Instrumental Analysis Lecture and Laboratory: A Survey - Journal of

Research: Science and Education

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Instrumental Analysis Lecture and Laboratory: A Survey James E. Girard* Department of Chemistry, American University, Washington, DC 200815-8014; [email protected] Constance T. Diamant Mary Washington College, Fredericksburg, VA 22401-5358

Instructors of instrumental analysis lecture and laboratories are faced with a dilemma. Which topics should be covered in lecture and which techniques should be used in the instrumental laboratory? This question has been asked before (1–3) and others have surveyed the instruments used in instrumental analysis laboratory courses (4, 5). Harris and O’Brien polled instructors of these courses at schools graduating the most undergraduate chemistry graduates about their practices in both the lecture and the laboratory (6, 7 ). The purpose of our study was to understand what topics are being taught in instrumental lecture and which instrumental techniques are being performed in the laboratory. A questionnaire based on one used by Sherren in 1981 (8) was sent to instructors teaching at schools that were randomly selected from the ACS’s College Chemistry Faculties 1996 publication and the 1995 Directory of Graduate Research. The sample group was diverse enough to allow us to see if large schools or schools with graduate chemistry programs or engineering schools were teaching the course in ways that differed from the methods used at smaller schools without graduate or engineering programs. We also compared our 1998 responses with those obtained in 1981 by Sherren to see if any long-term trends could be seen. The results of our survey indicate that the instrumental laboratory has changed more than the instrumental lecture course. The Surveys In 1981, Sherren sent out 100 questionnaires to faculty in four-year colleges and universities in all parts of the country. She received 58 responses, and of these, 52 schools had a separate course in Instrumental Analysis. Our questionnaire was based on that of Sherren. It was modified by adding five modern techniques that were not generally in use in 1981: capillary electrophoresis, GC–MS, Table 1. Number and Types of School Sur veyed Type of School

Number of Schools Surveyed

Responding

Public

124

42

Private

103

32

With an engineering program

102

34

Without an engineering program

125

40

With a chemistry graduate program

119

42

Without a chemistry graduate program

108

32

With more than 10,000 students

99

23

With fewer than 10,000 students

128

51

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ICP–AES, FTIR, and supercritical fluids. In addition, five categories that were redundant were removed. We sent 227 questionnaires to faculty at four-year colleges and universities and as Table 1 shows, we chose a diverse sample. We received 74 responses, a 32.6% response rate, and as can be seen in Table 1, the numbers of responses for each category of school were balanced. We correlated the individual responses with the type of school responding, and compared our 1998 results to Sherren’s 1981 responses. A comparison of the 1981 and 1998 percentage of responses regarding topics taught in lecture and laboratory can be seen in Table 2. Summary of the Responses Received The first question asked “How many credit hours do you give for Instrumental Analysis and Laboratory?” The responses we received are not significantly different from those obtained by Sherren in 1981. They indicate that the majority of schools, 54%, give four credits for instrumental lecture and laboratory; 15% give five credits and 16% give three. The next question was “What textbook are you currently using (or do you intend to use next time you teach the course?” We asked for separate answers for the lecture and the laboratory and we found that the overwhelming majority of instructors, 64 of the 74 respondents (86%), use one of the books by Skoog et al. from Saunders for the instrumental lecture. The majority of those teaching instrumental laboratory use no book. Forty-five of the 74 respondents, 54%, use individually designed handouts; another 10, 13%, use Chemistry Experiments For Instrumental Methods by Sawyer, Heineman, and Beebe, published by Wiley in 1984. Thirteen percent did not specify what materials they use. Five schools, 7%, do not offer instrumental laboratory. These findings perhaps indicate that instructors prefer to use their own handouts and as a result, the demand for lab manuals is so small that publishers are reluctant to invest in publishing such materials.

