Thermodynamics of the [CoCl(iPrOH)3]+ to [CoCl(iPrOH)2(MeOH)3]+ Reaction: A General Chemistry Laboratory Exercise

Nyasulu, Frazier; Nething, Daniel B.; Barlag, Rebecca; Wise, Lindy; Arthasery, Phyllis

doi:10.1021/ed200097x

Cited by 6 publications

(10 citation statements)

References 10 publications

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“…In order to observe the reverse equilibrium (eq ), students prepared Table solutions and analyzed the full spectrum on the LabQuest. The absorbance values and the given equilibrium constant expression, derived from eq , were used to determine the equilibrium constant for each solution in order to quantify and compare both directions of the cobalt complex equilibrium. For solution 3, representing the coexistence of two different complex species (and thus two distinct ε) in solution, students were asked to plot absorbance A against wavelength λ.…”

Section: Laboratory Descriptionmentioning

confidence: 99%

“…To improve comprehension of Le Châtelier’s principle, laboratory exercises often visualize concepts such as equilibrium using observable phenomena. For instance, color change in cobalt (Co) complexation , is an ideal identifier of reaction progress because it is both qualitatively distinguishable (when significant color change occurs) and quantifiable via instrumentation. UV–visible spectrophotometers are commonly used instruments for probing color-change equilibria in laboratory environments, and such equipment holds continued relevance in academia and industry to this day .…”

Section: Introductionmentioning

confidence: 99%

“…Several undergraduate laboratories and demonstrations ,,− have used Co complexation reactions for teaching equilibrium. Some experiments demonstrated the vivid color change by shifting the chemical equilibrium of Co complexes from pink octahedral to blue tetrahedral complexes by using HCl as a ligand. ,, Other work investigated the blue-to-pink transition by changing temperature in an alcohol-based Co complexation where the temperature effects on thermodynamic parameters were the focus . However, no prior work has used alcohol ligands to shift the chemical equilibrium from pink to blue Co complexes via alcohol concentration.…”

Section: Introductionmentioning

confidence: 99%

“…1,5,9 Other work investigated the blue-to-pink transition by changing temperature in an alcohol-based Co complexation where the temperature effects on thermodynamic parameters were the focus. 2 However, no prior work has used alcohol ligands to shift the chemical equilibrium from pink to blue Co complexes via alcohol concentration. This experiment allows a range of colors, from pink to blue, to be clearly visible as the reaction shifts from an alcohol-based pink complex to a blue complex.…”

Section: ■ Introductionmentioning

confidence: 99%

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Exploring Chemical Equilibrium for Alcohol-Based Cobalt Complexation through Visualization of Color Change and UV–vis Spectroscopy

et al. 2019

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Introducing chemical equilibrium concepts in undergraduate general chemistry promotes improved understanding of chemical reactions. We have developed an engaging laboratory experiment exploring the equilibrium of cobalt complexation in alcohols using UV−vis spectroscopy and successfully implemented in a large general chemistry class of 378 students at Brown University. The octahedral to tetrahedral (pink to blue) cobalt complex transition generates vivid visualizations, increasing students' interest in learning. The equilibrium constants can be measured using UV−vis absorption spectroscopy and the Beer−Lambert law. Vast differences in molar absorptivity coefficients between octahedral and tetrahedral geometries of cobalt complexes prompt discussions on absorptivity, orbital splitting, and color change under the purview of learning Le Chatelier's principle. Additionally, the experimental results regarding the equilibrium constant allowed students to examine possible mechanistic pathways. Student responses to conducting the experiment were positive, most notably because this experiment encouraged them to analyze their experimental results critically and propose possible reaction mechanisms and equilibrium expressions while appreciating the sharp color transition that the complexation equilibrium undergoes.

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Section: Laboratory Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Exploring Chemical Equilibrium for Alcohol-Based Cobalt Complexation through Visualization of Color Change and UV–vis Spectroscopy

et al. 2019

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“…[5][6][7][8][9][10][11][12][13] However, many of these analyses require instrumentation that may not be widely available to all laboratories, or require more sophisticated procedures that are unsuitable for an introductory audience. In the interest of bringing this concept to a broader group of students, an alternate methodology was developed to perform the analysis based on just the natural dissociation of the acid as determined by pH and temperature measurement.…”

Section: G H T S°°°∆ = ∆ − ∆ (2)mentioning

confidence: 99%

Determination of Thermodynamic Values (∆S°, ∆H°, and ∆G°) from the Dissociation of a Weak Acid

Rezsnyak¹

2017

WJCE

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The concepts of equilibrium and thermodynamics are among the most important topics covered in a general chemistry course. The thermodynamic properties ∆G°, ∆H°, and ∆S° are difficult to measure directly in a laboratory setting, but can be determined by monitoring the temperature dependence of the equilibrium constant, K. Previously published procedures require sophisticated technology or methodology, such as simultaneously measuring temperature and absorbance using a spectrophotometer, which may be unavailable to small and/or rural colleges and universities. Measuring the pH of a weak acid solution while varying the temperature allows for this analysis to be conducted simply, making it more accessible to broader range of academic laboratories. This experiment outlines the simple measurement of the equilibrium constant and temperature, with aspects of graphical analysis, allowing students to link the concepts of equilibrium and thermodynamics conceptually and mathematically. Calculated values of ∆G°2 98 are consistent with literature values, indicating that the experiment is suitably robust to be performed successfully by students of a wide range of skill levels.

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Thermochromism: Theory Directed Design of a Thermochromic Thermometer

2023

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The dissolution of cobalt(II) chloride in an appropriate binary alcohol solvent yields an equilibrium mixture, consisting of the differently colored octahedral (pink in color) and tetrahedral (blue in color) cobalt(II) coordination complexes, which can exhibit a brilliant and reversible pink-to-blue color transition over a ∼10 °C windowi.e., function as a thermochromic thermometerwhere the dynamic equilibrium is described by CoCl 2 false( normalR 1 OH false) 4 + 2 normalR 2 OH ⇄ CoCl 2 false( normalR 2 OH false) 2 + 4 normalR 1 OH . In this experiment, students are challenged to exploit the principles of equilibrium in order to exhibit control over the chemical system and design, model, and implement a thermochromic thermometer which, when correctly prepared, exhibits a specifically targeted composition and color at a unique temperature assigned to each student. By employing fundamental principles of physical chemistry in conjunction with spectrophotometric analysis, students quantify pertinent thermodynamic parameters for the chemical system, and then use them to predictively model/calculate (via Excel) the exact initial composition required to enable the specifically desired equilibrium composition and color to emerge at precisely the target temperature. Completely directed by their modeled prescriptions, students then validate their theoretical predictions by implementing the functional thermochromic thermometer in the laboratory.

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Thermodynamics of the [CoCl(ⁱPrOH)₃]⁺ to [CoCl(ⁱPrOH)₂(MeOH)₃]⁺ Reaction: A General Chemistry Laboratory Exercise

Cited by 6 publications

References 10 publications

Exploring Chemical Equilibrium for Alcohol-Based Cobalt Complexation through Visualization of Color Change and UV–vis Spectroscopy

Exploring Chemical Equilibrium for Alcohol-Based Cobalt Complexation through Visualization of Color Change and UV–vis Spectroscopy

Determination of Thermodynamic Values (∆S°, ∆H°, and ∆G°) from the Dissociation of a Weak Acid

Thermochromism: Theory Directed Design of a Thermochromic Thermometer

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