Rheology of Complex Fluids
Klingenberg Group

Publications

ARTICLES

  1. The influence of polymer adsorption, and fiber composition, on the rheology of aqueous suspensions of aspen, cotton, and corn stover pulps, J. R. Samaniuk, C. T. Scott, T.WRoot, and D. J. Klingenberg, Biomass and Bioenergy, 103, 47-54 (2017). [link]
  2. A jamming-like mechanism of yield-stress increase caused by addition of nonmagnetizable particles to magnetorheological suspensions, B. T. Wilson and D. J. Klingenberg, J. Rheol., 61(4), 601–611 (2017). [link]
  3. Rheometry of coarse biomass at high temperature and pressure, D. J. Klingenberg, T. W. Root, S. Burlawar, C. T. Scott, K. Bourne, R. Gleisner, C. Houtman, and V. Subramaniam, Biomass and Bioenergy, 99, 69–78 (2017). [link]
  4. Effects of nonmagnetizable particles on the structure of magnetorheological fluids, B. T. Wilson, and D. J. Klingenberg, Current Smart Materials 1, 35–48 (2016). [link]
  5. Model magnetorheology: a direct comparative study between theories, particle-level simulations and experiments, in steady and dynamic oscillatory shear, J. A. Ruiz-Lopez, J. C. Fernandez-Toledano, D. J. Klingenberg, R. Hidalgo-Alvarez, J. de Vicente, J. Rheol., 60, 61–74 (2016). [link]
  6. Effects of process variables on the yield stress of rheologically modified biomass, J. R. Samaniuk, C. T. Scott, T.W. Root, and D. J. Klingenberg, Rheol. Acta, 54, 941-949 (2015). [link]
  7. Shear-induced diffusion in dilute curved fiber suspensions in simple shear flow, J. Wang, M. D. Graham and D. J. Klingenberg, Phys. Fluids, 26, 033301 (2014). [link]
  8. Measuring the volume charge in dielectric films using single frequency electro-acoustic waves, Dong Pei, Yuri Shkel, Daniel J. Klingenberg, Zakai Segal, Yoshio Nishi, and J. L. Shohet, J. Mater. Res., 29, 501–508 (2014). [link]
  9. A novel rheometer design for yield stress fluids, J. R. Samaniuk, T. W. Shay, T. W. Root, Daniel J. Klingenberg, and C.T. Scott, AIChE J., 60, 1523–1528 (2014). [link]
  10. Multicomponent diffusion-a brief history, R. Byron Bird and Daniel J. Klingenberg, Adv. Water Resources, 62, 238–242 (2013).
  11. Flipping, scooping, and spinning: Drift of rigid curved nonchiral fibers in simple shear flow, J. Wang, E. J. Tozzi, M. D. Graham, and D. J. Klingenberg, Phys. Fluids, 24, 123304 (2012). [link]
  12. Combined effects of nanotube aspect ratio and shear rate on the carbon nanotube/polymer composites, A. E. Eken, E. J. Tozzi, D. J. Klingenberg,W. Bauhofer, Polymer, 53, 4493-4500 (2012). [link]
  13. Rheological modification of corn stover biomass at high solids concentrations, J. R. Samaniuk, C. T. Scott, T. W. Root, and D. J. Klingenberg, J. Rheol., 56, 649–665 (2012). [link]
  14. A simulation study on the effects of shear flow on the microstructure and electrical properties of carbon nanotube/polymer composites A. E. Eken, E. J. Tozzi, D. J. Klingenberg andW. Bauhofer, Polymer, 52 5178–5185 (2011). [link]
  15. Rheology and extrusion of high-solids biomass, C. T. Scott, J. R. Samaniuk and D. J. Klingenberg, TAPPI J., 10, 47–53 (2011). [link]
  16. Rheology of concentrated biomass, J. R. Samaniuk, J. Wang, T. W. Root, C. T. Scott and D. J. Klingenberg, Korea-Australia Rheology Journal, 23, 237–245 (2011). [link]
  17. Settling dynamics of asymmetric rigid fibers, E. J. Tozzi, C. T. Scott, D. Vahey and D. J. Klingenberg, Phys. Fluids, 23,033301 (2011). [link]
  18. A simulation study on the combined effects of nanotube shape and shear flow on the electrical percolation thresholds of carbon nanotube/polymer composites, A. E. Eken, E. J. Tozzi, D. J. Klingenberg and W. Bauhofer, J. Appl. Phys., 109, 084342 (2011). [link]
