Abstract
Mixed micellization study of cationic surfactants viz. alkyltrimethylammonium bromides (CnTAB) and alkyltriphenylphosphonium bromides (CnTPPB) with similar hydrophobic groups (C12-, C14-, and C16-) was performed using tensiometry and UV–visible light spectrophotometry techniques. Critical micelle concentration (CMC) values of the single and binary surfactant mixtures were obtained from a plot of surface tension versus the logarithm of surfactant concentration (C s). The degree of synergy and various mixed micelle parameters like interaction parameter (β), activity coefficients (f m) and interfacial parameters like surface pressure (π CMC), packing parameter (P), surface excess concentration (Г max), surface tension at the CMC (γ CMC), and minimum area per molecule (A min) were evaluated using the regular solution theory (RST). Thermodynamic parameters were calculated using several proposed models which suggest the mixed micellar system to be more thermodynamically stable than their respective individual components. In addition, a dye solubilization study was performed using a spectrophotometric method to validate the CMC data obtained from tensiometric method. Conductometric measurements were also carried out for the mixture of C12TAB + C12TPPB only as it showed a more negative β, indicating a higher degree of synergism.
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Introduction
Comprehensive studies on co-micellization in binary cationic surfactant mixtures are well reported [1–5]. Mixed surfactant systems are expected to give superior surface properties compared to the corresponding pure individual components. Consequently, such surfactant blends, with synergistic behavior, cost-effectiveness due to overall reduction in the total amount of surfactant used for a particular application and environmental impact, reinforces a wide variety of industrial applications [6–10]. Furthermore, such mixed micellar systems offer a better understanding of molecular interactions in surfactant aggregates and delivery systems. For all the above noted reasons, the study of mixed surfactant systems with different physico-chemical experimental techniques viz. surface/interfacial tensiometry, conductivity, spectroscopy, microscopy or scattering techniques has become increasingly important [1–13].
Thermodynamic theories proposed by Clint, Motoumura, Rubingh and Blackschtein have described the molecular details of various binary combinations and highlighted the specific synergistic (attractive)/antagonistic, i.e., repulsive, interactions between different surfactants in mixed micelles [13–16].
Binary mixtures of non-ionic surfactants are reported to exhibit ideal behavior while other surfactant pairs usually exhibit non-ideality resulting from the synergistic or antagonistic interactions between the surfactant monomers. Such behavior is attributed to electrostatic and steric interactions between hydrophilic head groups and hydrophobic tails of the respective surfactant molecules [17]. The influence of the hydrophobic chain length or different head groups on the micellization of mixtures of alkyl quaternary ammonium and alkyl pyridinium halides has been studied [17–21].
With the aim to synchronize our current research with the reported literature, we have chosen the mixture of alkyltrimethylammonium and alkyltriphenylphosphonium bromides with identical hydrophobic chain length and bromide as a counterion, but with dissimilar head groups (NH4 + and Ph3P+). Our work presents a systematic investigation on the interfacial and micellar properties of these surfactants in pure and in binary mixed systems in aqueous solution at 30 °C using tensiometry and ultraviolet–visible light (UV–vis) spectrophotometry methods. The critical micelle concentration (CMC) of these surfactants in the mixed system having different compositions was determined and the results obtained herein are explained in terms of ideality of mixing and thermodynamics. The significant influence of the head group in the micelle formation process and the contribution that comes from the hydrocarbon tails is also explained.
Experimental
Materials
Cationic surfactants alkyltrimethylammonium bromide (CnTAB) and alkyltriphenylphosphonium bromide (CnTPPB), dye (Orange OT) and a solvent (methanol, 99.8 % purity) of analytical reagent (AR) grade were procured from Sigma Aldrich. These compounds were used as received for the solubilization study. The sample solutions used in this study for the pure and the binary mixtures were prepared using Millipore water (ST = 71.4 mN m−1).
