Teaching Structure–Property Relationships ... - ACS Publications

In the Classroom

Teaching Structure–Property Relationships: Investigating Molecular Structure and Boiling Point Peter M. Murphy 16 Montbard Drive, Chadds Ford, PA 19317; [email protected]

Among the many challenges in teaching a chemistry course are (i) using the limited time wisely, (ii) integrating the laboratory and lecture materials, (iii) balancing the scope and depth of important principles studied, and (iv) giving students a taste of the methodology of scientific research including data analysis and literature searching. Teachers and students can benefit from resources that emphasize teaching different aspects of the scientific method. More laboratory time is often spent on experimentation and data tabulation at the expense of data analysis, hypothesis, prediction, and the iterative nature of research, which includes planning further experiments. Structure–property relationships are one theme that crosses many subdisciplines in chemistry and allows students to experience all aspects of the scientific method. In organic chemistry, students learn the effect of molecular structure and functional group on both physical properties and chemical reactivity to understand and to organize the vast number of reactions and reagents. Correia (1) provided an extensive set of boiling point data for 1-haloalkanes and showed how these data can be used to teach the structural-property effects of molecular weight, surface area or geometry, polarizability, and dipole–dipole interactions. Recent articles (2) have shown how correlations between molecular modeling and physical properties can be used to enhance students’ understanding of structure–property relationships. Research publications continue to model chemical and molecular structure as a predictor of physical and chemical properties for industrial applications (3). The determination of boiling points is an important skill for the purification and identification of organic compounds and this technique is usually taught early in a student’s career. When students combine their own experimental data with published physical properties, followed by an empirical analysis of all the data, they can further their understanding of structure–property relationships and their use of the scientific method. Textbooks (4), lab manuals (5), reference books (6), and online resources (7) have extensive physical property data but this information is scattered and not organized in the best format for teaching structure–property relationships. While spending some time compiling and organizing physical property data can benefit students, they will build a deeper understanding of scientific principles if more of their classroom, laboratory, and study time can be spent on analyzing the data and reaching appropriate conclusions and then pondering subsequent research questions. By manipulating an extensive, tabulated data set of boiling points for organic compounds organized by carbon chain and functional group, students can (i) more easily understand the process of studying structure–property relationships, (ii) learn how to develop empirical models, and (iii) begin to integrate those relationships in their thinking about the fundamental aspects of molecular structure. Through data analysis exerwww.JCE.DivCHED.org

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cises, the students can hone their analysis skills and come to “discover for themselves” various relationships between boiling point and important aspects of the chemical structure of organic compounds, such as molecular geometry, intermolecular bonding, and molecular weight. These exercises may generate unanswered questions in the student’s mind, which commonly happens in research, and may spark the curiosity necessary for more literature searching or for conducting additional experiments, thus allowing students to experience the open ended nature of research where preliminary conclusions lead to interest in further research. Tables 1 and 2 contain boiling points for a series of carbon chains (methyl, ethyl, n-propyl, phenyl, etc.) in rows and functional groups (hydroxy, chloride, amine, carboxylic acid, etc.) in columns. The tabulated boiling points were gathered from reference books (6), online resources (7, 8), and supplier catalogs (9). The tables are generally organized by increasing boiling points from top to bottom and left to right to give an overview of the trend from gases to higher boiling liquids for organic compounds. Merely having the students “color-code” the cells based on their boiling point ranges can aid the students’ understanding of the overall pattern for the impact of chemical structure on boiling point and to see the division between room temperature liquids and gases. The physical property of boiling point is commonly reported as a range of a few ⬚C, though published reports can vary widely. For example, over 30 reported values were found for the atmospheric and reduced pressure boiling point of cyclohexyl methyl ketone. The nearly two dozen published reports on the boiling point of t-butyl alcohol gave a combined range of 73 ⬚C to 96 ⬚C at atmospheric pressure (i.e., 760 mm Hg). The value in each cell in Tables 1 and 2 is a single boiling point value in ⬚C for each compound so that these data can be used as a teaching aid to facilitate quantitative exercises in empirical analysis. This single boiling point value is the mean of the reported boiling point range at atmospheric pressure whether from a single source or the average of multiple published values after excluding any values that were significantly different than the other values. More advanced students could benefit from a discussion as to why so many different boiling points are reported for the same compound and how to reconcile conflicting data in the published literature. Discussing the options and decisions for constructing Tables 1 and 2 would allow students to develop an appreciation of the complexity and potential biases of organizing even seemingly simple physical property data (such as boiling point, solubility, density, etc.) across a wide range of compounds. A number of other simplifications were made to allow students to more easily focus on correlating the effects of chemical structure on physical properties. For R⫺X compounds with the possibility of stereoisomers, (e.g., 2bromobutane), the reported boiling point of the racemic