Lecture Topics Responses to our questionnaire indicate that as in 1981, each of the 37 lecture topics listed was being taught by at least one school. However, no school indicated that all 37 topics were taught in one term. Comparison of the 1998 results to the 1981 survey showed a significant change in the frequency of inclusion of some lecture topics. For example, in 1981, optical rotary dispersion, circular dichroism, and polarimetry were taught by a large percentage of instructors. Today almost no one teaches these topics. Although most instructors include gas chromatography and proton NMR in their courses, these topics were taught

Journal of Chemical Education • Vol. 77 No. 5 May 2000 • JChemEd.chem.wisc.edu

Research: Science and Education Table 4. Instrumental Techniques Offered at Undergraduate Schools and Schools with a Graduate Program

Table 2. Topics Taught in Instrumental Analysis, 1981 and 1998 Topic

Lecture

Laboratory

1981 1998

1981 1998 ∆

Experiment

Respondents Including This Experiment (%)

Visible spectrophotometry–absorption

86

97

81

84

Ultraviolet spectrophotometry–absorption

88

91

81

78

Undergraduate

Graduate

Atomic absorption spectroscopy

84

89

62

77

+

UV–vis

88

81

HPLC

62

86

34

74

+

Fluorescence

45

58

Infrared absorption spectrophotometry

81

82

66

55

HPLC

70

76

GC–MS

—

78

—

69

AA

70

79

Liquid chromatography

64

77

28

24

Gas–liquid chromatography

79

77

78

64

–

GC–MS

45

84

FTIR

—

76

—

61

+

FTIR

45

72

Atomic emission spectroscopy

78

76

36

32

ICP–AES

9

26

Mass spectrometry

72

74

19

24

CE

6

28

Molecular fluorescence spectroscopy

64

72

38

54

+

39

12

Electrochemical cells, electrode potentials

86

65

45

31

–

Potentiometric methods

72

65

59

34

–

Inductively coupled plasma–AES

34

65

2

19

+

Cyclic voltammetry

33

57

16

38

+

Proton NMR

59

55

48

33

–

Polarography

78

49

60

35

–

Raman spectroscopy

45

47

3

7

Capillary electrophoresis

—

46

—

18

+

Atomic fluorescence spectroscopy

34

42

2

54

+

X-ray methods

43

39

7

8

31

38

2

20

+

Electric circuits

28

35

7

18

+

Supercritical fluids

—

32

—

3

Controlled potential coulometry

60

28

7

11

Controlled current coulometry

59

23

29

7

–

Electrogravimetric methods

55

22

33

11

–

Amperometric methods

62

22

28

8

–

Chemical analysis of surfaces: ESCA, SIMS

21

19

0

1

Radiochemical methods

28

19

10

3

Thermal methods

33

18

5

7

Conductance methods

55

14

40

14

Electron spin resonance spectroscopy

33

7

3

1

Opical rotatory dispersion

16

5

3

0

Refractometry

26

4

17

3

–

Polarimetry

21

4

21

0

–

Computerized analysis

31

30

21

22

13

C NMR

+

–

Table 3. Most Commonly Offered Instrumental Techniques Respondents Including This Experiment (%)

Experiment UV–visible spectrophotometry

84

Atomic absorption spectroscopy

77

High-pressure liquid chromatography

74

Gas chromatography–mass spectroscopy

69

Gas chromatography

64

Fourier transform–infrared spectroscopy

61

Molecular fluorescence

54

Electrochemical cells

31

Proton nuclear magnetic resonance

33

Electronics

18

Computerized analysis

22

Computerized analysis

by fewer instructors in 1998 than in 1981. As Organic Chemistry II has become more a spectroscopy course, these techniques are generally being taught in the sophomore year. Except for cyclic voltammetry, few instructors now include electrochemistry topics. The instrumentation for cyclic voltammetry has improved considerably since 1981, which probably explains why more instructors are teaching this technique. Other techniques, such as atomic spectroscopy, are replacing electrochemical techniques in the curriculum. The lecture topics most often included are UV–vis spectrophotometry, infrared spectrophotometry, molecular fluorescence spectroscopy, atomic absorption spectroscopy, NMR, GC–MS, mass spectrometry, electrochemical cells, cyclic voltammetry, HPLC, and GC. Results for lecture topics that were not included in the 1981 questionnaire, but added in 1998 were as follows: GC– MS, 78%; ICP–AES, 65%; capillary electrophoresis, 46%; and supercritical fluids, 32%. Except for GC–MS, few of these topics were included in the laboratory at most schools, which is not surprising considering the difficulty of obtaining expensive modern instrumentation for teaching laboratories. GC–MS is the one instrument in this group whose price has fallen significantly, and 69% of schools responding indicated that they included a GC–MS experiment.