Methods
UV–visible spectrophotometry
Spectrophotometry measurements were carried out on an Evolution™ 300 UV–vis spectrophotometer (Thermo-Scientific) with a matched pair of quartz cuvets having an internal thickness of 10 mm. The dye solubilization measurements using this technique were obtained at 30 °C maintained in a water bath. The temperature environment was thoroughly controlled and maintained constant within an error limit of ±0.1 °C. Considering the solubility of the dye in a particular solvent (methanol in our case), a calibration plot is drawn within the limit of dye solubility where there is no excess insoluble dye left in the solvent system. After the calibration plot is drawn, the same dye is added in excess to various concentrations of surfactant solution. The entire system was shaken for 48 h at 30 °C to let the dye solubilize completely in the micellar solution. As far as the issue of the insoluble dye accountability is concerned, the excess insoluble dye is separated using Millipore filters (pore size of ~0.22 µm) and the filtrate is diluted with an equal volume of methanol. The concentration of the solubilized dye in the surfactant solutions was determined from the absorbance study at the wavelength of maximum absorption (λ max = 505 nm).
Tensiometry
The surface tension measurements for the single and mixed binary surfactant systems were performed on a K9 tensiometer (Krüss, Germany). Temperature was maintained constant throughout the experiments (30 °C within ±0.1 °C). Surfactant concentration was varied by adding small installments of the same in water. This solution mixture was kept for at least 30 min for equilibration before measuring the surface tension. Readings of the surface tension for aqueous solutions of single and mixed surfactant systems at different mole fractions was noted after careful mixing and temperature equilibration in order to obtain the CMC. The inflection or break point in the plot of surface tension as a function of surfactant concentration in mole/liter corresponded to the CMC value.
Air/water interface behavior of the binary surfactant mixture
Using the Gibbs adsorption equation, the surface pressure at the CMC (π CMC), maximum surface excess concentration (Г max, mol m−2), and the minimum area per molecule at the air/solution interface (A min) were calculated from Eqs. 1–3.
where \(\left( {\frac{\partial \gamma }{\partial \ln c}} \right)\) is the maximum slope, R = 8.314 J mol−1 K−1, N A is Avogadro’s number, n = 2 for monovalent counter ions and T is the absolute temperature in Kelvin [22, 23, 26, 27].
According to Rubingh’s regular solution theory for mixed micelles, the mixed CMC obtained by mixing two surfactants is given by Eq. 4:
where α 1 is the mole fraction of the first surfactant in the mixture, and C 1 and C 2 are the respective CMC values of the first and second surfactant in the mixture [13, 20].
The Clint equation [11, 20] was employed to understand the mixed micellization at varying mole fraction compositions. In this study, the experimental CMC of the pure components was related with the ideally mixed CMC and the activity coefficients f m1 and f m2 were considered to be unity. Hence Eq. 4 reduces to Eq. 5.
The strength of the interaction between the two surfactants in the mixture is denoted as β, which is determined by calculating the CMCs from the curve: surface tension (γ)-log concentration (C s) of individual surfactant and in their mixtures. Considering the phase separation model for micellization, we have employed Eq. 6 proposed by Rubingh [15]:
where X 1 is the mole fraction of surfactant 1 in the mixed micelle. Solving the equation iteratively gives the value of β, as shown in Eq. 7.
β is a measure of the degree of interaction between the surfactants resulting in their deviations from mixed micelle ideal behavior. Negative β values indicated synergism in mixed micelle formation, while positive values indicate antagonism. If β = 0, then no strong interactions are observed [26, 27].
The activity coefficients highlight the contribution of the individual component in a mixed micellar system and are directly related to the interaction parameter by Eqs. 8 and 9:
where f m1 and f m2 are the activity coefficients of TTAB and TTPPB, respectively.
