{"id":13,"date":"2012-02-01T15:47:51","date_gmt":"2012-02-01T20:47:51","guid":{"rendered":"https:\/\/www.bu.edu\/fluidlab\/?page_id=13"},"modified":"2024-05-22T13:13:38","modified_gmt":"2024-05-22T17:13:38","slug":"research","status":"publish","type":"page","link":"https:\/\/www.bu.edu\/fluidlab\/research\/","title":{"rendered":"Research Themes"},"content":{"rendered":"<style><span style=\"display: inline-block; width: 0px; overflow: hidden; line-height: 0;\" data-mce-type=\"bookmark\" class=\"mce_SELRES_start\">\ufeff<\/span>\ntable,td {<br \/>    vertical-align: middle;<br \/>    border: none;<br \/>}<br \/>th {<br \/>    vertical-align: middle;<br \/>    font-weight: bold;<br \/>}<br \/>th.cent {<br \/>    border: none;<br \/>    border-left: 1px solid #A9A9A9;<br \/>    border-right: 1px solid #A9A9A9;<br \/>}<br \/>th.left {<br \/>    border: none;<br \/>    border-right: 1px solid #A9A9A9;<br \/>}<br \/>th.right {<br \/>    border: none;<br \/>    border-left: 1px solid #A9A9A9;<br \/>}<br \/>td.left {<br \/>    border-right: 1px solid #A9A9A9;<br \/>    text-align: center;<br \/>    width: 33%;<br \/>}<br \/>td.cent {<br \/>    border-left: 1px solid #A9A9A9;<br \/>    border-right: 1px solid #A9A9A9;<br \/>    text-align: center;<br \/>    width: 33%;<br \/>}<br \/>td.right {<br \/>    border-left: 1px solid #A9A9A9;<br \/>    text-align: center;<br \/>    width: 33%;<br \/>}<br \/><\/style>\n<table>\n<tbody>\n<tr>\n<th class=\"left\">Environment<\/th>\n<th class=\"cent\"><b>Energy<\/b><\/th>\n<th class=\"right\">Manufacturing<\/th>\n<\/tr>\n<tr>\n<td class=\"left\">Bubble-driven flux of sea salt &amp; cloud condensation nuclei<\/td>\n<td class=\"cent\">Enhancing oil recovery &amp; carbon sequestration with wettability<\/td>\n<td class=\"right\">Cell damage from bubbles in bioreactors. Bubbles in molten glass.<\/td>\n<\/tr>\n<tr style=\"border-top: 1px solid #A9A9A9;\">\n<th class=\"left\">Health<\/th>\n<th class=\"cent\">Materials and coatings<\/th>\n<th class=\"right\">Forensics<\/th>\n<\/tr>\n<tr>\n<td class=\"left\">Fluid mechanics of urological procedures. Pathogen transfer from aerosols.<\/td>\n<td class=\"cent\">Mitigating biofouling with aeration and advanced coatings<\/td>\n<td class=\"right\">Fluid dynamics of spreading and drying human blood<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<\/p>\n<h3>Publication List<\/h3>\n<hr \/>\n<p style=\"font-size: 12px;\">Please note: Electronic versions of these papers are provided for academic purposes only. Please do not repost without appropriate permission.<\/p>\n<p><bf>2023:<\/bf><\/p>\n<ul>\n<li>\nLee, G., Attinger, D., Martin, K. F., Shiri, S., &#038; Bird, J. C. (2023). Bloodstain tails: Asymmetry aids reconstruction of oblique impact. <em>Physics of Fluids<\/em>, <strong>35<\/strong>(11), 112113. doi:<a href=\"https:\/\/doi.org\/10.1063\/5.0170124\">https:\/\/doi.org\/10.1063\/5.0170124<\/a><\/li>\n<\/li>\n<li> Dubitsky, L., Stokes, M.D., Deane, G.B., &#038; Bird, J. C. (2023). Effects of salinity beyond coalescence on submicron aerosol distributions. <em>Journal of Geophysical Research: Atmospheres<\/em>, <strong>128<\/strong>(5), e2022JD038222. doi:<a href=\"https:\/\/doi.org\/10.1029\/2022JD038222\">https:\/\/doi.org\/10.1029\/2022JD038222<\/a><\/li>\n<\/li>\n<li> Bartlett, C., Oratis, A.T., Santin, M., &#038; Bird, J. C. (2023). Universal