Submitted by Sabrina Sobel / Hofstra University on Mon, 06/24/2013 - 20:35
My Notes
Description

Synthesis of ammonium decavanadate, and analysis via IR, UV-Vis and quantitative titration. Time: 1.5 lab periods

 

Purpose

            The purpose of this lab experiment is to expose students to the synthesis of a colored POM, and to connect the use of standard analytical techniques to this new type of compound. It introduces the use of IR spectroscopy of inorganic materials.

 

Introduction

            Ammonium decavanadate ((NH4)6V10O28•6H2O) is an example of a polyoxometallate (POM). POMs are a large and diverse group, containing various metal cations, including, but not limited to, vanadium, molybdenum, chromium and iron. They are formed spontaneously in solution through what is called ‘self-assembly’. Essentially, they come together in solution through unknown mechanisms. In the lab, we can isolate various POMs by controlling conditions to favor one form over another, by varying concentration, pH or counter-ion. In the phase diagram of vanadates (Figure 1), one can see how varying pH and vanadium concentration can yield monomeric vanadate (VO43-), or POMs containing 2-10 vanadium atoms.

Decavanadate in Geology

            The decavanadate anion occurs naturally in minerals, huemulite Na4Mg2V10O28•24H2O, hummerite (KMg)2V10O28•16H2O, lasalite (NaMg)2V10O28•20H2O , pascoite Ca3V10O28•16H2O, magnesiopascoite Ca2MgV10O28•16H2O, and rauvite Ca(UO2)2V10O28•16H2O, which differ in the cations and amount of hydration. As you can see from Figure 3, the dominant color is yellow-orange. This is due to the presence of the decavanadate anion, which is yellow-orange. All of the vanadium POMs and vanadate are yellow-orange due to charge-transfer bands in the 200 – 500 nm range.

Decavanadate in Biology

            Vanadate (VO43-) is isostructural and isoelectronic with phosphate (PO43-). For this reason, vanadate has found interest with researchers studying the role of phosphate in biological systems, such as in insulin uptake in cells. In addition, decavanadate has been used to bind to biologically relevant molecules, such as gelatin, cytosine, estrogen receptor, and myosin.

 

Laboratory Experiment

In this experiment, students synthesize ammonium decavanadate, and analyze the resulting product via UV-Vis and IR spectroscopy as well as by permanganate titration.

Learning Goals
  1. The student will define polyoxometallates (POMs).
  2. The student is able to interpret a concentration-pH diagram to determine conditions suitable for formation of the desired product.
  3. The student will apply IR spectroscopy to identify inorganic compounds.
  4. The student will use Beer’s Law to analyze the purity of a colored compound.
  5. The student will use redox titration to analyze a compound for purity.
Equipment needs

Materials for a class of 20:

Ammonium metavanadate (NH4VO3, CAS#7803-55-6, Aldrich 99%): 6.0g

50% acetic acid solution: 100 mL

95% ethanol: 360 mL

Oxalic acid dihydrate (H2C2O4•2H2O, CAS#6153-56-6, Aldrich 99%):  2.5g

1.0 M sulfuric acid: 1.2 L

Sodium bisulfite (NaHSO3, CAS#7631-90-5, Aldrich):   2.0g

0.10 M potassium permanganate (KMnO4): 100 mL

50 mL beakers, 100 mL volumetric flasks, funnels and erlenmeyers

50 mL burets, 10.0 mL and 20.0 mL transfer pipettes

UV-Vis (Spec 20 is fine) and IR spectrophotometers

Implementation Notes

Because the synthesis is quick, but the crystals should be allowed to dry, I pair this experiment with another synthesis and analysis experiment, and spend the first lab period on the two syntheses, then the subsequent lab periods on analyses. If you have another experiment that takes 1.5 lab periods, then you can pair appropriately. The 0.5 lab period part is the synthesis. See Instructor Notes for other comments.

Time Required
1.5 - 4 hour lab periods (0.5 lab period for synthesis, 1 lab period for analyses)
Evaluation
Evaluation Methods

Student performance on Preliminary Questions (PQs) and reports are assessed

Percent yield and percent purity from UV-Vis and titration analyses

Accuracy in completion of table of IR bands/assignments

Answers to Thought Questions

Evaluation Results

Percent Yield across two years: average 80%+/-11% for 21 students

Percent Purity via titration analysis in first year: -12% error (less than theoretical); implemented improved estimation of endpoint – see Instructor Notes

Added IR Spectroscopy Tables (given values, and a blank one to fill in on report). Without these 'lead by the nose' guides, students did a poor job demonstrating understanding of the meaning of the IR spectra. This is most likely due to the fact that this is their first exposure to IR spectroscopy (second-semester freshman level).

Creative Commons License
Attribution CC BY
Sheila Smith / University of Michigan- Dearborn

Sabrina-

 

I'm still reading through the materials that you've put up and this looks great... However.. my initial reaction is that there's too much  in the intro on the VIPER page... can we take a ot of that info out and leave it as a laboratory procedure in a document that people can download.  That's the piece that they are going to want to download for their students and if you think about how difficult it is to cut and paste from html into a word doc, we can do this better.  Not only that but making it a document with a header containing the CC info will better allow you to protect your ownership of this.. in fact, I might even suggest that you upload the lab procedure as a .pdf file.

 

S.

Wed, 06/26/2013 - 11:43 Permalink
Sabrina Sobel / Hofstra University

Great suggestion! You can tell that this is my first LO. I'll trim the intro, since I just copied and pasted from my established handout to the students. I'll separate the data pages and keep them as word docs so that students could use them directly to add results in the doc for the report.

Wed, 06/26/2013 - 12:48 Permalink
Franky / Nnamdi Azikiwe University
Hello Dear Sabrina G. Sobe please can you answer some of the questions you have hear  Decavanadate Student PQs.docx
If any body can help I will be glad.....
 
5. Determine the mass of oxalic acid dihydrate (H2C2O4•2H2O) necessary to make 100. mL of 0.010 M solution.
 
 
6. Calculate the theoretical yield of (NH4)6V10O28•6H2O if a student starts with 0.3124g NH4VO3.
 
 
 
7. If recovered 0.2248g (NH4)6V10O28•6H2O, what is the percent yield?
 
 
8. Calculate the percent vanadium in (NH4)6V10O28•6H2O.
 
 
 
Sat, 04/29/2017 - 15:12 Permalink
Barbara Reisner / James Madison University

Dear Francis,

Faculty privleges are required to access keys.

With regards,

The VIPEr admin team

Sun, 04/30/2017 - 23:00 Permalink