The minimum surface area of surfactants at the interface can be used to predict the shape of the micelle by calculating the packing parameter, P, given by Tanford’s formula:
where volume of exclusion per monomer in the aggregate, V 0 = [27.4 + 26.9(n c − 1)] Å3 (n c is the number of carbon atoms in the hydrocarbon chain), and the maximum chain length, l c = [1.54 + 1.26(n c − 1)] Å [24, 25].
Results and Discussion
Micellization Study
Figure 1 shows the plots of surface tension (γ) versus the logarithm of surfactant concentration (C s) for mixed micellization study of cationic surfactants with identical alkyl chain lengths but with dissimilar head groups (NH4 + and Ph3P+) at 30 °C. The surface tension of single surfactant and surfactant mixtures decreases with concentration, which is a typical signature of surfactants.
A typical non-linear decrease in surface tension is observed up to the CMC, beyond which the surface tension remains more or less constant. Mixed CMC values along with the computed results for mixed micellar composition, interaction parameter (β) and activity coefficients (f m) are shown in Table 1. It was observed that the CMC values lie between those of the single conventional components, indicating good surface activity. The calculated CMC of single surfactants are in good agreement to the reported values [19, 20]. The β appeared to be more negative for the same set of mixtures, indicating strong non-ideal mixing in the blends, resulting in favorable synergism in mixed micelles. The lower mole fraction (X m1 ) value of the surfactant reflects a low activity coefficient (f m1 ) value, suggesting that the cationic surfactant in the mixed micelle is very far away from its respective standard state, while the higher values of (f m2 ) appear close to unity, which represents that CnTPPB in the mixed micelle is near its standard state. Such a noticeable trend is well reported [19, 28].
The study of interfacial adsorption is an important criterion to understand the surfactant behavior in the solution. Various parameters related to the interfacial study are presented in Table 2. It can be seen that in all surfactant mixtures, the values of surface pressure (Π CMC) appear lower than that of their corresponding pure surfactants, indicating a synergistic mixed micelle formation. The minimum area per molecule (A min) provides an insight on the assembly of the surfactant molecule at the air–water interface. It was observed that the A min value of pure CnTPPB is almost always larger than CnTAB which may be ascribed to greater electrostatic repulsions between triphenylphoshonium bromide head groups at the interface. The A min value can be used to calculate the packing parameter P which predicts the shape of the mixed micelle. Because of the inverse relationship, larger A min values predict smaller packing parameters, suggesting that the mixed micelles are roughly spherical in shape [21, 29].
Synergism
Synergism is a measure of the interaction between the individual surfactants in the mixture. Synergy can be measured for monolayer formation at the air–water interface and mixed micelle formation. The conditions required for synergy include: (a) β o and β m must be negative, (b) \(|\beta^{o} | > |\ln \, (C_{1}^{o} /C_{2}^{o} )|\), where C o1 and C o2 are the molar concentration of the individual surfactants in the binary mixture and (c) \(|\beta^{m} | > |\ln (C_{1}^{m} /C_{2}^{m} )| ,\) where C m1 and C m2 are the CMC values of the individual surfactants.
The terms: \(1 - \left( {{\raise0.7ex\hbox{${c_{{12, { \hbox{min} }}} }$} \!\mathord{\left/ {\vphantom {{c_{{12, { \hbox{min} }}} } {c_{1}^{o} }}}\right.\kern-0pt} \!\lower0.7ex\hbox{${c_{1}^{o} }$}}} \right)\) and \(1 - \left( {{\raise0.7ex\hbox{${C_{{12, { \hbox{min} }}}^{m} }$} \!\mathord{\left/ {\vphantom {{C_{{12, { \hbox{min} }}}^{m} } {c_{1}^{m} }}}\right.\kern-0pt} \!\lower0.7ex\hbox{${c_{1}^{m} }$}}} \right)\) were evaluated using Eq. (11) proposed by Liu and Rosen whose value must be maximum 1 and which determines the degree of synergism in reducing the surface tension or CMC efficiently [30–33].
where C 12,min and \(C_{12,min}^{m}\) are the minimum concentrations of mixed surfactant systems.