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Boltzmann factors, the Eyring and Clausius–Claperyon equations, and the Trouton–Hildebrand–Everett rule for the entropy of vaporization as the basis for determining boiling point as a function of pressure. As a learning exercise, students could be led to speculate why no atmospheric boiling points were reported. Perhaps these compounds are unstable and may decompose at their atmospheric pressure boiling point, or perhaps no researcher has determined the atmospheric pressure boiling point of these compounds, or perhaps the boiling point has been determined but deemed uninteresting and not worth publishing, or perhaps the boiling point has been published in a source not commonly included in reference books and online databases. For some compounds, no experimental boiling point was found after checking both CAS STN online, including the databases REGISTRY, MRCK, HSDB, HODOC, DIPPR, and BEILSTEIN (9), and the CRC Handbook of Chemistry and Physics (6, 7). For such compounds, a dash was entered in Tables 1 and 2. For two compounds, the only information found pertaining to boiling point was an indication that these two compounds sublime, in the online version of the CRC Handbook of Data on Organic Compounds (HODOC) (9). These “miss-

Figure 1. Boiling point vs molecular weight for 392 organic compounds.

mixture was entered into Tables 1 and 2. For higher boiling liquids, often reduced pressure boiling points were the only values reported. Many laboratory manuals and textbooks contain nomographs to estimate boiling point as a function of pressure. For higher boiling liquids, the corresponding boiling point at 760 mm Hg was estimated using an online pressure–temperature applet and indicated in the data table by bold font. In constructing the applet, Goodman (10) used

Table 1. Boiling Points (°C) of Common Organic Compounds (R–X) at Atmospheric Pressure X

MW (g/mol)