Changes in Laboratory Topics The instrumental laboratory has changed more than the instrumental lecture. Four techniques that were often used in 1981, infrared, NMR, electrochemical methods, and gas chromatography, have declined in usage. Six instrumental techniques are increasing in usage: molecular fluorescence, atomic absorption spectroscopy, GC–MS, cyclic voltammetry, HPLC, and elementary electronics. It appears that there is a consensus about which experimental techniques the instrumental course should offer to undergraduates. The 11 most offered instrumental experiments are listed in Table 3 with the frequency of their offering. A comparison was made of the experiments offered by the different types of institution and it was found there were no differences between public and private institutions, between those with more than 10,000 students and those with less than 10,000, or between schools with and without engineering

JChemEd.chem.wisc.edu • Vol. 77 No. 5 May 2000 • Journal of Chemical Education

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Research: Science and Education

departments. However, we did find a difference in lab offerings when we compared departments with and without a graduate program in chemistry. A comparison of the frequency of offering of 9 experiments in departments with and without a graduate program is shown in Table 4. As can be seen in this table, undergraduate and graduate departments offer UV–vis, HPLC, AA, and molecular fluorescence laboratories with roughly equal frequency. However, GC–MS is offered almost twice as frequently by graduate departments, and other expensive modern techniques such as FTIR, capillary electrophoresis, and ICP–AES are all more commonly offered by graduate departments than by undergraduate departments. Undergraduate departments, on the other hand, offer computerized analysis more often, probably because they rely on computer simulations of analytical instruments. Expensive modern instrumentation for instrumental laboratory appears to be less available to undergraduate departments than in graduate departments.

the limited amount of laboratory time that is available, or it may be caused by limitations in instrumentation. The results from the questionnaire we describe may help instructors choose which topics to include. As expected, departments with graduate programs have better equipment available for the instrumental laboratory and consequently undergraduates get a more comprehensive laboratory experience in these departments.

Conclusion

Literature Cited

The content of the analytical curriculum and the instrumental analysis course is constantly evolving, and not surprisingly, the curriculum reflects the sophistication of society. Subjects once taught at the graduate level are now offered at the junior or senior level, and subjects that were once juniorlevel topics are now offered at the sophomore level, mirroring technological advances. The instructor of the instrumental analysis course will always have to weigh which topics are fundamental and necessary and which have to be left out of the syllabus. Responses to our questionnaire indicate that more than twice as many topics are covered in instrumental lecture than in the laboratory. This may simply be a function of

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Acknowledgments We thank Anne Sherren for permission to use her 1981 survey and data. We acknowledge the assistance of Julia Elmer and Ramya Mahadevanijaya in the preparation of the survey and the tabulation of the data. The results of this survey were presented at the 1998 Middle Atlantic Regional Academic Analytical Conference, Georgetown University, Washington, DC.

1. Strobel, H. A. J. Chem. Educ. 1954, 31, 159. 2. Laitinen, H. A. J. Chem. Educ. 1956, 33, 422. 3. Ewing, G. W.; van Swaay, M. Anal. Chem. 1985, 57, 385A– 392A. 4. Leggett, D. J. Anal. Chem. 1981, 53, 385A–392A. 5. Instrumentation Needs of Academic Departments of Chemistry; Anal. Chem. 1984, 56, 1225A–1231A. 6. Harris, H. H.; O’Brien, J. J. J. Chem. Educ. 1992, 69, A266. 7. Jones, B. T. J. Chem. Educ. 1992, 69, A268. 8. Sherren, A. T. Instrumental Analysis: Who is doing what in lecture and lab in the 1980’s. Presented at the Great Lakes Regional ACS Meeting, June 1982, Chicago.

Journal of Chemical Education • Vol. 77 No. 5 May 2000 • JChemEd.chem.wisc.edu