Data presented in Table 3 predicts the appreciable level of synergism for the examined three binary surfactant mixtures as their values appear close to 1. More evidently, it was observed that C12TAB + C12TPPB attributed a high degree of synergism and, thereby, became more efficient in reducing the surface tension. However, it was noticed that this trend decreases as the degree of hydrophobicity increases, which could be attributed to the difference in hydrophobic and hydrophilic groups resulting in a weak or low degree of synergism.
Thermodynamics of micellization and interfacial adsorption phenomenon
Our mixed surfactant systems are ionic in nature. Reported studies have rationalized such mixed systems as important as they clearly explain the role of head group–head group and chain–chain interactions which drive synergism. For mixed micelles, we have considered the thermodynamic analysis proposed by Maeda which involves ionic species based on the phase separation model [34, 35]. Table 4 presents the free energy of micellization (∆G Maeda) as a function of the mole fraction of the ionic component in the mixed micelle which is given by:
where B o is related to the CMC of the second surfactant within the mixture and is given by B o = ln C 2 (where C 2 is the CMC of CnTPPB). The second term, B 1 relates to the standard free energy change, and the last coefficient, B 2, is equivalent to β n as per the regular solution theory (RST), specifically, as \(B_{2} = - \beta^{m}\). Thus, once B 2 is calculated, we can obtain B 1 using
Negative values of B 1 indicate chain–chain interaction also plays an important role in mixed micellization.
The transfer of surfactant molecules from the bulk phase to the surface phase depends on the free energy change. As the value of free energy decreases, the surface becomes more stable thermodynamically, leading to more actives at the adsorbed surface. Thus, synergism in a mixed surfactant system depends on the extent of lowering of the measured free energy change [36, 37].
Thermodynamic parameters during micellization in terms of free energy such as surface free energy (∆G min), free energy of micellization (∆G M), and free energy of adsorption (∆G ads) were evaluated using the equations below, as described in the literature [24–26].
The last term \(\left(\frac{{\pi_{\text{CMC}} }}{{\varGamma_{{max}}}}\right)\) in Eq. (14a) expresses the work involved in transferring the surfactant molecule from a monolayer at a zero surface pressure to the micelle. Here, for all the binary mixtures, the last term of the Eq. (14a) is very small as compared to \(\Delta G_{\text{M}}\), which suggests that the work involved in transferring the surfactant molecule from a monolayer at zero surface pressure to the micelle is negligible.
According to RST, the excess free energy of micellization, \((\Delta G_{\text{ex}} )\) is calculated by using Eq. 15 which is related to excess enthalpy and the entropy of micellization as
Table 5 presents the data of the free energy change for all three systems, which appeared to be very low, indicating a more stable system and high surface activity which could be attributed to the evolution of synergism in the mixed surfactant system.
Solubilization study in mixed micellar system
Solubilization in surfactant micelles influences the absorption spectra of dyes. Such spectral change is typical dye behavior in the presence of cationic surfactants of opposite charge and a varying headgroup/hydrophobic environment. This phenomenon involves a consistent equilibrium existing between surfactant monomers and their respective micelles, the aggregation of the dye in the solution, the premicellar dye–surfactant complex and dye incorporated in the surfactant micelle. Studies have explained the role of hydrophobic interaction and electrostatic effect which results in the dye–surfactant complex formation in aqueous solution. However, such behavior is strongly connected with the chemical structure of the surfactant and the dye and also the way they assemble themselves in the micellar solution [38–40].
A dye solubilization study was performed to validate the CMC obtained from the surface tension measurements. For the solubilization study, we have used the hydrophobic dye, Orange OT which exhibits high affinity towards cationic surfactants. Figure 2 reveals the influence of surfactant hydrophobicity on the process of dye solubilization. A negligible amount of the Orange OT gets solubilized at low surfactant concentration while a sudden and steep rise was observed after the CMC. This value was noted as the CMC, the data of which are presented in Table 1.