R

Alkane

Chloride

Methyl ether

H

Cl

-OCH3

1

35.5

Amine

Bromide Aldehyde

-NH2

Br

-CHO

31

16

80

29

Alcohol

Iodide

Methyl ketone

Nitrile

-OH

I

-COCH3

-CN

17

127

43

26

1

᎑253

᎑85

65

᎑33

᎑67

᎑21

100

-35

21

26

CH 3

15

᎑161

᎑24

᎑25

᎑6

4

21

65

42

56

26

CH3CH2

29

᎑88

12

11

17

38

48

78

71

80

82 77

H

CH2=CH

27

᎑104

᎑13

6

56

16

53

---

56

87

CH2=CHCH3

41

᎑48

45

46

53

70

97

97

102

107

78

(CH3)2CH

43

᎑42

35

51

33

59

63

82

89

94

118

CH3CH2CH2

43

᎑42

46

39

48

71

75

97

102

102

97

(CH3)3C

57

᎑12

52

55

46

73

75

83

100

106

106

2-Butyl

57

0

79

60

63

91

92

98

120

117

125

(CH3)2CHCH2

57

᎑12

68

59

68

91

90

108

120

117

131

1-Butyl

57

0

78

70

78

102

103

118

130

128

140

Cyclopentyl

69

50

114

106

107

138

136

140

171

162

169

1-Pentyl

71

36

108

100

102

130

131

137

154

150

162

1-Hexyl

85

69

133

126

130

156

153

158

180

170

186

Cyclohexyl

83

81

142

133

134

166

161

160

202

180

185

1-Heptyl

99

98

160

151

157

180

171

176

204

194

205

Ph

77

80

132

155

184

156

179

182

188

202

191

91

111

179

170

184

198

195

205

242

217

234

1-Octyl

113

125

183

174

180

201

214

195

226

213

199

1-Naphthyl

128

218

260

269

301

280

318

279

302

297

299

2-Naphthyl

128

218

256

274

306

282

309

286

308

300

306

PhCH2

NOTE: For some liquids, only a reduced pressure boiling has been reported, perhaps because the compound is unstable and would decompose at its atmospheric pressure boiling point. For these compounds, an estimated atmospheric boiling point has been calculated using an applet described in ref 10 and the entry in Table 1 is bold. For compounds containing a chiral center, (e.g., 2-butanol) the entry in Table 1 is for the racemic mixture.

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Figure 2. Boiling point vs carbon chain length and functional group.

ing” boiling point data can allow the students to speculate (i) whether the boiling points of these compounds have ever been determined experimentally; (ii) whether their boiling points could ever be determined (e.g., if the compounds are sufficiently stable); (iii) whether the data might be published but not gathered in the widely used handbooks and databases for physical properties of organic compounds; or (iv) whether the lack of boiling point data might indicate that

the uninteresting nature of these compounds have left their properties so far unresearched. The overall relationship between boiling point and molecular weight for the 392 compounds contained in Tables 1 and 2 are shown in Figure 1. These data show the general trend of increasing boiling point as molecular weight increases, but the scatter in the data clearly shows that other aspects of molecular structure affect a compound’s boiling point. Figure 2 shows an example of how extracting a portion of the data in Tables 1 and 2 can be used to compare the boiling points versus carbon chain lengths or functional groups for different families of compounds. Note that Figure 2 has been constructed from the data in Tables 1 and 2 so that the total number of carbon atoms (not merely the carbon atoms in the R group) is being compared. Students can easily construct Figure 2 (or any similar comparisons) to learn that there is generally an excellent correlation of boiling point for a homologous series of compounds with the same functional group. Figure 2 also shows that most different classes of functional groups have a reasonably consistent separation in boiling point at matching carbon chain length. The three isomers of C3H6O2 shown in Table 3 indicate that at the same molecular weight, carboxylic acids have

Table 2. Boiling Points (°C) of Common Organic Compounds (R–X) at Atmospheric Pressure X

R

MW (g/mol)