non-monotonic drainage in large bare viscous bubbles. <em>Nature Communications<\/em>, <strong>14<\/strong>, 877. doi:<a href=\"https:\/\/doi.org\/10.1038\/s41467-023-36397-0\">https:\/\/doi.org\/10.1038\/s41467-023-36397-0<\/a> [<a href=\"\/fluidlab\/files\/2023\/02\/NatComm_Bartlett2023.pdf\">PDF<\/a>] <\/li>\n<\/li>\n<li> Dubitsky, L., McRae, O., &#038; Bird, J. C. (2023). Enrichment of scavenged particles in jet drops determined by bubble size and particle position. <em>Physical Review Letters<\/em>, <strong>130<\/strong>(5), 054001. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevLett.130.054001\">https:\/\/doi.org\/10.1103\/PhysRevLett.130.054001<\/a> [<a href=\"\/fluidlab\/files\/2023\/02\/PhysRevLett.130.054001.pdf\">PDF<\/a>] <\/li>\n<\/li>\n<\/ul>\n<p><bf>2022:<\/bf><\/p>\n<ul>\n<li> McRae, O., Ramakrishnan, T. S., &#038; Bird, J. C. (2022). Microscale heterogeneous pore occupancy with variable background resistance. <em>Journal of Colloid and Interface Science<\/em>, <strong>608<\/strong>, 1919-1928. doi:<a href=\"https:\/\/doi.org\/10.1016\/j.jcis.2021.10.029\">10.1016\/j.jcis.2021.10.029<\/a> <\/li>\n<li> Bird, J. C. (2022). Hot surfaces cooled by isolating steam from spray. <em>Nature News and Views<\/em>, <strong>601<\/strong>, 509-510. doi:<a href=\"https:\/\/doi.org\/10.1038\/d41586-022-00123-5\">10.1038\/d41586-022-00123-5<\/a> <\/li>\n<\/ul>\n<\/li>\n<\/ul>\n<p><bf>2021:<\/bf><\/p>\n<ul>\n<li>McRae, O., Oratis, A. T., &#038; Bird, J. C. (2021). Viscous wrinkling of nonuniform sheets. <em>Physical  Review Fluids<\/em> <strong>6<\/strong>(11), 110506. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevFluids.6.110506\">10.1103\/PhysRevFluids.6.110506<\/a> [<a href=\"\/fluidlab\/files\/2022\/12\/McRae_Oratis_PRF2021.pdf\">PDF<\/a>]<\/li>\n<li>Dubitsky, L., Menesses, M., Belden, J., &amp; Bird, J. C. (2021). Using aeration to probe the flow characteristics associated with long-term marine macrofouling growth and suppression. <em>Biofouling<\/em>, <strong>37<\/strong>(3), 289-298. doi:<a href=\"https:\/\/doi.org\/10.1080\/08927014.2021.1900131\">10.1080\/08927014.2021.1900131<\/a> [<a href=\"\/fluidlab\/files\/2021\/03\/Dubitsky_et_al-2021_Biofouling_author_version.pdf\">PDF<\/a>]<\/li>\n<li>McRae, O., Mead, K. R, &amp; Bird, J. C. (2021). Aerosol agitation: Quantifying the hydrodynamic stressors on particulates encapsulated in small droplets. <em>Phys. Rev. Fluids<\/em>, <strong>6<\/strong>(3), L031601. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevFluids.6.L031601\">10.1103\/PhysRevFluids.6.L031601<\/a> [<a href=\" \/fluidlab\/files\/2021\/05\/McRae_et_al_2021_PRF.pdf\">PDF<\/a>]<\/li>\n<li style=\"list-style-type: none;\">\n<\/ul>\n<\/li>\n<\/ul>\n<p><bf>2020:<\/bf><\/p>\n<ul>\n<li>Oratis, A. T., Bush, J. W., Stone, H. A., &amp; Bird, J. C. (2020). A new wrinkle on liquid sheets: Turning the mechanism of viscous bubble collapse upside down. <em>Science<\/em>, <b>369<\/b>(6504). doi:<a href=\"https:\/\/doi.org\/10.1126\/science.aba0593\">10.1126\/science.aba0593<\/a> [<a href=\"\/fluidlab\/files\/2021\/05\/Oratis_et_al_2020_Science.