Abstract
Nature has created ways of reducing drag in fluid flow, evident in the efficient movement of fish, dolphins, and sharks. The mucus secreted by fish causes a reduction in drag as they move through water, protects the fish from abrasion by making the fish slide across objects rather than scrape, and prevents disease by making the surface of the fish difficult for microscopic organisms to adhere to (Shephard, 1994). [Accumulation of unwanted biological matter on surfaces with biofilms created by microorganisms is referred to as biofouling (Bixler and Bhushan, 2012).] It has been known for many years that by adding as little as a few hundred parts per million guar, a naturally occurring polymer, friction in pipe flow, can be reduced by up to two thirds. Other synthetic polymers provide an even larger benefit (Hoyt, 1975). The compliant skin of the dolphin has also been studied for drag-reducing properties. By responding to the pressure fluctuations across the surface, a compliant material on the surface of an object in a fluid flow has been shown to be beneficial. Though early studies showed dramatic drag reduction benefits, later studies have only been able to confirm 7% drag reduction (Choi et al., 1997).
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Bechert DW, Hoppe G, Reif WE (1985) On the drag reduction of the shark skin. In: Paper presented at AIAA Shear Flow Control Conference, Boulder, CO, Paper # AIAA-85-0564, AIAA, New York
Bechert DW, Bartenwerfer M, Hoppe G, Reif W-E (1986) Drag reduction mechanisms derived from shark skin. In: Proceedings of 15th ICAS congress, vol 2 (A86-48-97624-01), Paper # ICAS-86-1.8.3. AIAA, New York, pp 1044–1068
Bechert DW, Hoppe G (1985) On the drag reduction of the shark skin. Paper presented at AIAA Shear Flow Control Conference, Boulder, CO, March 12–14 Mar 1985, # AIAA-85–0564
Bechert DW, Bartenwerfer M, Hoppe G, Reif W-E (1986) Drag Reduction mechanisms derived from shark skin. In: Proceedings of 15th ICAS congress, vol 2 (A86–48–97624–01), pp 1044–1068, AIAA, New York, Paper # ICAS-86-1.8.3
Bechert DW, Hoppe G, van der Hoven JGTh, Makris R (1992) The Berlin oil channel for drag reduction research. Exp Fluids 12:251–260
Bechert DW, Bruse M, Hage W, Meyer R (1997a) Biological surfaces and their technological application—laboratory and flight experiments on drag reduction and separation control. Paper presented at AIAA 28th Fluid Dynamics Conference, Snowmass Village, CO, AIAA, New York, # AIAA-1997–1960
Bechert DW, Bruse M, Hage W, van der Hoeven JGTh, Hoppe G (1997b) Experiments on drag reducing surfaces and their optimization with an adjustable geometry. J Fluid Mech 338:59–87
Bechert DW, Bruse M, Hage W (2000a) Experiments with three-dimensional riblets as an idealized model of shark skin. Exp Fluids 28:403–412
Bechert DW, Bruse M, Hage W, Meyer R (2000b) Fluid mechanics of biological surfaces and their technological application. Naturwissenschaften 87:157–171
Bixler GD, Bhushan B (2012) Biofouling: lessons from nature. Philos Trans R Soc A 370:2381–2417
Blevins RD (1984) Applied fluid dynamics handbook. Van Nostrand Reinhold, New York
Carman ML, Estes TG, Feinburg AW, Schumacher JF, Wilkerson W, Wilson LH, Callow ME, Callow JA, Brennan AB (2006) Engineered antifouling microtopographies—correlating wettability with cell attachment. Biofouling 22:11–21
Choi KS, Gadd GE, Pearcey HH, Savill AM, Svensson S (1989) Tests of drag-reducing polymer coated on a riblet surface. Appl Sci Res 46:209–216
Choi KS, Yang X, Clayton BR, Glover EJ, Altar M, Semenov BN, Kulik VM (1997) Turbulent drag reduction using compliant surfaces. Proc R Soc A 453:2229–2240
Coles D (1978) A model for flow in the viscous sublayer. In: Smith CR, Abbott DE (eds) Proceedings of the workshop on coherent structure of turbulent boundary layers. ehigh University, Bethlehem, PA, pp 462–475
Daniel TL (1981) Fish mucus: in situ measurements of polymer drag reduction. Biol Bull 160: 376–382
Dean BD, Bhushan B (2010) Shark-skin surfaces for fluid-drag reduction in turbulent flow: a review. Philos Trans R Soc A 368:4775–4806
Dean BD, Bhushan B (2012) The effect of riblets in rectangular duct flow. Appl Surf Sci 258:3936–3947
Denkena B, de Leon L, Wang B (2009) Grinding of microstructures functional surfaces: a novel strategy for dressing of microprofiles. Prod Eng 3:41–48
Enyutin GV, Lashkov YuA, Samoilova NV (1995) Drag reduction in riblet-lined pipes. Fluid Dyn 30:45–48
Frings B (1988) Heterogeneous drag reduction in turbulent pipe flows using various injection techniques. Rheol Acta 27:92–110
Genzer J, Efimenko K (2006) Recent developments in superhydrophobic surfaces and their relevance to marine fouling: a review. Biofouling 22:339–360
Goldstein D, Handler R, Sirovich L (1995) Direct numerical simulation of turbulent flow over a modeled riblet covered surface. J Fluid Mech 302:333–376
Han M, Huh JK, Lee SS, Lee S (2002) Micro-Riblet film for drag reduction. In: Proceedings of the Pacific Rim workshop on transducers and micro/nano technologies, Xiamen, China