  19. Enhancing Magnetorheology, D. J. Klingenberg and J. C. Ulicny, Int. J. Mod. Phys. B., 25, 911-917 (2011).
  20. Magnetorheological fluids: A review, J. de Vicente, D. J. Klingenberg and R. Hidalgo-Alvarez, SoftMatter, 7, 3701–3710 (2011). [link]
  21. Steady shear magnetorheology of inverse ferrofluids, J. Ramos, D. J. Klingenberg, R. Hidalgo-Alvarez and J. de Vicente, J. Rheol., 55, 127–152 (2011). [link]
  22. The effect of high intensity mixing on the enzymatic hydrolysis of concentrated cellulose fiber suspensions, J. R. Samaniuk, C. T. Scott, T. W. Root and D. J. Klingenberg, Bioresource Technology, 102, 4489-4494 (2011). [link]
  23. Shear-controlled electrical conductivity of carbon nanotubes networks suspended in low and high molecular weight liquids, W. Bauhofer, S. C. Schulz, A. E. Eken, E. J. Tozzi, D. J. Klingenberg, T. Skipa, D. Lellinger and I. Alig, Polymer, 51, 5024–5027 (2010). [link]
  24. Enhancing magnetorheology with nonmagnetizable particles, J. C. Ulicny, K. S. Snavely, M. A. Golden and D. J. Klingenberg, Appl. Phys. Lett., 96, 231903 (2010). [link]
  25. Effects of nonmagnetic interparticle forces on magnetorheological fluids, D. J. Klingenberg, C. H. Olk, M. A. Golden and J. C. Ulicny, J. Phys.: Cond. Matter, 22, 324101 (2010). [link]
  26. Rheology of dilute acid hydrolyzed corn stover at high solids concentration,M. R. Ehrhardt, T. O. Monz, T. W. Root, R.K. Connelly, C. T. Scott, D. J. Klingenberg, Appl. Biochem. Biotechnol., 160, 1102-1115 (2010). [link]
  27. Rheology measurements of a biomass slurry: an inter-laboratory study, J. J. Stickel, J. S. Knutsen, M. W. Liberatore, W. Luu, D. W. Bousfield, D. J. Klingenberg, C. T. Scott, T. W. Root, M. Ehrhardt and T. O. Monz, Rheol. Acta, 48, 1005–1015 (2009). [link]
  28. Iron oxidation and its impact on MR behavior, S. R. Sunkara, T. W. Root, D. J. Klingenberg and J. C. Ulicny, J. Phys.: Conf. Ser., 149, 012081 (2009). [link]
  29. Effects of nonmagnetic interparticle forces on magnetorheological fluids, D. J. Klingenberg, C. K. Olk, M. A. Golden and J. C. Ulicny, J. Phys.: Conf. Ser., 149, 012063 (2009). [link]
  30. Correlation of fiber shape measures with suspension properties, E. J. Tozzi, D. J. Klingenberg and C. T. Scott, Nord. Pulp Pap. Res. J., 23, 369–373 (2008). [link]
  31. Transient behavior of electrorheological fluids in shear flow, D. Kittipoomwong, D. J. Klingenberg, Y. M. Shkel, J. F. Morris and J. C. Ulicny, J. Rheol., 52, 225–241 (2008). [link]
  32. Mason numbers for magnetorheology, D. J. Klingenberg, J. C. Ulicny and M. A. Golden, J. Rheol., 51, 883–893 (2007). [link]
  33. Simulated strength of wet fibre networks, P. P. J.Miettinen, J. A. Ketoja, D. J. Klingenberg, J. Pulp Pap. Sci., 33, 198–205 (2007).