Me ester

Ether

Acetate

Chloride

-CO2 CH3

-OR

-OCOCH3

-COCl

59

---

59

Et ester Phenyl -CO2 CH2 CH-Ph 3

63.5

73

77

Acid

Amide

Amine

Anhydride

-CO2 H

-CONH2

R3 N

-CO-O-COR

--

--

45

44

1

34

100

118

---

53

80

100

210

᎑33

123

CH3

15

58

᎑25

58

51

77

111

118

222

4

270

CH3 CH2

29

79

35

76

78

99

136

141

213

89

167 205

H

CH2 =CH

27

80

39

72

74

99

146

163

253

---

CH2 =CHCH3

41

106

94

104

101

119

156

163

---

150

218

(CH3 )2 CH

43

90

68

90

92

112

153

154

218

139

182

CH3 CH2 CH2

43

102

89

102

102

120

159

162

224

156

199

(CH3 )3 C

57

101

106

98

106

118

169

164

212

---

193

2-Butyl

57

116

121

112

116

133

174

177

231

---

237

(CH3 )2 CHCH2

57

117

121

112

116

132

171

176

226

192

215

1-Butyl

57

128

142

126

126

144

183

185

225

216

227

Cyclopentyl

69

158

216

180

161

174

219

212

---

---

308

1-Pentyl

71

151

188

149

152

168

205

202

255

236

247

1-Hexyl

85

174

222

171

173

188

226

223

180

264

268

Cyclohexyl

83

180

252

173

207

196

239

232

---

387

535

1-Heptyl

99

194

272

192

195

207

264

240

239

330

345

Ph

77

198

258

196

198

212

255

249

290

348

378

91

218

298

216

237

229

264

265

317

385

374

1-Octyl

113

214

287

210

236

224

262

256

sublimes

366

380

1-Naphthyl

128

395

461

351

322

378

324

300

sublimes

---

---

2-Naphthyl

128

290

426

354

331

386

---

300

---

---

---

PhCH2

NOTE: For some liquids, only a reduced pressure boiling has been reported, perhaps because the compound is unstable and would decompose at its atmospheric pressure boiling point. For these compounds, an estimated atmospheric boiling point has been calculated using an applet described in ref 10 and the entry in Table 2 is bold. For compounds containing a chiral center, (e.g. 2-butyl ether) the entry in Table 2 is for the racemic mixture.

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Table 3. Isomer Analysis for C3H6O2 Boiling Point/°C

Name Propanoic acid

141

Structure CH3CH2COOH

Methyl acetate

058

CH3COOCH3

Ethyl formate

053

HCOOCH2CH3

Table 4. Statistical Analysis of Functional Groups or Carbon Chains -OH

-OCH3

20

0

142

104

Data Analyses

n-Butyl

Number of higher boiling points within pairs

t-Butyl

19

0

128

103

Figure 3. Boiling points of C1 through C8 n-alkyl halides.

overall averages

63

78

54

54

65

᎑25

standard deviation minimum

0

᎑12

286

274

maximum

227

212

95% confidence interval for the mean difference between 29 to 47

paired comparisons (paired t-test)

22 to 29

a substantially higher boiling point than esters. Comparing the columns for -CO2H, -CO2CH3, and -CO2CH2CH3 in Table 2 show that even with higher molecular weights, methyl and ethyl esters have lower boiling points than their corresponding acids in 19 of the 21 carbon chains, the exceptions being the 1- and 2-naphthyl groups where only estimates of their boiling points at 760 mm Hg are entered into Table 2. This analysis can lead to a discussion of the importance of hydrogen bonding in intermolecular interactions. Figure 3 shows the correlation between boiling point and both carbon chain length and functional group for the C1 through C8 alkanes and the corresponding n-alkyl halides for the fluorides, chlorides, bromides, and iodides. For this graph, the boiling points for the n-alkyl fluoride were found in the CRC Handbook of Chemistry and Physics (6) to supplement the data in Tables 1 and 2 prior to constructing Figure 3. From Figure 3, we can conclude that increasing the molecular weight of the carbon chain results in a higher boiling point though the rate of increasing boiling point decreases as the carbon chain length increases. Also, for a given n-alkyl chain, increasing the atomic weight of the halide results in a compound with a higher boiling point. The data in Tables 1 and 2 allow students to hone their analysis skills and see various patterns and correlations between molecular structure and boiling point. Assigning follow up readings (such as Correia for 1-alkyl halides; ref 1 ) can explain structure–property relationships in greater detail. After the students have constructed their own Figure 2 (or similar comparisons), then they are prepared to mathematically model for themselves a limited aspect of the relationship between molecular structure and boiling point. Students can use their own model to predict the boiling points for C9, C10, and other carbon chains, and then compare their predictions to actual boiling point data reported in the literature or experimentally determined for themselves and finally discuss any discrepancies. The use of models for structure–property relationships opens the way for a discussion of the 100

