1 The chelate CuA, exhibits maximum absorption at 480 nm. When the chelating reagent is present in at least a tenfold excess, the absorbance depends only on the analytical concentration of Cu(II) and conforms to Beer's law over a wide range. A solution in which the analytical concentration of Cu* is 2.15 × 10-*M and that for A- is 9.00 x 10- M has an absorbance of 0.759 when measured in a 1.00-cm cell at 480 nm. A solution in which the analytical concentrations of Cu** and A are 2.15 x 10-*Mand 4.00 x 10-* M, respectively, has an absorbance of 0.654 when measured under the same conditions. Use this information to calculate the formation constant K, for the process Cu+ + 2A- = CuA-
1 The chelate CuA, exhibits maximum absorption at 480 nm. When the chelating reagent is present in at least a tenfold excess, the absorbance depends only on the analytical concentration of Cu(II) and conforms to Beer's law over a wide range. A solution in which the analytical concentration of Cu* is 2.15 × 10-*M and that for A- is 9.00 x 10- M has an absorbance of 0.759 when measured in a 1.00-cm cell at 480 nm. A solution in which the analytical concentrations of Cu** and A are 2.15 x 10-*Mand 4.00 x 10-* M, respectively, has an absorbance of 0.654 when measured under the same conditions. Use this information to calculate the formation constant K, for the process Cu+ + 2A- = CuA-
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
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Transcribed Image Text:1 The chelate CuA, exhibits maximum absorption at 480 nm. When the chelating reagent is present in at
least a tenfold excess, the absorbance depends only on the analytical concentration of Cu(II) and conforms
to Beer's law over a wide range. A solution in which the analytical concentration of Cu* is 2.15 × 10-*M
and that for A- is 9.00 x 10- M has an absorbance of 0.759 when measured in a 1.00-cm cell at 480 nm.
A solution in which the analytical concentrations of Cu** and A are 2.15 x 10-*Mand 4.00 x 10-* M,
respectively, has an absorbance of 0.654 when measured under the same conditions. Use this information to
calculate the formation constant K, for the process
Cu+ + 2A- = CuA-
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