In our study, the degree of dye solubilization followed the order of C16 − > C14 − > C12 − as the degree of hydrophobicity of the cationic surfactant had a major effect on micellization and aggregation. Our findings were similar to reported work which related the solubilization power with N agg [40–43]. A reverse trend was observed for the CnTPPB series, though, having a lower aggregation number than the CnTAB series, the former was able to solubilize a larger amount of dye. The higher solubilization power and lower CMC of the CnTPPB series could be explained by the three phenyl groups in the polar head group region which occupies a large area per molecule at the interface, imparting additional hydrophobicity, thereby promoting favorable conditions for micellization [38]. Figure 3 shows negative deviation from ideal behavior, indicating attractive interaction amongst all the three mixed surfactant systems. This behavior is agrees well with the negative values of β m [24].
Conclusion
A detailed study of interfacial and micellar behavior for a single and binary mixture of quaternary, salt-based cationic surfactants in aqueous solution using surface tension and dye solubilization measurements was performed. The selected binary surfactant mixtures belonging to the family of n-alkyltrimethylammonium bromide and n-alkyltriphenylphosphonium bromide with alkyl chain length (n = 12, 14 and 16 carbon atoms) exhibited good surface activity. The composition of the mixed micelles and the negative value of the interaction parameters, β o and β m from Rubingh’s theory, indicated an attractive interaction, i.e., synergistic mixing between each pair of surfactant. Further it was also inferred that the interaction decreased with an increase in the concentration of CnTPPB which could be due to electrostatic repulsion between the ionic species of CnTPPB. Activity coefficients (f 1 and f 2) of mixed surfactant systems exhibited the ideality of the individual surfactant in the binary mixture. Out of our examined systems, the C12TPPB + C12TAB mixture showed significant deviation from ideality with an average negative value of β as ~−2.7. Such behavioral change in the ideality for the mixed micellar system could be attributed to the weakening of the electrostatic head group repulsion, which favors the mixed micelle formation. A similar high degree of synergism was confirmed using Rosen’s approach. The measured CMC values obtained for the pure and mixed components appeared closer to CnTPPB than CnTAB, indicating a key role of the former in influencing the extent of interaction. The negative value of ∆G M and ∆G ads showed the micelle formation to be a spontaneous process and adsorption of surfactant at the air/solution interface to be energetically favorable, while a negative value of ∆G ex ensured a higher order of stability for the mixed micelles. Considering these findings, we anticipate that such studies may prove beneficial in understanding the interfacial and micellar properties for well-characterized mixed micellar systems.
References
Owoyomi O, Ige J, Soriyan O (2014) Mixed micelles of tetradecyltrimethylammonium and n-alkyltriphenylphosphonium bromides. J Dispers Sci Technol 35:826–831
Patrick HN, Warr GG, Manne S, Aksay IA (1999) Surface micellization patterns of quaternary ammonium surfactants on mica. Langmuir 15:1685–1692
Varade D, Patel V, Bahadur A, Bahadur P, Vethamuthu MS (2004) Mixed micelles of cationic surfactants and sodium cholate in water. Indian J Biochem Biophys 41(2/3):107–112
Azum N, Asiri AM, Rub MA, Khan AAP, Khan A, Rahman MM, Kumar D, Al-Youbi AO (2013) Mixed micellization of gemini surfactant with nonionic surfactant in aqueous media: a fluorometric study. Colloid J 75(3):235–240