  34. Effects of body forces on the structure and rheology of ER and MR fluids, D. J. Klingenberg, J. C. Ulicny and A. L. Smith, Int. J. Mod. Phys. B, 21, 4841–4848 (2007). [link]
  35. Simulations of magnetorheological suspensions in Poiseuille flow, G. M. Pappas and D. J. Klingenberg, Rheol. Acta, 45, 621–629 (2006). [link]
  36. Thermal transport in sheared electro- and magnetorheological fluids, M. Heine, J. de Vicente, and D. J. Klingenberg, Phys. Fluids, 18, 023301 (2006). [link]
  37. Dynamic yield stress enhancement in bidisperse magnetorheological fluids, D. Kittipoomwong, D. J. Klingenberg, and J. C. Ulicny, J. Rheol., 49, 1521–1538 (2005). [link]
  38. Effects of body forces on electro- and magnetorheological fluids, D. J. Klingenberg, J. C. Ulicny, and A. Smith, Appl. Phys. Lett., 86, 104101 (2005). [link]
  39. Transient response of magnetorheological fluids: shear flow between concentric cylinders, J. C. Ulicny, M. A. Golden, C. S. Namuduri and D. J. Klingenberg, J. Rheol., 49, 87–104 (2005). [link]
  40. Nonlocal electrostatics in heterogeneous suspensions using a point-dipole model, Karl von Pfeil and Daniel J. Klingenberg, J. Appl. Phys., 96, 5341–5348 (2004). [link]
  41. Handsheet formation and mechanical testing via fiber-level simulations, L. H. Switzer III, C. T. Scott and D. J. Klingenberg, Nordic Pulp Pap. Res. J., 19, 418–423 (2004). [link]
  42. Flocculation in simulations of sheared fiber suspensions, L. H. Switzer III and D. J. Klingenberg, Int. J. Mult. Flow, 30, 67–87 (2004). [link]
  43. Simulations of fiber floc dispersion in linear flow fields, L. H. Switzer III and D. J. Klingenberg, Nordic Pulp Pap. Res. J., 18, 141–144 (2003). [link]
  44. Rheology of sheared flexible fiber suspensions via fiber-level simulations, L. H. Switzer III and D. J. Klingenberg, J. Rheol., 47, 759–778 (2003). [link]
  45. Structure evolution in electrorheological and magnetorheological suspensions from a continuum perspective, K. von Pfeil, M. D. Graham, D. J. Klingenberg and J. F. Morris, J. Appl. Phys., 93, 5769–5779 (2003). [link]
  46. Pattern formation in flowing electrorheological fluids, K. von Pfeil, M. D. Graham, D. J. Klingenberg and J. F. Morris, Phys. Rev. Lett., 88, 188301 (2002). [link]
  47. A two-fluid model of electro- and magnetorheological suspensions, K. von Pfeil, M. D. Graham, D. J. Klingenberg and J. F. Morris, Int. J. Mod. Phys. B, 16 2669–2675 (2002)
  48. Simulation of bidisperse magnetorheological fluids, D. Kittipoomwong, D. J. Klingenberg and J. C. Ulicny, Int. J. Mod. Phys. B, 16, 2732–2738 (2002). [link]
  49. Determination of rheological and magnetic properties for magnetorheological composites via shear magnetization measurements, A. T. Horvath, D. J. Klingenberg, and Y. M. Shkel, Int. J. Mod. Phys. B, 16, 2690–2696 (2002). [link]
  50. A thermodynamic approach to field-induced stresses in electro- and magnetoactive composites, Y. M. Shkel and D. J. Klingenberg, Int. J. Mod. Phys. B, 15, 795–802 (2001). [link]
  51. Probing aspects of nonlinear conduction in electrorheological suspensions, P. J. Rankin, Y. M. Shkel, D. J. Klingenberg and J. L. Shohet, Int. J. Mod. Phys. B, 15, 965–972 (2001). [link]
  52. Magnetorheology and magnetostriction of isolated chains of nonlinearly magnetizable spheres, Y. M. Shkel and D. J. Klingenberg, J. Rheol., 45, 351–368 (2001). [link]
  53. Friction between cellulose surfaces measured with colloidal probe microscopy, S. Zauscher and D. J. Klingenberg, Coll. Surf. A, 178, 213–229 (2001). [link]
  54. Surface and friction forces between cellulose surfaces measured with colloidal probe microscopy, S. Zauscher and D. J. Klingenberg, Nordic Pulp and Paper Research Journal, 15, 459–468 (2001). [link]
  55. Magnetic and elastic properties of a structured magnetic fluid, V. A. Naletova, V. V. Kiryushin, V. A. Turkov, Y. M. Shkel, and D. J. Klingenberg, Magnetohydrodynamics, 37(1,2), 206–214 (2001).
