| dc.contributor.author | Abboud J.E. |
| dc.contributor.author | Oweis G.F. |
| dc.contributor.editor | |
| dc.date | 2013 |
| dc.date.accessioned | 2017-10-04T11:15:54Z |
| dc.date.available | 2017-10-04T11:15:54Z |
| dc.date.issued | 2013 |
| dc.identifier | 10.1007/s00348-012-1438-6 |
| dc.identifier.isbn | |
| dc.identifier.issn | 07234864 |
| dc.identifier.uri | http://hdl.handle.net/10938/14913 |
| dc.description.abstract | An inertial bubble collapsing near a solid boundary generates a fast impulsive microjet directed toward the boundary. The jet impacts the solid boundary at a high velocity, and this effect has been taken advantage of in industrial cleaning such as when tiny bubbles are driven ultrasonically to cavitate around machined parts to produce jets that are believed to induce the cleaning effect. In this experimental investigation, we are interested in the jetting from single cavities near a boundary. By introducing a through hole in the boundary beneath a laser-induced bubble, it is hypothesized that the forming jet, upon bubble implosion, will proceed to penetrate through the hole to the other side and that it may be utilized in useful applications such as precise surgeries. It was found that the growth of the bubble induced a fast flow through the hole and lead to the formation of secondary hydrodynamic cavitation. The experiments also showed the formation of a counter jet directed away from the hole and into the bubble. During the growth phase of the bubble, and near the point of maximumexpansion, the bubble wall bulged out toward the hole in a 'bulb' like formation, which sometimes resulted in the pinching-off of a secondary small bubble. This was ensued by the inward recoiling of the primary bubble wall near the pinch-off spot, which developed into a counter jet seen tomove away from the hole and inward into the bubble. © Springer-Verlag Berlin Heidelberg 2012. |
| dc.format.extent | |
| dc.language | English |
| dc.publisher | NEW YORK |
| dc.relation.ispartof | Publication Name: Experiments in Fluids; Publication Year: 2013; Volume: 54; no. 1; |
| dc.relation.ispartofseries | |
| dc.relation.uri | |
| dc.source | Scopus |
| dc.subject.other | |
| dc.title | The microjetting behavior from single laser-induced bubbles generated above a solid boundary with a through hole |
| dc.type | Article |
| dc.contributor.affiliation | Abboud, J.E., Department of Mechanical Engineering, American University of Beirut, P.O. Box 11-0236, Beirut 1107 2020, Lebanon |
| dc.contributor.affiliation | Oweis, G.F., Department of Mechanical Engineering, American University of Beirut, P.O. Box 11-0236, Beirut 1107 2020, Lebanon |
| dc.contributor.authorAddress | Oweis, G.F.; Department of Mechanical Engineering, American University of Beirut, P.O. Box 11-0236, Beirut 1107 2020, Lebanon; email: goweis@aub.edu.lb |
| dc.contributor.authorCorporate | University: American University of Beirut; Faculty: Faculty of Engineering and Architecture; Department: Mechanical Engineering; |
| dc.contributor.authorDepartment | Mechanical Engineering |
| dc.contributor.authorDivision | |
| dc.contributor.authorEmail | goweis@aub.edu.lb |
| dc.contributor.faculty | Faculty of Engineering and Architecture |
| dc.contributor.authorInitials | Abboud, JE |
| dc.contributor.authorInitials | Oweis, GF |
| dc.contributor.authorOrcidID | |
| dc.contributor.authorReprintAddress | Oweis, GF (reprint author), Amer Univ Beirut, Dept Mech Engn, POB 11-0236, Beirut 11072020, Lebanon. |
| dc.contributor.authorResearcherID | |
| dc.contributor.authorUniversity | American University of Beirut |
| dc.description.cited | BLAKE JR, 1993, J FLUID MECH, V255, P707, DOI 10.1017-S0022112093002654; Blake R., 1987, ANNU REV FLUID MECH, V19, P99; Brennen C. E., 1995, CAVITATION BUBBLE DY; Brennen CE, 2002, J FLUID MECH, V472, P153, DOI 10.1017-S0022112002002288; Brujan EA, 2001, J FLUID MECH, V433, P251; Chen H., 2009, J ACOUST SOC AM, V125, P2680; Chen YH, 2008, PHYS REV E, V77, DOI 10.1103-PhysRevE.77.026304; Choi J, 2009, J FLUID MECH, V624, P255, DOI 10.1017-S0022112008005430; Choi JK, 2004, PHYS FLUIDS, V16, P2411, DOI 10.1063-1.1740771; Fletcher DA, 2001, APPL PHYS LETT, V78, P1933, DOI 10.1063-1.1357452; Fong SW, 2009, EXP FLUIDS, V46, P705, DOI 10.1007-s00348-008-0603-4; Franc JP, 1995, CAVITATION MECANISME; Gharib M, 1998, J FLUID