Kamil M, Siddiqui H (2013) Experimental study of surface and solution properties of gemini-conventional surfactant mixtures on solubilization of polycyclic aromatic hydrocarbon. Model Numer Simul Mater Sci 3(04):17–25
Myers D (2005) Surfactant science and technology. Wiley, New York
Mohamed DE, Negm NA, Mishrif MR (2013) Micellization and interfacial interaction behaviors of gemini cationic surfactants–CTAB mixed surfactant systems. J Surf Deter 16(5):723–731
Dar AA (2006) Mixed micellization and interfacial properties of dodecyltrimethylammonium bromide and tetraethyleneglycol mono-n-dodecyl ether in absence and presence of sodium propionate. J Colloid Interface Sci 298(1):395–405
Dar AA (2008) Micellization and interfacial behavior of binary and ternary mixtures of model cationic and nonionic surfactants in aqueous NaCl medium. J Colloid Interface Sci 322(2):572–581
Holland P (1992) Mixed surfactant systems: an overview. In: Holland PM, Rubingh DN (eds) Mixed surfactant systems in ACS symposium series
Rosen MJ, Tracy DJ (1998) Gemini surfactants. J Surf Deterg 1(4):547–554
Zhang N, Wardwell PR, Bader RA (2013) Polysaccharide-based micelles for drug delivery. Pharmaceutics 5(2):329–352
Clint JH (1975) Micellization of mixed nonionic surface active agents. J Chem Soc Faraday Trans 1: Phys Chem Condens Phases 71:1327–1334
Motomura K, Yamanaka M, Aratono M (1984) Thermodynamic consideration of the mixed micelle of surfactants. Colloid Polym Sci 262(12):948–955
Rubingh DN (1979) Mixed micelle solutions. In: Mittal KL (ed) Solution chemistry of surfactants, vol 1. Springer, New York, pp 337–354
Sarmoria C, Puvvada S, Blankschtein D (1992) Prediction of critical micelle concentrations of nonideal binary surfactant mixtures. Langmuir 8(11):2690–2697
Sehgal P (2007) Interactions between the cationic Surfactants bearing different polar head groups: interfacial, conductivity, NMR, and fluorescence studies. J Dispers Sci Technol 28(8):1262–1271
Javadian S (2008) Electrolyte effect on mixed micelle and interfacial properties of binary mixtures of cationic and nonionic surfactants. J Colloid Interface Sci 318(2):449–456
Rodenas E, Valiente M, del Sol Villafruela M (1999) Different theoretical approaches for the study of the mixed tetraethylene glycol mono-n-dodecyl ether/hexadecyltrimethylammonium bromide micelles. J Phys Chem B 103(21):4549–4554
Paria S (2006) The mixing behavior of n-alkylpyridinium bromide–NP-9 mixed surfactant systems. Colloids Surf A 281:113–118
Oida T (2003) Adsorption and micelle formation of mixed surfactant systems in water. III. A comparison between cationic gemini/cationic and cationic gemini/nonionic combinations. J Oleo Sci 52(10):509–522
Minero C, Pramauro E, Pelizzetti E, Degiorgio V, Corti M (1986) Micellar properties of sodium dodecylpoly(oxyethy1ene) sulfates. J Phys Chem 90:1620–1625
Zhou Q, Rosen MJ (2003) Molecular interactions of surfactants in mixed monolayers at the air/aqueous solution interface and in mixed micelles in aqueous media: the regular solution approach. Langmuir 19:4555–4562
Parekh P, Varade D, Parikh J, Bahadur P (2011) Anionic-cationic mixed surfactant systems: micellar interaction of sodium dodecyl trioxyethylene sulfate with cationic gemini surfactants. Colloids Surf A: Physicochem Eng Aspects 385:111–120
Mahajan RK, Sharma R (2011) Analysis of interfacial and micellar behavior of sodium dioctyl sulphosuccinate salt (AOT) with zwitterionic surfactants in aqueous media. J Colloid Interface Sci 363:275–283
