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NTIS 바로가기Korean journal of cosmetic science, v.2 no.1, 2020년, pp.33 - 46
Bae, Jung-Eun (LG Household & Health Care, E10 LG Science Park) , Ryoo, Joo-Yeon (LG Household & Health Care, E10 LG Science Park) , Kang, Nae-Gyu (LG Household & Health Care, E10 LG Science Park)
Cosmetics are representative complex fluids, and there have been many studies focusing on the correlation between the rheological properties and sensory attributes. Various instrumental measurements have been suggested to evaluate the sensory attributes, and one of the most common instruments is Tex...
L. S. Calixto, P. M. B. G. M. Campos, C. Picard, and G. Savary, Brazilian and French sensory perception of complex cosmetic formulations: a cross-cultural study, Int. J. Cosmet. Sci., 42(1), 60 (2020).
K. Timm, C. Myant, H. Nuguid, H. A. Spikes, and M. Grunze, Investigation of friction and perceived skin feel after application of suspensions of various cosmetic powders, Int. J. Cosmet. Sci., 34(5), 458 (2012).
K. Kusakari, M. Yoshida, F. Matsuzaki, T. Yanaki, H. Fukui, and M. Date, Evaluation of post-application rheological changes in cosmetics using a novel measuring device: relationship to sensory evaluation, J Cosmet Sci, 54(4), 321 (2003).
K. Nakano, K. Kobayashi, K. Nakao, R. Tsuchiya, and Y. Nagai, Tribological method to objectify similarity of vague tactile sensations experienced during application of liquid cosmetic foundations, Tribol. Int., 63, 8 (2013).
E. Gore, C. Picard, and G. Savary, Complementary approaches to understand the spreading behavior on skin of O/W emulsions containing different emollients, Colloids Surf. B, 193, 111132 (2020).
A. Tai, R. Bianchini, and J. Jachowicz, Texture analysis of cosmetic-pharmaceutical raw materials and formulations, Int. J. Cosmet. Sci., 36(4), 291 (2014).
M. Lukic, I. Jaksic, V. Krstonosic, N. Cekica, and S. Savic, A combined approach in characterization of an effective w/o hand cream: the influence of emollient on textural, sensorial and in vivo skin performance, Int. J. Cosmet. Sci., 34(2), 140 (2012).
F. Eudier, D. Hirel, M. Grisel, C. Picard, and G. Savary, Prediction of residual film perception of cosmetic products using an instrumental method and non-biological surfaces: the example of stickiness after skin application, Colloids Surf. B, 174, 181 (2019).
J. Lauger and H. Stettin, Differences between stress and strain control in the non-linear behavior of complex fluids, Rheol. Acta, 49, 909 (2010).
K. Suzuki and T. Watanabe, Relationship between sensory assessment and rheological properties of cosmetic creams, J. Texture Stud., 2(4), 431 (1971).
A. Z. Nelson and R. H. Ewoldt, Design of yield-stress fluids: a rheology-to-structure inverse problem, Soft matter, 13, 7578 (2017).
G. Tafuro, A. Costantini, G. Baratto, L. Busata, and A. Semenzato, Rheological and textural characterization of acrylic polymer water dispersions for cosmetic use, Ind. Eng. Chem. Res., 58, 23549 (2019).
S. Ozkan, T. W. Gillece, L. Senak and D. J. Moore, Characterization of yield stress and slip behavior of skin/hair care gels using steady flow and LAOS measurements and their correlation with sensorial attributes, Int. J. Cosm. Sci., 34(2), 193 (2012).
A. Zosel, Adhesive failure and deformation behavior of polymers, J. Adhes., 30, 135 (1989).
B. J. Dobraszczyk, The rheological basis of dough stickiness, J. Texture Stud., 28, 139 (1997).
Z. Yuan, J. Wang, X. Niu, J. Ma, X. Qin, L. Li, L. Shi, Y. Wu, and X. Guo, A study of the surface adhesion and rheology properties of cationic conditioning polymers, Ind. Eng. Chem. Res., 58(22), 9390 (2019).