MECH, V360, P121, DOI 10.1017-S0022112097008410; Godwin RP, 1999, P SOC PHOTO-OPT INS, V3601, P225, DOI 10.1117-12.350042; Gopalan S, 1999, J FLUID MECH, V398, P1, DOI 10.1017-S0022112099006072; Honl M, 2003, BIO-MED MATER ENG, V13, P317; Ida M, 2009, PHYS REV E, V79, DOI 10.1103-PhysRevE.79.016307; Johnsen E, 2008, J ACOUST SOC AM, V124, P2011, DOI 10.1121-1.2973229; Karri B, 2011, SENSOR ACTUAT A-PHYS, V169, P151, DOI 10.1016-j.sna.2011.04.015; Khoo BC, 2005, SENSOR ACTUAT A-PHYS, V118, P152, DOI 10.1016-j.sna.2004.08.008; Kodama T, 1997, PHYS MED BIOL, V42, P2355, DOI 10.1088-0031-9155-42-12-004; Krieger JR, 2005, J ACOUST SOC AM, V118, P2961, DOI 10.1121-1.2047147; LAUTERBORN W, 1975, J FLUID MECH, V72, P391, DOI 10.1017-S0022112075003448; Lauterborn W, 1997, ULTRASON SONOCHEM, V4, P65, DOI 10.1016-S1350-4177(97)00009-6; Leighton TG, 1994, ACOUSTIC BUBBLE; Lew KSF, 2007, SENSOR ACTUAT A-PHYS, V133, P161, DOI 10.1016-j.sna.2006.03.023; Miller JM, 2003, ARCH OPHTHALMOL-CHIC, V121, P871, DOI 10.1001-archopht.121.6.871; Oweis GF, 2005, PHYS FLUIDS, V17, DOI 10.1063-1.1834916; Oweis GF, 2004, J ACOUST SOC AM, V115, P1049, DOI 10.1121-1.1646402; Pavard D, 2009, PHYS FLUIDS, V21, DOI 10.1063-1.3211132; Philipp A, 1998, J FLUID MECH, V361, P75, DOI 10.1017-S0022112098008738; Popinet S, 2002, J FLUID MECH, V464, P137, DOI 10.1017-S002211200200856X; Rattray M., 1951, THESIS CALTECH; RAU HG, 1995, SURG ENDOSC-ULTRAS, V9, P1009; Shervani-Tabar MT, 2011, J ENG MATH, V71, P349, DOI 10.1007-s10665-011-9456-6; Siegman AE, 1986, LASERS; Tomita Y, 2002, J FLUID MECH, V466, P259, DOI 10.1017-S0022112002001209; Tomita Y, 2003, J APPL PHYS, V94, P2809, DOI 10.1063-1.1594277; TOMITA Y, 1990, APPL PHYS LETT, V57, P234, DOI 10.1063-1.103726; Wilhelm FH, 1999, OPHTHALMOLOGE, V96, P640, DOI 10.1007-s003470050466; Xing T, 2005, J FLUID ENG-T ASME, V127, P714, DOI 10.1115-1.1976742 |
| dc.description.citedCount | |
| dc.description.citedTotWOSCount | 0 |
| dc.description.citedWOSCount | 0 |
| dc.format.extentCount | 1 |
| dc.identifier.articleNo | 1438 |
| dc.identifier.coden | EXFLD |
| dc.identifier.pubmedID | |
| dc.identifier.scopusID | 84871682597 |
| dc.identifier.url | |
| dc.publisher.address | 233 SPRING ST, NEW YORK, NY 10013 USA |
| dc.relation.ispartofConference | |
| dc.relation.ispartofConferenceCode | |
| dc.relation.ispartofConferenceDate | |
| dc.relation.ispartofConferenceHosting | |
| dc.relation.ispartofConferenceLoc | |
| dc.relation.ispartofConferenceSponsor | |
| dc.relation.ispartofConferenceTitle | |
| dc.relation.ispartofFundingAgency | |
| dc.relation.ispartOfISOAbbr | Exp. Fluids |
| dc.relation.ispartOfIssue | 1 |
| dc.relation.ispartOfPart | |
| dc.relation.ispartofPubTitle | Experiments in Fluids |
| dc.relation.ispartofPubTitleAbbr | Exp Fluids |
| dc.relation.ispartOfSpecialIssue | |
| dc.relation.ispartOfSuppl | |
| dc.relation.ispartOfVolume | 54 |
| dc.source.ID | WOS:000318153700020 |
| dc.type.publication | Journal |
| dc.subject.otherAuthKeyword | |
| dc.subject.otherChemCAS | |
| dc.subject.otherIndex | Bubble wall |
| dc.subject.otherIndex | Cleaning effect |
| dc.subject.otherIndex | Counter-jet |
| dc.subject.otherIndex | Experimental investigations |
| dc.subject.otherIndex | Flowthrough |
| dc.subject.otherIndex | Growth phase |
| dc.subject.otherIndex | High velocity |
| dc.subject.otherIndex | Hydrodynamic cavitations |
| dc.subject.otherIndex | Industrial cleaning |
| dc.subject.otherIndex | Laser induced bubbles |
| dc.subject.otherIndex | Micro-jet |
| dc.subject.otherIndex | Pinchoff |
| dc.subject.otherIndex | Single cavity |
| dc.subject.otherIndex | Solid boundaries |
| dc.subject.otherIndex | Through hole |
| dc.subject.otherIndex | Lasers |
| dc.subject.otherIndex | Laser produced plasmas |
| dc.subject.otherKeywordPlus | INDUCED CAVITATION BUBBLES |
| dc.subject.otherKeywordPlus | VORTEX CAVITATION |
| dc.subject.otherKeywordPlus | RIGID BOUNDARY |
| dc.subject.otherKeywordPlus | WATER-JET |
| dc.subject.otherKeywordPlus | COLLAPSE |
| dc.subject.otherKeywordPlus | DYNAMICS |
| dc.subject.otherKeywordPlus | OSCILLATION |
| dc.subject.otherKeywordPlus | INCEPTION |
| dc.subject.otherKeywordPlus | SURFACES |
| dc.subject.otherKeywordPlus | SURGERY |
| dc.subject.otherWOS | Engineering, Mechanical |
| dc.subject.otherWOS | Mechanics |
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