  56. Magnetorheology: Applications and challenges, D. J. Klingenberg, invited article, AIChE J., 47, 246–249 (2001).
  57. Normal forces between cellulose surfaces measured with colloidal probe microscopy, S. Zauscher and D. J. Klingenberg, J. Coll. Int. Sci., 229, 497–510 (2000). [link]
  58. Simulation of fiber flocculation: Effects of fiber properties and interfiber friction, C. F. Schmid, L. H. Switzer and D. J. Klingenberg, J. Rheol., 44, 781–809 (2000). [link]
  59. Properties of fiber flocs with frictional and attractive interfiber forces, C. F. Schmid and D. J. Klingenberg, J. Coll. Int. Sci., 226, 136–144 (2000). [link]
  60. Mechanical flocculation in flowing fiber suspensions, C. F. Schmid and D. J. Klingenberg, Phys. Rev. Lett., 84, 290–293 (2000). [link]
  61. Pulp extrusion at ultra-high consistencies: A new processing method for recycling wastepapers and papermill sludges, S. Zauscher, C. T. Scott, J. L. Willet and D. J. Klingenberg, TAPPI J., 83, 62 (2000).
  62. Magnetorheology in viscoplastic media, P. J. Rankin, A. T. Horvath and D. J. Klingenberg, Rheol. Acta, 38, 471–477 (1999). [link]
  63. A continuum approach to electrorheology, Y. M. Shkel and D. J. Klingenberg, J. Rheol., 43, 1307–1322 (1999). [link]
  64. Model of a magnetizable elastic material, V. A. Naletova , V. A. Turkov, Y.M. Shkel and D. J. Klingenberg, J.Magnetism and Magnetic Mat., 202(2-3), 570–573 (1999).
  65. Large amplitude oscillatory shear of electrorheological suspensions, M. Parthasarathy and D. J. Klingenberg, J. Non-Newt. Fluid Mech., 81, 83–104 (1999).
  66. Flow distribution in chromatographic columns, Q. S. Yuan, A. Rosenfeld, T. W. Root, D. J. Klingenberg and E. N. Lightfoot, J. Chromatography A, 831, 149–165 (1999).
  67. Simulation of flowing wood fiber suspensions, R. F. Ross and D. J. Klingenberg, J. Pulp and Paper Sci., 24, 388–392 (1998).
  68. The electrorheology of barium titanate suspensions, P. J. Rankin and D. J. Klingenberg, J. Rheol., 42, 639–656 (1998). [link]
  69. Electrostriction of polarizable media: Comparison of models with experimental data, Y. M. Shkel and D. J. Klingenberg, J. Appl. Phys., 83, 415–424 (1998); reprinted 83, 7834–7843 (1998). [link]
  70. Electro- and magneto-rheology, P. J. Rankin, J. M. Ginder and D. J. Klingenberg, invited article, Curr. Opin. Coll. Int. Sci., 3, 373–381 (1998). [link]
  71. Polarization in electrorheological suspensions, D. J. Klingenberg, invited article, Mat. Res. Soc. Bull., 23, 30–34 (1998).
  72. Simulation of single fiber dynamics, P. Skjetne, R. F. Ross and D. J. Klingenberg, J. Chem. Phys., 107, 2108–2121 (1997). [link]
  73. The nonlinear behavior of surfactant-activated electrorheological suspensions, Y. D. Kim and D. J. Klingenberg, Korean J. Chem. Eng., 14, 23–29 (1997). [link]
  74. An interfacial polarization model for activated electrorheological suspensions, Y. D. Kim and D. J. Klingenberg, Korean J. Chem. Eng., 14, 30–36 (1997). [link]
  75. Dynamic simulation of flexible fibers composed of linked rigid bodies, R. F. Ross and D. J. Klingenberg, J. Chem. Phys.,106, 2949–2960 (1997). [link]
  76. Material parameters for electrostriction, Y. M. Shkel and D. J. Klingenberg, J. Appl. Phys., 80, 4566–4572 (1996). [link]
  77. Two roles of nonionic surfactants in electrorheology, Y. D. Kim and D. J. Klingenberg, J. Coll. Int. Sci., 183, 568–578 (1996). [link]
  78. Interactions between polymer-grafted membranes in concentrated solutions of free polymer, E. Evans, D. J. Klingenberg, W. Rawicz, and F. Szoka, Langmuir, 12, 3031–3037 (1996). [link]
  79. Electrorheology: Mechanisms and models, M. Parthasarathy and D. J. Klingenberg, Mat. Sci. Eng. R, invited review paper, R17, 57–103 (1996).
