The kinetics of gold(III) extraction by pyridine-2-azo‑p‑dimethylaniline in water and in micellar systems

Aydınoğlu, Sabriye; Biver, Tarita; Secco, Fernando; Venturini, Marcella

doi:10.1016/j.colsurfa.2015.05.048

Cited by 4 publications

(9 citation statements)

References 18 publications

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“…The extent of retention is independent of the solution pH. [8], is totally different from the spectrum in water. In contrast, the shape of the spectrum in SDS does not differ from that of the spectrum recorded in water.…”

Section: The Partitioning Of Pada Au(iii) and Au-pada Complex Betweementioning

confidence: 79%

“…The commercially available ligand PADA ( Figure 1) is totally adsorbed on a variety of surfactants, including SDS [4] and has proven to be an excellent metal extractor, being able to transfer metal ions from water to micellar phases with yields approaching 100% [5][6][7] Moreover, we have found that PADA is able to complex Au(III) with great affinity even if the coordination shell of the metal is occupied, as in AuCl4 - [8,9]. In this case, a molecule of PADA replaces two chloride ions forming a strong chelate.…”

Section: Introductionmentioning

confidence: 90%

“…The stock solutions of these reactants were prepared by dissolving appropriate amounts of the relevant solid material in water. The gold content was determined by direct UV absorption spectrometry exploiting the absorption band of AuCl4ion centred at 233 nm whose maximum absorption is proportional to the gold concentration [8,9]. Water, purified by pumping deionized water through a Milli-Q apparatus, was used to prepare the solutions and also as the reaction medium.…”

Section: Methodsmentioning

confidence: 99%

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The mechanism of the reaction between Au(III) and PADA in sodium dodecylsulphate

Aydınoğlu

Biver

Secco

et al. 2016

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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Section: The Partitioning Of Pada Au(iii) and Au-pada Complex Betweementioning

confidence: 79%

Section: Introductionmentioning

confidence: 90%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

The mechanism of the reaction between Au(III) and PADA in sodium dodecylsulphate

Aydınoğlu

Biver

Secco

et al. 2016

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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“…Note that Au(III) absorbs in the UV [31], hence, the UV-vis spectrophotometric technique could have been used to quantify the gold content. However, spectrophotometry becomes unsuitable for low Au(III) concentrations ( = 7.1 × 10 3 M −1 cm −1 at 233 nm).…”

Section: Instrumentation and Methodsmentioning

confidence: 99%

Gold(III) extraction and recovery and gold(III)/copper(II) separation using micelles

Aydınoğlu

Biver

Ceccarini

et al. 2015

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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Gold extraction from aqueous solutions has been performed by micellar enhanced ultrafiltration (MEUF), using SDS and DTAC micelles. DTAC entraps 92-100% of the metal, which is present in form of AuCl4^-, owing to electrostatic interaction. Using SDS the extraction of gold is unsuccessful. However, addition of PADA, as a metal extractor agent, according to the ligand modified micellar enhanced ultrafiltration (LM-MEUF) procedure, makes the extraction yield to approach 100% also with SDS. The recovery of gold entrapped in the micellar pseudo-phase has also been investigated. Different stripping agents have been used, the most efficient of them being a mixture of NaCl and NH3 which allowed the metal to be expelled from the micelle with a yield of 85%. Finally, Au(III)/Cu(II) separation is achieved with DTAC or SDS between pH 3 and 5. Almost 100% of Au(III) is retained on DTAC micelles while all Cu(II) remains in the aqueous medium, while the opposite occurs in SDS

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“…Thus, under such conditions, the rate of hydrolysis is negligible compared with rate of piperidinolysis of PSa -. It is widely known that the ability of surfactant to form nanoparticle aggregates such as micelles could create different media in reaction phases that might affect the rate of the reactions [39,40]. A pseudophase micellar (PM) model can be used to explain the effect of TTABr micelles on the rate of nucleophilic reaction between Pip and PSa - [41] as 4) and (5) with kinetic parameters (k 0 , h, K X/S and k 0 , X k cat , K X/S ) listed in Table 1, at ½4-FBzNa] op 0 ¼ 0:0046 (filled circle), 0.0093 (filled triangle) and 0.0131 (filled diamond) 4) and (5) with kinetic parameters (k 0 , h, K X/S and k 0 , X k cat , K X/S ) listed in Table 1 [26].…”

Section: Kinetic Measurementsmentioning

confidence: 99%

Counterion‐Induced Cationic Flexible Nanoparticle Catalytic of Piperidinolysis of Phenyl Salicylate

Noh

Khalid

Ariffin

et al. 2017

J Surfact & Detergents

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The removal of PSa− from bulk aqueous phase to the pseudo‐micellar phase by halobenzoate counterion X is responsible for the monotonic increase in kobs (pseudo first‐order rate constants) with the increase in the values of [MX] where MX = sodium salts of 2‐, and 4‐halobenzoic acids. The values of ion exchange constants, KnormalXBr or RnormalXBr for X = 2‐ and 4‐halobenzoate ions in the presence of tetradecyltrimethylammonium bromide (TTABr) were calculated from the apparent catalytic rate constants, Xkcat which represent the catalytic effect of CFN. Larger values of KnormalXBr or RnormalXBr were observed for X = 4‐halobenzoate ions than that for X = 2‐halobenzoate ions due to isomeric factors. The values of KnormalXBr or RnormalXBr determined in the presence of TTABr were compared with previously determined KnormalXBr or RnormalXBr values in the presence of cetyltrimethylammonium bromide (CTABr). The values of KnormalXBr or RnormalXBr are nearly 8 ~ 9‐fold larger for 4‐IBz−, 4‐BrBz− and 4‐ClBz− compared to the respective values of X = 2‐IBz−, 2‐BrBz− and 2‐ClBz−. The values of KnormalXBr or RnormalXBr for X = 4‐FBz− is nearly 3‐fold larger than that for X = 2‐FBz−. The values of KnormalXBr or RnormalXBr for X = 2‐ and 4‐halobenzoates are significantly smaller in the presence of TTABr than these in the presence of CTABr nanoparticles.

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The kinetics of gold(III) extraction by pyridine-2-azo‑p‑dimethylaniline in water and in micellar systems

Cited by 4 publications

References 18 publications

The mechanism of the reaction between Au(III) and PADA in sodium dodecylsulphate

The mechanism of the reaction between Au(III) and PADA in sodium dodecylsulphate

Gold(III) extraction and recovery and gold(III)/copper(II) separation using micelles

Counterion‐Induced Cationic Flexible Nanoparticle Catalytic of Piperidinolysis of Phenyl Salicylate

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