B. Andreotti and J. H. Snoeijer, Statics and dynamics of soft wetting, Annu. Rev. Fluid Mech., 52, 285 (2020).
N. Bait, C. Derail, A. Benaboura, and B. Grassl, Rheology and adhesive properties versus structure of poly(acrylamide-co-hydroxyethyl methacrylate) hydrogels, Int. J. Adhes. Adhes., 96, 102449 (2020).
H. M. Laun and J. Meissner, A sandwich-type creep rheometer for the measurement of rheological properties of polymer melts at low shear stress, Rheol. Acta, 19, 60 (1980).
W. Philippoff, Vibrational measurements with large amplitudes, Trans. Soc. Rheol., 10, 317 (1966).
A. T. Tsai and D. S. Soong, Measurement of fast transient and steady state responses of viscoelastic fluids with sliding cylinder rheometer executing coaxial displacements, J. Rheol., 29, 1 (1985).
T. B. Goudoulas and N. Germann, Concentration effect on the nonlinear measures of dense polyethylene oxide solutions under large amplitude oscillatory shear, J. Rheol., 62, 1299 (2018).
A. J. Giacomin, R. S. Jeyaseelan, T. Samurkas, and J. M. Dealy, Validity of separable BKZ model for large amplitude oscillatory shear, J. Rheol., 37, 811 (1993).
H. M. Laun, Prediction of elastic strains of polymer melts in shear and elongation, J. Rheol., 30, 459 (1986).
F. J. Stadler, A. Leygue, H. Burhin, and C. Bailly, The potential of large amplitude oscillatory shear to gain an insight into the long-chain branching structure of polymers, Proceeding of the 235th ACS National Meeting, polymer preprints ACS, 49, 121, New Orleans, LA, USA (2008).
J. E. Bae and K. S. Cho, Semianalytical methods for the determination of the nonlinear parameter of nonlinear viscoelastic constitutive equations from LAOS data, J. Rheol., 59, 525 (2015).
R. S. Jeyaseelan and A. J. Giacomin, Network theory for polymer solutions in large amplitude oscillatory shear, J. Nonnewton. Fluid Mech., 148, 24 (2008).
R. H. Ewoldt and G. H. McKinley, On secondary loops in LAOS via self-intersection of Lissajous-Bowditch curves, Rheol. Acta, 49, 213 (2010).
K. S. Cho, K. Hyun, K. H. Ahn, and S. J. Lee, A geometrical interpretations of large amplitude oscillatory shear response, J. Rheol., 47, 747 (2005).
S. A. Rogers and M. P. Lettinga, A sequence of physical processes determined and quantified in LAOS: application to theoretical nonlinear models, J. Rheol., 56, 1 (2012).
C. R. Lopez-Barron, N. J. Wagner, and L. Porcar, Layering, melting, and recrystallization of a close-packed micellar crystal under steady and large-amplitude oscillatory shear flows, J. Rheol., 59, 793 (2015).
M. Wilhelm, D. Maring, and H. W. Spiess, Fourier-transform Rheology, Rheol. Acta, 37, 399 (1998).
M. Wilhelm, P. Reinheimer, and M. Ortseifer, High sensitivity Fourier-transform rheology, Rheol. Acta, 38, 349 (1999).
T. Neidhofer, M. Wilhelm, and B. Debbaut, Fourier-transform rheology experiments and finite-element simulations on linear polystyrene solutions, J. Rheol., 47, 1351 (2003).
R. H. Ewoldt, A. E. Hosoi, and G. H. McKinley, New measures for characterizing nonlinear viscoelasticity in large amplitude oscillatory shear, J. Rheol., 52, 1427 (2008).
J. E. Bae, M. Lee, K. S. Cho, K. H. Seo, and D. G. Kang, Comparison of stress-controlled and strain-controlled rheometers for large amplitude oscillatory shear, Rheol. Acta, 52, 841 (2013).
K. S. Cho, K. W. Song, and G. S. Chang, Scaling relations in nonlinear viscoelastic behavior of aqueous PEO solutions under large amplitude oscillatory shear flow, J. Rheol., 54, 27 (2010).
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