  80. A microstructural investigation of the nonlinear response of electrorheological suspensions I. Start-up of steady shear flow, M. Parthasarathy and D. J. Klingenberg, Rheol. Acta, 34, 417–429 (1995).
  81. A microstructural investigation of the nonlinear response of electrorheological suspensions II. Oscillatory shear flow,M. Parthasarathy and D. J. Klingenberg, Rheol. Acta, 34, 430–439 (1995). [link]
  82. Protein enhanced electrorheological fluids, D. J. Klingenberg, P. Pakdel, B. M. Belongia, and S. Kim, Ind. Eng. Chem. Res., 34, 3303-3306 (1995). [link]
  83. Electrostatics at rough interfaces, D. J. Klingenberg and S. L. Cooper, J. Electrostatics, 35, 339-348 (1995).
  84. Surfactant-activated electrorheological suspensions, Y. D. Kim and D. J. Klingenberg, Polym. Preprints, 35(2), 389-390 (1994). [link]
  85. The role of suspension structure in the dynamic response of electrorheological suspensions, M. Parthasarathy, K. H. Ahn, B. M. Belongia, and D. J. Klingenberg, Int. J. Modern Physics B, 8, 2789 (1994). [link]
  86. Relaxation of polydisperse electrorheological suspensions, K. H. Ahn and D. J. Klingenberg, J. Rheol., 38, 713 (1994). [link]
  87. Simulation of the dynamic response of electrorheological suspensions: Demonstration of a relaxation mechanism, D. J. Klingenberg, J. Rheol., 37, 199 (1993). [link]
  88. Making fluids into solids with magnets, invited article, Scientific American, 112–113, October, 1993.
  89. Kinetics of structure formation in electrorheological suspensions, D. J. Klingenberg, C. F. Zukoski, and J. C. Hill, J. Appl. Phys., 73, 4644 (1993). [link]
  90. The small shear rate response of electrorheological suspensions I: Simulation in the point-dipole limit, D. J. Klingenberg, Frank van Swol, and C. F. Zukoski, J. Chem. Phys., 94, 6160 (1991). [link]
  91. The small shear rate response of electrorheological suspensions II: Extension beyond the point-dipole limit, D. J. Klingenberg, Frank van Swol, and C. F. Zukoski, J. Chem. Phys., 94, 6170 (1991). [link]
  92. Stress transfer mechanisms in electrorheological suspensions, D. J. Klingenberg, D. Dierking, and C. F. Zukoski, J. Chem. Soc. Faraday Trans., 87, 425 (1991). [link]
  93. Studies on the steady shear behavior of electrorheological suspensions, D. J. Klingenberg and C. F. Zukoski, Langmuir, 6, 15 (1990). [link]
  94. Dynamic simulation of electrorheological suspensions, D. J. Klingenberg, Frank van Swol, and C. F. Zukoski, J. Chem. Phys., 91, 7888 (1989). [link]

BOOKS AND BOOK CHAPTERS

  1. Introductory Transport Phenomena, R. B. Bird, W. E. Stewart, E. N. Lightfoot, and D. J. Klingenberg,Wiley, New York (2015).
  2. One-dimensional analysis of a continuum model for structure in electrorheological fluids, K. von Pfeil,M. D. Graham, D.J. Klingenberg and J. F. Morris, in “ComputationalMethods in Multiphase Flow II,” A. A. Mammoli and C. A. Brebbia, eds.,WIT Press, Southampton, 2004, pp. 275–285.
  3. Surface forces and friction between cellulose surfaces in aqueous media, S. Zauscher and D. J. Klingenberg, in “Nanotribology. Critical Assessment and Research Needs,” S. M. Hsu and Z. C. Ying, eds., Kluwer, Boston, October, 2002, Chapter 29.

PATENTS

  1. Device and method for measuring the rheological properties of a yield stress fluid, J. R. Samaniuk, D. J. Klingenberg, C.T. Scott, and T. W. Root, U.S. Patent No. 9,116,092 B2, Aug. 25, 2015.
  2. Magnetorheological fluid device, J. C. Ulicny, D. J. Klingenberg, A. L. Smith, M. A. Golden, U.S. Patent No. US 7,306,083 B2, Dec. 11, 2007.
  3. Protein-enhanced electrorheological fluids, S. Kim and D. J. Klingenberg, U. S. Patent 5,435,931 (1995).