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n<p><bf>2019:<\/bf><\/p>\n<ul>\n<li>Menesses, M., Roch\u00e9, M., Royon, L., &amp; Bird, J. C. (2019). Surfactant-free persistence of surface bubbles in a volatile liquid. <em>Phys. Rev. Fluids<\/em>, <strong>4<\/strong>(10), 100506. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevFluids.4.100506\">10.1103\/PhysRevFluids.4.100506<\/a> [<a href=\"\/fluidlab\/files\/2021\/05\/Menesses_et_al_2019_PRF.pdf\">PDF<\/a>]<\/li>\n<li>Oratis A. T., &amp; Bird J. C. (2019). Shooting Rubber Bands: Two Self-Similar Retractions for a Stretched Elastic Wedge. <em>Phys. Rev. Lett.<\/em>, <b>122<\/b>(1), 014102. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevLett.122.014102\">10.1103\/PhysRevLett.122.014102<\/a> <!--[<a href=\"\/fluidlab\/files\/2019\/01\/Oratis_Bird-PRL-2019-Shooting_Rubber_Bands.pdf\">PDF<\/a>]--><\/li>\n<li>Shiri S., Martin K.F., &amp; Bird J.C. (2019). Surface coatings including fingerprint residues can significantly alter the size and shape of bloodstains. <em>Forensic Science International<\/em>, <b>295<\/b>, 189-198. doi:<a href=\"https:\/\/doi.org\/10.1016\/j.forsciint.2018.12.008\">10.1016\/j.forsciint.2018.12.008<\/a><\/li>\n<\/ul>\n<p><bf>2018:<\/bf><\/p>\n<ul>\n<li>Oratis A. T., Subasic J. J., Hernandez N., Bird J. C., &amp; Eisner B. H. (2018). A simple fluid dynamic model of renal pelvis pressures during ureteroscopic kidney stone treatment. <em>PLOS One<\/em>, <b>13<\/b>(11). doi:<a href=\" https:\/\/doi.org\/10.1371\/journal.pone.0208209\">journal.pone.0208209<\/a> [<a href=\"\/fluidlab\/files\/2018\/12\/Oratis_et_al-2018-PLOS_One.pdf\">PDF<\/a>]<\/li>\n<li>Shiri S., Murrizi A., &amp; Bird J. C. (2018). Trapping a Hot Drop on a Superhydrophobic Surface with Rapid Condensation or Microtexture Melting. <em> Micromachines<\/em>, <b>9<\/b>(11), 566. doi:<a href=\"https:\/\/doi.org\/10.3390\/mi9110566\">10.3390\/mi9110566<\/a> [<a href=\"\/fluidlab\/files\/2018\/11\/Shiri_Bird-2018-TrappingaHotDrop_Micromachines.pdf\">PDF<\/a>]<\/li>\n<li>Brasz C. F., Berny A., &amp; Bird, J. C. (2018). Threshold for discretely self-similar satellite drop formation from a retracting liquid cone. <em>Phys. Rev. Fluids<\/em>, <b>3<\/b>(10), 104002. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevFluids.3.104002\">10.1103\/PhysRevFluids.3.104002<\/a> [<a href=\"\/fluidlab\/files\/2018\/10\/Brasz_et_al-2018-Phys_Rev_F-Threshold_for_discretely_self-similar_satelite_drop.pdf\">PDF<\/a>]<\/li>\n<li>Brasz C. F., Bartlett C.T., Walls P. L. L., Flynn E. G., Yu Y. E., &amp; Bird, J. C. (2018). Minimum size for the top jet drop from a bursting bubble. <em>Phys. Rev. Fluids<\/em>, <b>3<\/b>(7), 074001. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevFluids.3.074001\">10.1103\/PhysRevFluids.3.074001<\/a> [<a href=\"\/fluidlab\/files\/2018\/07\/Brasz_et_al-2018-Phys_Rev_F-Minimum_size_top_jet_drop.