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possibility of misleading predictions when estimating or forecasting beyond the range of a model. Advanced students may construct different mathematical models (e.g., linear or quadratic) and then compare the advantages and drawbacks of each model. Once the students gain these understandings, they are prepared to discuss and investigate how other aspects of molecular structure such as dipole moment, hydrogen bonding, molecular shape or size, and so forth can affect boiling point. The data in Tables 1 and 2 can lead students to explore for themselves these effects by considering sets of isomers, for example the four C4 isomeric side chains. Analyses of the six sets of paired items for the four isomeric C4 side chains across the 19 functional groups in Tables 1 and 2 showed that all pairs except the isobutyl and the 2-butyl pair have a statistically significant difference in boiling point. The data in Tables 1 and 2 form the basis for lessons and exercises in chemistry courses (high school, general college, organic, physical, etc.) and as examples of chemical data for analyses in computer, mathematics, and statistics lessons. These tabulated data can be adapted to a variety of exercises depending on the students’ scientific background, time allocation, and educational goals. These tabulated boiling point data are suitable for both individual and group assignments. Working with actual data reinforces the principles of structure–property relationships while showing that general trends are not universal predictors. Table 4 contains an example as to how the data in Table 1 can be extracted and analyzed at different levels of sophistication to compare either two functional groups or two carbon chains for their corresponding structure–property relationships. Merely calculating averages, ranges, and standard deviations may be less effective for showing the differences between various aspects of molecular structure. Comparing pairs of data (counting head-to-head differences or paired t-tests) can help the students learn to apply the appropriate statistical tool and to understand how various statistical analyses compare with their graphical representations of the same data. The exercise of completing a teacher-prepared abridged version of Tables 1 and 2 may also be an effective teaching tool by leveraging the students’ time and efforts. The complementary benefits of experimental investigation and literature searching are more understandable when students integrate their actual determination of boiling point data in the laboratory with published sources to complete their own larger data set prior to analysis. The instructors’ preparation of an abridged data table and the resources available to students to

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find published boiling points can lead the students to make temperature conversions (e.g., K to ⬚C) and to correct for reduced pressure boiling points. In addition to sharpening their literature-searching skills, students can begin to learn how scientists determine when to conduct their own experiments and when to consult published results. By wisely choosing which compounds to have the students find in the literature, teachers can also reinforce their students’ nomenclature skills, particularly with common names and indices of molecular formulas. Another way to sharpen the students’ literature searching skills would be to assign additional functional groups or other carbon chains to add columns or rows to Tables 1 and 2 as shown in Figure 3 for the n-alkyl fluorides. For example, the 1-methyl vinyl group (CH3⫺CH⫽CH⫺) would lead students to explore the structure–property aspects of cis–trans isomerization and conjugation. An advanced literature searching exercise could involve constructing an entirely new table of physical properties such as water solubility, index of refraction, density, melting point, heat of combustion, dielectric constant, viscosity, or any physical property widely reported for organic compounds. After searching for other physical properties, functional groups, or carbon chains, students will have a better understanding of the “incompleteness” of science and be more prepared to speculate why certain data remain unknown or unpublished. These literature searching exercises may be valuable preparation for laboratory experimentation. If students take note of the original publication date of the physical property data, their lesson can provide a glimpse into the modern history of chemistry. Advanced data analysis exercises may spark a student’s interest in mathematical modeling based on multiple fundamental structural features, an active research area with dedicated journals (11) containing recent articles on determining quantitative structure–property relationships, including for example boiling points (12). Conclusion By providing a concise, well-organized table of the boiling points of 392 organic compounds, this article and the corresponding online resources mentioned previously (7) facilitate inquiry-based instruction in multiple scientific principles including (i) obtaining physical property data, (ii) searching the various types of published literature for physical property data, (iii) analyzing data with varying levels of statistical sophistication, (iv) determining empirical structure– property relationships, and (v) considering how empirical modeling gives insight into fundamental structure–property relationships. Many individual or group learning activities can be derived from this tabulated data based on the instructor’s educational objectives and the students’ backgrounds.

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6.

7.

8.

9.

10.

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