics in mixed-phase stratiform clouds. Geophysical Research Letters40, 3756-3760, doi:10.1002/grl.50700.

Gurganus, C., A. B. Kostinski, and R. A. Shaw, 2013: High speed imaging of freezing drops: Still no preference for the contact line. Journal of Physical Chemistry C117, 6195-6200.

Gurganus, C., A. B. Kostinski, and R. A. Shaw, 2011: Fast imaging of freezing drops: No preference for nucleation at the contact line. Journal of Physical Chemistry Letters2, 1449-1454.

Niedermeier, D., S. Hartmann, T. Clauss, H. Wex, A. Kiselev, R. C. Sullivan, P. J. DeMott, M. D. Petters, P. Reitz, J. Schneider, E. Mikhailov, B. Sierau, O. Stetzer, B. Reimann, U. Bundke, R. A. Shaw, A. Buchholz, T. F. Mentel, and F. Stratmann, 2011: Experimental study of the role of physicochemical surface processing on the IN ability of mineral dust particles. Atmospheric Chemistry and Physics11, 11131-11144.

Niedermeier, D., R. A. Shaw, S. Hartmann, H. Wex, T. Clauss, J. Voigtländer, and F. Stratmann, 2011: Heterogeneous ice nucleation: Exploring the transition from stochastic to singular freezing behavior. Atmospheric Chemistry and Physics11, 8767-8775.

Wehner, B., H. Siebert, A. Ansmann, F. Ditas, P. Seifert, F. Stratmann, A. Wiedensohler, A. Apituley, R. A. Shaw, H. E. Manninen, and M. Kulmala, 2010: Observations of turbulence-induced new particle formation in the residual layer. Atmospheric Chemistry and Physics10, 4319-4330.

Niedermeier, D., S. Hartmann, R. A. Shaw, D. Covert, Th. F. Mentel, J. Schneider, L. Poulain, P. Reitz, C. Spindler, T. Clauss, A. Kiselev, E. Hallbauer, H. Wex, K. Mildenberger, and F. Stratmann, 2010: Heterogeneous freezing of droplets with immersed mineral dust particles – measurements and parameterization. Atmospheric Chemistry and Physics10, 3601-3614.

Durant, A. J., R. A. Shaw, W. I. Rose, Y. Mi, and G. G. J. Ernst, 2008: Ice nucleation and overseeding of ice in volcanic clouds. Journal of Geophysical Research, 113, D09206, doi:10.1029/2007JD009064.

Durant, A. J., and R. A. Shaw, 2005: Evaporation freezing by contact nucleation inside-out. Geophysical Research Letters, 32, L20814, doi:10.1029/2005GL024175.

Shaw, R. A., A. J. Durant, and Y. Mi, 2005: Heterogeneous surface crystallization observed in undercooled water. Journal of Physical Chemistry B109, 9865-9868.

Shaw, R. A., and D. Lamb, 1999: Experimental determination of the thermal accommodation and condensation coefficients of liquid water. Journal of Chemical Physics11110659-10663.

Shaw, R. A., and D. Lamb, 1999: Homogeneous freezing of evaporating cloud droplets. Geophysical Research Letters26, 1181-1184.

Jeffries, M. O., R. A. Shaw, K. Morris, A. Veazey, and H. R. Krouse, 1994: Crystal structure, stable isotopes (del18O), and development of sea ice in the Ross, Amundsen, and Bellingshausen Seas, Antarctica. Journal of Geophysical Research99, 985-995.

Jeffries, M. O., W. F. Weeks, R. Shaw, and K. Morris, 1993: Structural characteristics of congelation and platelet ice and their role in the development of Antarctic land-fast sea ice. Journal of Glaciology39, 223-238.

Instrumentation and Experimental Techniques

Packard, C. D., M. L. Larsen, W. H. Cantrell, and R. A. Shaw, 2019: Light scattering in a spatially-correlated particle field: role of the radial distribution function. Journal of Quantitative Spectroscopy and Radiative Transfer, 236, 106601.

Thomas, S., M. Ovchinnikov, F. Yang, D. van der Voort, W. Cantrell, S. K. Krueger, and R. A. Shaw, 2019: Scaling of an atmospheric model to simulate turbulence and cloud microphysics in the Pi Chamber. Journal of Advances in Modeling Earth Systems, 11, 1981-1994, https://doi.org/10.1029/2019MS001670.

Larsen, M. L., and R. A. Shaw, 2018: A method for computing the three-dimensional radial distribution function of cloud particles from holographic images. Atmospheric Measurement Techniques, 11, 4261-4272.

Lamb, D., and R. A. Shaw, 2016: A mechanical demonstration of liquid-vapor phase equilibrium. Bulletin of the American Meteorological Society97, 1355-1362.

Tao, J., C. Wang, C.-K. Shene, and R. A. Shaw, 2016: A vocabulary approach to partial streamline matching and exploratory flow visualization. IEEE Transactions on Visualization and Computer Graphics22, 1503-1516.

Risius, S., H. Xu, F. Di Lorenzo, H. Xi, H. Siebert, R. A. Shaw, and E. Bodenschatz, 2015: Schneefernerhaus as a mountain research station for clouds and turbulence. Atmospheric Measurement Techniques8, 3209-3218.