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n<p><bf>2017:<\/bf><\/p>\n<ul>\n<li>Oratis, A.T., Farmer, T.P., &amp; Bird, J.C. (2017). Capillary induced twisting of Janus cylinders. <em>Soft matter<\/em>, <b>13<\/b>(21) 7556-7561. doi:<a href=\"https:\/\/doi.org\/10.1039\/C7SM01288H\">10.1039\/C7SM01288H<\/a><\/li>\n<li>Walls, P. L. L., McRae, O., Natarajan, V., Johnson, C., Antoniou, C., &amp; Bird J. C. (2017). Quantifying the potential for bursting bubbles to damage suspended cells. <em>Scientific Reports<\/em>. doi:<a href=\"https:\/\/doi.org\/10.1038\/s41598-017-14531-5\">10.1038\/s41598-017-14531-5<\/a><\/li>\n<li>Menesses M, Belden J, Dickenson, N &amp; Bird JC. (2017). Measuring a critical stress for continuous prevention of marine biofouling accumulation with aeration. <em>Biofouling<\/em>. <b>33<\/b>(9), 703-711. doi:<a href=\"https:\/\/doi.org\/10.1080\/08927014.2017.1359574\">10.1080\/08927014.2017.1359574<\/a> [<a href=\"\/fluidlab\/files\/2018\/08\/Menesses_et_al-2017-author_archival_version_with_supplemental.pdf\">PDF<\/a>]<\/li>\n<li>McRae O, Gaillard A, &amp; Bird JC. (2017). Periodic jetting and monodisperse jet drops from oblique gas injection. <em>Phys. Rev. E<\/em>, 96,013112. doi:<a href=\"https:\/\/doi.org\/10.1103\/PhysRevE.96.013112\">10.1103\/PhysRevE.96.013112<\/a> <!--[<a href=\"\/fluidlab\/files\/2017\/07\/McRae_Gaillard_Bird-Periodic_jetting_monodisperse_drops-2017.pdf\">PDF<\/a>]--><\/li>\n<li>Walls, P. L. L., &amp; Bird, J. C. (2017). Enriching particles on a bubble through drainage: Measuring and modeling the concentration of microbial particles in a bubble film at rupture. <em>Elem Sci Anth<\/em>, 5. [<a href=\"\/fluidlab\/files\/2017\/07\/Walls-Bird_elementa_2017.pdf\">PDF<\/a>]<\/li>\n<li>Shiri, S., &amp; Bird, J. C. (2017). Heat exchange between a bouncing drop and a superhydrophobic substrate. <em>J. Proc. Natl. Acad. Sci.<\/em>, <b>114<\/b>(27), 6930-6935. <a href=\"http:\/\/doi.org\/10.1073\/pnas.1700197114\">http:\/\/doi.org\/10.1073\/pnas.1700197114<\/a> [<a href=\"\/fluidlab\/files\/2017\/07\/Heat-exchange-between-a-bouncing-drop-and-a-superhydrophobic-substrate.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n<p><bf>2016:<\/bf><\/p>\n<ul>\n<li>Patterson, C. J., Shiri, S., &amp; Bird, J. C. (2016). Macrotextured spoked surfaces reduce the residence time of a bouncing Leidenfrost drop. <em>J. Phys. Condens. Matter<\/em> 29 (6), 064007. <a href=\"http:\/\/iopscience.iop.org\/article\/10.1088\/1361-648X\/aa4e8a\">http:\/\/iopscience.iop.org\/article\/10.1088\/1361-648X\/aa4e8a<\/a><\/li>\n<li>Walls, P. L. L., Dequidt, G., &amp; Bird, J. C. (2016). Capillary displacement of viscous liquids. <em>Langmuir<\/em> 32 (13), 3186\u20133190. <a href=\"http:\/\/pubs.acs.org\/doi\/abs\/10.1021\/acs.langmuir.6b00351\">http:\/\/doi.org\/10.1021\/acs.langmuir.6b00351<\/a><\/li>\n<\/ul>\n<p><bf>2015:<\/bf><\/p>\n<ul>\n<li>Walls, P. L. L., Henaux, L., &amp; Bird, J. C. (2015). Jet drops from bursting bubbles: How gravity and viscosity couple to inhibit droplet production. <em>Phys. Rev. E<\/em>, 92(2), 021002. <a href=\"http:\/\/doi.org\/10.1103\/PhysRevE.92.021002\">http:\/\/doi.org\/10.1103\/PhysRevE.92.021002<\/a> [<a href=\"\/fluidlab\/files\/2016\/01\/Walls-Henaux-Bird-2015-Jet-drops-from-bursting-bubbles-How-gravity-and-viscosity-couple-to-inhibit-droplet-production.pdf\">PDF<\/a>]<\/li>\n<li>Farmer, T. P., &amp; Bird, J. C. (2015). Asymmetric capillary bridges between contacting spheres. <em>J. Colloid Interf. Sci<\/em>, 454 (April), 192\u2013199. [<a href=\"\/fluidlab\/files\/2016\/01\/Asymmetric-capillary-bridges-between-contacting-spheres.