Hoyt JW (1975) Hydrodynamic drag reduction due to fish slimes. In: Swimming and flying in nature, vol 2. Plenum, New York, pp 653–672
Jones OC (1976) An improvement in the calculation of turbulent friction in rectangular ducts. J Fluids Eng 98:173–180
Jung YC, Bhushan B (2010) Biomimetic structures for fluid drag reduction in laminar and turbulent flows. J Phys Condens Matter 22:035104
Kesel A, Liedert R (2007) Learning from nature: non-toxic biofouling control by shark skin effect. Comp Biochem Physiol A 146:S130
Kline SJ, Reynolds WC, Schraub FA, Runstadler PW (1967) The structure of turbulent boundary layers. J Fluid Mech 30:741–773
Klocke F, Feldhaus B, Mader S (2007) Development of an incremental rolling process for the production of defined Riblet surface structures. Prod Eng 1:233–237
Koury E, Virk PS (1995) Drag reduction by polymer solutions in a Riblet-lined pipe. Appl Sci Res 54:323–347
Krieger K (2004) Do pool sharks really swim faster? Science 305:636–637
Lang AW, Motta P, Hidalgo P, Westcott M (2008) Bristled shark skin: a microgeometry for boundary layer control? Bioinspir Biomim 3:1–9
Lee SJ, Choi YS (2008) Decrement of spanwise vortices by a drag-reducing Riblet surface. J Turbulence 9:1–15
Lee S-J, Lee S-H (2001) Flow field analysis of a turbulent boundary layer over a Riblet surface. Exp Fluids 30:153–166
Liu KN, Christodoulou C, Riccius O, Joseph DD (1990) Drag reduction in pipes lined with riblets. AIAA J 28:1697–1699
Maali A, Bhushan B (2008) Nanorheology and boundary slip in confined liquids using atomic force microscopy. J Phys Condes Matter 20:315201
Maali A, Wang Y, Bhushan B (2009) Evidence of the no-slip boundary condition of water flow between hydrophilic surfaces using atomic force microscopy. Langmuir 25:12002–12005
Marentic FJ, Morris TL (1992) Drag reduction article. United States Patent, No. 5,133,516
Munson B, Young D, Okiishi T (2005) Fundamentals of fluid mechanics, 5th edn. Wiley, New York
Ou J, Perot B, Rothstein JP (2004) Laminar drag reduction in microchannels using ultrahydrophobic surfaces. Phys Fluids 16:4635–4643
Ralston E, Swain G (2009) Bioinspiration – the solution for biofouling control? Bioinspir Biomim 4:1–9
Reif W-E (1985) Squamation and ecology of sharks, vol 78. Courier Forschungsinstitut Senckenberg, Frankfurt, pp 1–255
Robinson SK (1991) The kinematics of turbulent boundary layer structure. NASA TM 103859, NASA, Washington, DC
Rohr JJ, Anderson GW, Reidy LW, Hendricks EW (1992) A comparison of the drag-reducing benefits of Riblets in internal and external flows. Exp Fluids 13:361–368
Schumacher JF, Aldred N, Callow ME, Finlay JA, Callow JA, Clare AS, Brennan AB (2007) Species-specific engineered antifouling topographies: correlations between the settlement of algal zoospores and barnacle cyprids. Biofouling 23:307–317
Shephard KL (1994) Functions for fish mucus. Rev Fish Biol Fish 4:401–429
Walsh MJ (1980) Drag characteristics of V-groove and transverse curvature riblets. Visc Flow Drag Reduct 72:169–184
Walsh MJ (1982) Turbulent boundary layer drag reduction using riblets. Paper presented at AIAA 20th aerospace sciences meeting, Orlando, FL, AIAA, New York, Paper # AIAA-82–0169
Walsh MJ, Anders JB (1989) Riblet/LEBU research at NASA Langley. Appl Sci Res 46:255–262
Walsh MJ, Lindemann AM (1984) Optimization and application of riblets for turbulent drag reduction. Paper presented at AIAA 22nd aerospace sciences meeting, Reno, NV, AIAA, New York, Paper # AIAA-84–0347
Wang Y, Bhushan B (2010) Boundary slip and nanobubble study in micro/nanofluidic using atomic force microscopy. Soft Matter 6:29–66
Wang Y, Bhushan B, Maali A (2009) Atomic force microscopy measurement of boundary slip on hydrophilic, hydrophobic, and superhydrophobic surfaces. J Vac Sci Technol A 27:754–760
Weiss MH (1997) Implementation of drag reduction techniques in natural gas pipelines. Paper presented at 10th European drag reduction working meeting, Berlin, Germany, 19–21 Mar 1997
Wilkinson SP (1983) Influence of wall permeability on turbulent boundary-layer properties. Paper presented at 21st aerospace sciences meeting of the american institute of aeronautics and astronautics, Reno, NV, 10–13 Jan 1983, Paper # AIAA 83–0294
Wilkinson SP, Lazos BS (1988) Direct drag and hot-wire measurements on thin-element riblet arrays. In: Liepman HW, Narasimha R (eds) Proceedings of Turbulence Management and Relaminarization. Springer, Berlin
Wilkinson SP, Anders JB, Lazos BS, Bushnell DM (1988) Turbulent drag reduction research at NASA Langley: progress and plans. Int J Heat Fluid Flow 9:266–277
Xin H, Zhang D (2008) Study on the micro-replication of shark skin. Sci China Ser E Technol Sci 51:890–896
Zhu Y, Granick S (2001) Rate-dependent slip of Newtonian liquid at smooth surfaces. Phys Rev Lett 87:096105
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Bhushan, B. (2012). Shark skin Surface for Fluid-Drag Reduction in Turbulent Flow. In: Biomimetics. Biological and Medical Physics, Biomedical Engineering. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-25408-6_10
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