Siebert, H., R. A. Shaw, J. Ditas, T. Schmeissner, S. P. Malinowski, E. Bodenschatz, and H. Xu, 2015: High-resolution measurement of cloud microphysics and turbulence at a mountaintop station. Atmospheric Measurement Techniques8, 3219-3228.

Jackson, R. C., G. M. McFarquhar, J. Stith, M. Beals, R. A. Shaw, J. Jensen, J. Fugal, and A. Korolev, 2014: An assessment of the impact of antishattering tips and artifact removal techniques on cloud ice size distributions measured by the 2D cloud probe. Journal of Atmospheric and Oceanic Technology31, 2567-2590.

Bange, J., M. Esposito, D. H. Lenschow, P. R. A. Brown, V. Dreiling, A. Giez, L. Mahrt, S. Malinowski, A. R. Rodi, R. A. Shaw, H. Siebert, H. Smit, and M. Zöger, 2013: Measurement of aircraft state and thermodynamic and dynamic variables. Chapter 2 in Airborne Measurements for Environmental Research: Methods and Instruments, M. Wendisch and J.-L. Brenguier, eds., Wiley (Author of section 2.8.2 “Laser Doppler anemometers”).

Brenguier, J.-L., W. Bachalo, P. Y. Chuang, B. M. Esposito, J. Fugal, T. Garrett, J.-F. Gayet, H. Gerber, A. Heymsfield, A. Kokhanovsky, A. Korolev, R. P. Lawson, D. C. Rogers, R. A. Shaw, W. Strapp, and M. Wendisch, 2013: In situ measurements of cloud and precipitation particles. Chapter 5 in Airborne Measurements for Environmental Research: Methods and Instruments, M. Wendisch and J.-L. Brenguier, eds., Wiley (Coauthor with J. Fugal of section 5.3.4 “Imaging of particle ensembles – holography”).

Werner, F., H. Siebert P. Pilewskie, T. Schmeissner, R. A. Shaw, and M. Wendisch, 2013: New airborne retrieval approach for trade wind cumulus properties under overlying cirrus. Journal of Geophysical Research118, 3634-3649, doi:10.1002/jgrd.50334.

Lu, J., R. A. Shaw, and W. Yang, 2012: Improved particle size estimation in digital holography via sign matched filtering. Optics Express20, 12666-12674.

Hartmann, S., D. Niedermeier, J. Voigtländer, T. Clauss, R. A. Shaw, H. Wex, A. Kiselev, and F. Stratmann, 2011: Homogeneous and heterogeneous ice nucleation at LACIS: Operating principle and theoretical studies. Atmospheric Chemistry and Physics11, 1753-1767.

Henrich, F., H. Siebert, E. Jäkel, R. A. Shaw, and M. Wendisch, 2010: Collocated measurements of boundary layer cloud microphysical and radiative properties: A feasibility study. Journal of Geophysical Research115, D24214, doi:10.1029/2010JD013930.

Fugal, J. P., and R. A. Shaw, 2009: Cloud particle size distributions measured with an airborne digital in-line holographic instrument. Atmospheric Measurement Techniques2, 259-271.

Fugal, J. P., T. J. Schulz, and R. A. Shaw, 2009: Practical methods for automated reconstruction and characterization of particles in digital in-line holograms. Measurement Science and Technology20, 075501.

Stratmann, F., O. Möhler, R. A. Shaw, and H. Wex, 2009: Laboratory cloud simulation: Capabilities and limitations. Chapter 7 in Clouds in the Perturbed Climate System: Their Relationship to Energy Balance, Atmospheric Dynamics, and Precipitation, J. Heintzenberg and R. J. Charlson, eds., MIT Press.

Lu, J., J. P. Fugal, H. Nordsiek, E. W. Saw, R. A. Shaw, and W. Yang, 2008: Lagrangian particle tracking in three dimensions via single-camera in-line digital holography. New Journal of Physics10, 125013.

Chuang, P. Y., E. W. Saw, J. D. Small, R. A. Shaw, C. M. Sipperley, G. A. Payne, and W. D. Bachalo, 2008: Airborne phase Doppler interferometry for cloud microphysical measurements. Aerosol Science and Technology42, 685-702.

Fong, C. S., N. D. Black, P. A. Kiefer, and R. A. Shaw, 2007: An experiment on Rayleigh instability of charged liquid drops. American Journal of Physics75, 499-503.

Siebert, H., K. Lehmann, and R. A. Shaw, 2007: On the use of hot-wire anemometers for turbulence measurements in clouds. Journal of Atmospheric and Oceanic Technology24, 980-993.

Sergeyev, A. V., and R. A. Shaw, 2006: An inexpensive uniform-size aerosol generator. Measurement Science and Technology17, N41-N44.

Yang, W., A. B. Kostinski, and R. A. Shaw, 2006: Phase signature for particle detection with digital in-line holography. Optics Letters31, 1399-1401.

Yang, W., A. B. Kostinski, and R. A. Shaw, 2005: Depth-of-focus reduction for digital in-line holography of particle fields. Optics Letters30, 1303-1305.

Fugal, J. P., R. A. Shaw, E. W. Saw, and A. V. Sergeyev, 2004: Airborne digital holographic system for cloud particle measurements. Applied Optics43, 5987-5995.

Shaw, R. A., D. Lamb, and A. M. Moyle, 2000: An electrodynamic levitation system for studying individual cloud particles under upper-tropospheric conditions. Journal of Atmospheric and Oceanic Technology17, 940-948.