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n<p><bf>2014:<\/bf><\/p>\n<ul>\n<li>Bartlett, C. T., G\u00e9n\u00e9ro, G. A., &amp; Bird, J. C. (2014). Coalescence and break-up of nearly inviscid conical droplets. <em>J. Fluid Mech.<\/em>, 763, 369\u2013385. [<a href=\"\/fluidlab\/files\/2016\/01\/Bartlett-G\u00e9n\u00e9ro-Bird-2014-Coalescence-and-break-up-of-nearly-inviscid-conical-droplets.pdf\">PDF<\/a>]<\/li>\n<li>Walls, P. L. L., Bird, J. C., &amp; Bourouiba, L. (2014). Moving with Bubbles: A Review of the Interactions between Bubbles and the Microorganisms that Surround them. <em>Integrative and Comparative Biology<\/em>, 1\u201312. [<a href=\"\/fluidlab\/files\/2016\/01\/Walls-Bird-Bourouiba-2014-Moving-with-Bubbles-A-Review-of-the-Interactions-between-Bubbles-and-the-Microorganisms-that-Surround-th.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n<p><bf>2013 and earlier:<\/bf><\/p>\n<ul>\n<li>J.C. Bird, R. Dhiman, H. Kwon, &amp; K. K. Varanasi (2013). \u201cReducing contact time of a bouncing drop.\u201d <em>Nature<\/em>. 503, 385-388. [<a href=\"\/fluidlab\/files\/2016\/01\/Bird-et-al.-2013-Reducing-the-contact-time-of-a-bouncing-drop.pdf\">PDF<\/a>]<\/li>\n<li>H. Kim, J.C. Bird, K. K. Varanasi (2013) \u201cIncreasing the Leidenfrost point using micro-nano hierarchical surface textures.&#8221; <em>App. Phys. Lett.<\/em> 103, 201601. [<a href=\"\/fluidlab\/files\/2016\/01\/Increasing-the-Leidenfrost-point-using-micro-nano-hierarchical-surface-textures.pdf\">PDF<\/a>]<\/li>\n<li>N. Meskhidze, et al., (2013) \u201cProduction mechanisms, number concentration, size distribution, chemical composition and optical properties of sea spray aerosols\u201d <em>Atmos. Sci. Lett.<\/em> 14 207-213. [<a href=\"\/fluidlab\/files\/2016\/01\/Meskhidze_et_al-2013-Atmospheric_Science_Letters.pdf\">PDF<\/a>]<\/li>\n<li>J.C. Bird, R. de Ruiter, L. Courbin, &amp; H.A. Stone (2010) \u201cDaughter bubble cascades produced by folding of ruptured thin films.\u201d <em>Nature<\/em>. 465, 759-762. [<a href=\"\/fluidlab\/files\/2017\/10\/Bird_et_al-2010-Daughter_bubble_cascades_produced_by_folding_of_ruptured_thin_films-with_supplement.pdf\">PDF<\/a>]<\/li>\n<li>L. Courbin, J.C. Bird, M. Reyssat, and H.A. Stone (2009). &#8220;Dynamics of wetting: From inertial spreading to viscous imbibition.&#8221; <em>J. Phys.: Condens. Matter <\/em>21<em> <\/em><em>464127<\/em>. [<a href=\"\/fluidlab\/files\/2016\/01\/inertial-to-viscous.pdf\">PDF<\/a>]<\/li>\n<li>A.C. Rowat, J.C. Bird, J.J. Agresti, O.J. Rando, and D.A. Weitz (2009). &#8220;Tracking lineages of cells in lines using a microfluidic device.&#8221; <em>Proc. Nat. Acad. Sci. U.S.A.<\/em><em> 106:18149-18154.<\/em> [<a href=\"\/fluidlab\/files\/2016\/01\/Rowat-et-al.-2009-Tracking-lineages-of-single-cells-in-lines-using-a-microfluidic-device.pdf\">PDF<\/a>]<\/li>\n<li>J.C. Bird, W. D. Ristenpart, A. Belmonte, and H.A. Stone (2009). &#8220;Critical angle for electrically driven coalescence of two conical droplets.&#8221; <em>Phys. Rev. Lett.<\/em><em> 103, 164502.<\/em> [<a href=\"\/fluidlab\/files\/2016\/01\/critical-angle-conical.pdf\">PDF<\/a>]<\/li>\n<li>W. D. Ristenpart, J.C. Bird, A. Belmonte, F. Dollar, and H.A. Stone (2009). &#8220;Non-coalescence of oppositely charged drops&#8221; <em>Nature<\/em> 461, 377-380. [<a href=\"\/fluidlab\/files\/2016\/01\/noncoalescence-of-opposite-charge.pdf\">PDF<\/a>]<\/li>\n<li>J.C. Bird, S.S.H. Tsai, and H.A. Stone (2009). &#8220;Inclined to splash: Triggering and inhibiting a splash with tangential velocity.