Abstract
This review presents a series of measurements of the surface and interfacial tensions we have been able to make using the micropipette technique. These include: equilibrium tensions at the air-water surface and oil-water interface, as well as equilibrium and dynamic adsorption of water-soluble surfactants and water-insoluble and lipids. At its essence, the micropipette technique is one of capillary-action, glass-wetting, and applied pressure. A micropipette, as a parallel or tapered shaft, is mounted horizontally in a microchamber and viewed in an inverted microscope. When filled with air or oil, and inserted into an aqueous-filled chamber, the position of the surface or interface meniscus is controlled by applied micropipette pressure. The position and hence radius of curvature of the meniscus can be moved in a controlled fashion from dimensions associated with the capillary tip (~5–10 μm), to back down the micropipette that can taper out to 450 μm. All measurements are therefore actually made at the microscale. Following the Young–Laplace equation and geometry of the capillary, the surface or interfacial tension value is simply obtained from the radius of the meniscus in the tapered pipette and the applied pressure to keep it there. Motivated by Franklin’s early experiments that demonstrated molecularity and monolayer formation, we also give a brief potted-historical perspective that includes fundamental surfactancy driven by margarine, the first use of a micropipette to circuitously measure bilayer membrane tensions and free energies of formation, and its basis for revolutionising the study and applications of membrane ion-channels in Droplet Interface Bilayers. Finally, we give five examples of where our measurements have had an impact on applications in micro-surfaces and microfluidics, including gas microbubbles for ultrasound contrast; interfacial tensions for micro-oil droplets in oil recovery; surface tensions and tensions-in-the surface for natural and synthetic lung surfactants; interfacial tension in nanoprecipitation; and micro-surface tensions in microfluidics.
Highlights
In order to finish this section on the development of the micropipette techniques, we present our most recent Micropipette Interfacial Area‐expansion Method (MIAM) that has allowed us to make Dynamic Surface Tension (DST) measurements
In this review paper we have presented a series of the micropipette techniques that we have developed and used to make measurements of the surface and interfacial tensions for clean air-water surfaces and oil-water interfaces
By using a tapered micropipette and introducing rapid image monitoring of the position of meniscus in the micropipette and its radius of curvature for a given applied micropipette pressure, we have presented a series of equilibrium tensions as well as equilibrium and dynamic tensions due to the adsorption of water-soluble surfactants and water-insoluble and lipids
Summary
IntrIondthuicsticoonntribution to the Special Issue "Microscale Surface Tension and Its Applications," we give an uIpn-ttoh-idsactoenrtervibieuwtiofnrotmo 1th9e83Sp[1e]ctioalthIsesupere"sMenictrdoasyc,aolef SouurrfwaciedeTernansigoenoafnmdicItrsopAipppetlticea-tteiochnns,i"qwuees guivtielisaend ufopr-tmo-deaastue rreemvieenwts forof msur1f9a8c3e [a1n]dtointtheerfapcrieasletnetnsdiaoyn,s,ofdroouprlewt iddiessroalnugtieono,f amndicrmopoilpeceuttlea-r taedchsnoriqputieosnuitniliasierd-wfaotrerm, oeails-uwraetmere,nwtsatoefr-souirlfsaycesteamnds.inWtehriflaecitahletreenasrioenms,adnryopotlehterditsescohlnuitqioune,saanndd mmoeltehcoudlaorloagdiessorapstsioocniatiend awiri-twh amteirc,roosiul-rwfaacteesr,inwclautdeirn-ogilmsicyrsoteflmuisd. IcWtehnilseiotmheertrey,acraepimllaarnityy oofthgears tbecuhbnbilqeus,esanadndothmeerthmoidcroolotgeicehsnaiqssuoecsiaintevdolwviinthg “mLiacrpolasucerfsaecnessoirnsc”lu[2d–in5]gwmeictarokfeluthideiclibteenrtsyiotmo eltimryi,t ctahpeilslcaoriptye ooff gthaissbruevbibelwes,toanodurotohwernmstiucrdoietse.chMniicqruoepsipinevttoelsvainreg g“lLaaspslcaacpeislleanrsieosrst”ha[2t-a5r]ewceustatokme tchuet litboehrtayvteotliipmdititahmeestceorpse~o5f μthmis arenvdiecwantotaopuerroowunt sttoud45ie0s.μMmi,craonpdipseottaelsl amreegaslausrsecmaepniltlsaraieres tahcatut aarlley cmusatdoemocnustutrofahcaevaentdipindtiearmfaectiearlsm~e5nμismci,agnads cmaincrtoabpuebr boluets toor 4li5q0uiμdmm, aicnrdodsroopallletms eaatstuhreemmiecnrotsscaarlee. This historical-perspective briefly describes certain collaWboerasttiaorntst,hpoeurgsohnbayl cpornetsaecntst,inangdafrfeiewndsshhoirptsstthoartieosftbenehuinnddesrolime,eorahspaevcetesvoefnseunrafabcletadn, csyurwfaectfainncdy inRt&erDe.stIitngtakanesd/uosr ohnavae pmoattdeed cpoenrtsroibnuatliiosends tjoou. Technique for studying fundamentals of “Black Lipid Films” (BLMs) and their interfacial tension, and how this system helped to generate a new, and currently very active, field of “Droplet Interface
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