Joshi T, Bharatiya B, Kuperkar K (2008) Micellization and interaction properties of aqueous solutions of mixed cationic and nonionic surfactants. J Dispers Sci Technol 29:1–7
Kuperkar K, Abezgauz L, Prasad K, Bahadur P (2010) Formation and growth of micelles in dilute aqueous CTAB solutions in the presence of NaNO3 and NaClO3. J Surf Deterg 13(3):293–303
Patil SR, Mukaiyama T, Rakshit AK (2003) Interfacial, thermodynamic, and performance properties of a-sulfonato myristic acid methyl ester-hexaoxyethylene monododecyl ether mixed surfactants. J Dispers Sci Technol 24:659–671
Matsubara H, Ohta A, Kameda M, Ikeda N (2000) Aratono M interaction between ionic and nonionic surfactants in the adsorbed film and micelle. Dodecylammonium chloride and tetraethylene glycol monooctyl ether. Langmuir 16:7589–7596
Rosen MJ, Zhu ZH, Gao T (1993) Synergism in binary mixture of surfactants. Mixtures containing mono- and disulfonated alkyl- and dialkyldiphenylethers. J Colloid Interface Sci 157:254–259
Rosen MJ, Gao T, Nakatsuj Y (1994) Masuyama A Synergism in binary mixtures of surfactants. Mixtures containing surfactants with two hydrophilic and two or three hydrophobic groups. Colloids Surf A 88:1–11
Li F, Rosen MJ, Sulthana SB (2001) Surface properties of cationic gemini surfactants and their interaction with alkylglucoside or -maltoside surfactants. Langmuir 17:1037–1042
Liu L (1996) The interaction of some novel diquaternary gemini surfactants with anionic surfactants. J Colloid Interface Sci 179:454–459
Maeda H (1995) A simple thermodynamic analysis of the stability of ionic/nonionic mixed micelles. J Colloid Interface Sci 172:98–105
Ruiz CC, Aquiar J (2000) Interaction, stability, and microenvironmental properties of mixed micelles of Triton X100 and n-alkyltrimethylammonium bromides: influence of alkyl chain length. Langmuir 16:7946–7953
Oida T, Nakashima N, Nagadome S, Ko J, Oh S, Sugihara G (2003) Adsorption and micelle formation of mixed surfactant systems in water. III. A comparison between cationic gemini/cationic and cationic gemini/nonionic combinations. J Oleo Sci 52:509–522
Evans DF, Wennerstorm H (1994) The colloidal domain: where physics, chemistry, biology and technology meets. VCH, New York
Akbas H, Taner T (2009) Spectroscopic studies of interactions between C.I. Reactive Orange 16 with alkyltrimethylammonium bromide surfactants. Spectrochimica Acta Part A 73:150–153
Diaz Garcia ME, Sanz-Medel A (1986) A review. Talanta 33:255–264
Tehrani Bagha AR, Bahrami H, Movassagh B, Arami M, Menger FM (2007) Interactions of gemini cationic surfactants with anionic azo dyes and their inhibited effects on dye ability of cotton fabric. Dyes Pigm 72:331–338
Mata J, Varade D, Bahadur P (2005) Aggregation behavior of quaternary salt based cationic surfactants. Thermochim Acta 428:147–155
Aiysha E, Wardian Aland Rama MP (2005) Investigations on Mixed Systems of Alkyltriphenylphosphonium Bromides (C10-C16) with Tween 20 in Aqueous Media. J Dispers Sci Technol 26:155–162
Kim JH, Domach MM, Tilton RD (2000) Effect of electrolytes on the pyrene solubilization capacity of dodecyl sulfate micelles. Langmuir 16:10037–10043
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The author sincerely acknowledges the Special Assistance Programme (SAP) under scheme no. F.7-233/2009 (BSR) for the financial support.
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Padasala, S., Kanoje, B., Kuperkar, K. et al. Mixed Micellization Study of Alkyltrimethylammonium and Alkyltriphenylphosphonium Bromides in Aqueous Solution. J Surfact Deterg 19, 389–398 (2016). https://doi.org/10.1007/s11743-015-1780-9
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DOI: https://doi.org/10.1007/s11743-015-1780-9