&#8221; <em>New J. Phys.<\/em> 11, 063017. [IOP Select] [<a href=\"\/fluidlab\/files\/2016\/01\/inclined-to-splash.pdf\">PDF<\/a>]<\/li>\n<li>L. Courbin, J.C. Bird, A. Belmonte, and H.A. Stone (2008). &#8220;&#8221;Black hole&#8221; nucleation in a splash of milk&#8221; <em>Phys. Fluids<\/em> 20, 091106. [Winning entry, 2008 Gallery of Fluid Motion] [<a href=\"\/fluidlab\/files\/2016\/01\/black-hole-nucleation.pdf\">PDF<\/a>]<\/li>\n<li>J.C. Bird, S. Mandre, and H.A. Stone (2008). &#8220;Short-time dynamics of partial wetting.&#8221; <em>Phys. Rev. Lett.<\/em> 100, 234501. [<a href=\"\/fluidlab\/files\/2016\/01\/Bird-Mandre-Stone-2008-Short-Time-Dynamics-of-Partial-Wetting.pdf\">PDF<\/a>]<\/li>\n<li>L. Courbin, J.C. Bird, and H.A. Stone (2006). &#8220;Splash and anti-splash: Observation and design.&#8221; <em>Chaos<\/em> 16, 041102. [<a href=\"\/fluidlab\/files\/2016\/01\/splash-antisplash.pdf\">PDF<\/a>]<\/li>\n<li>M.J. Kim, M.J. Kim, J.C. Bird , J. Park, T.R. Powers, &amp; K.S. Breuer (2004). &#8220;Particle Image Velocimetry Measurements on a Macro-scale Model for Bacterial Flagellar Bundling.&#8221; <em>Exp. Fluids<\/em> 37: 782-788. [<a href=\"\/fluidlab\/files\/2016\/01\/particle-image-velocimetry.pdf\">PDF<\/a>]<\/li>\n<li>G. Han, K.J. Westin, J.C. Bird, Z. Cao, &amp; K.S. Breuer (2004). &#8220;Infrared Diagonistics for Measuring Fluid and Solid Motion inside Microdevices.&#8221; <em>Microscale Therm. Eng.<\/em> 8: 169-182. [<a href=\"\/fluidlab\/files\/2016\/01\/Hans-et-al-2004.pdf\">PDF<\/a>]<\/li>\n<li>M.J. Kim, J.C. Bird, A.J. VanParys, K.S. Breuer, &amp; T.R. Powers (2003). &#8220;A macroscopic scale model of bacterial flagellar bundling.&#8221;<em> Proc. Nat. Acad. Sci. U.S.A. <\/em>100: 15481-15485. [<a href=\"\/fluidlab\/files\/2016\/01\/bundling.pdf\">PDF<\/a>]<\/li>\n<\/ul>\n","protected":false},"excerpt":{"rendered":"<p>Environment Energy Manufacturing Bubble-driven flux of sea salt &amp; cloud condensation nuclei Enhancing oil recovery &amp; carbon sequestration with wettability Cell damage from bubbles in bioreactors. Bubbles in molten glass. Health Materials and coatings Forensics Fluid mechanics of urological procedures. Pathogen transfer from aerosols. Mitigating biofouling with aeration and advanced coatings Fluid dynamics of spreading [&hellip;]<\/p>\n","protected":false},"author":5737,"featured_media":0,"parent":0,"menu_order":3,"comment_status":"closed","ping_status":"closed","template":"page-templates\/no-sidebars.php","meta":[],"_links":{"self":[{"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/pages\/13"}],"collection":[{"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/users\/5737"}],"replies":[{"embeddable":true,"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/comments?post=13"}],"version-history":[{"count":51,"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/pages\/13\/revisions"}],"predecessor-version":[{"id":1480,"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/pages\/13\/revisions\/1480"}],"wp:attachment":[{"href":"https:\/\/www.bu.edu\/fluidlab\/wp-json\/wp\/v2\/media?parent=13"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}