Transesterification of Ethyl-10-undecenoate Using a Cu-Deposited V2O5 Catalyst as a Model Reaction for Efficient Conversion of Plant Oils to Monomers and Fine Chemicals.

Transesterification of ethyl-10-undecenoate (derived from castor oil) with 1,4-cyclohexanedimethanol over a recyclable Cu-deposited V2O5 catalyst afforded 1,ω-diene, the corresponding cyclohexane-1,4-diylbis(methylene) bis(undec-10-enoate), a promising monomer for the synthesis of biobased polyesters, in an efficient manner. Deposition of Cu plays an important role in proceeding the reaction with high selectivity, and both the activity and the selectivity are preserved for five recycled runs by the addition of the substrates. The present catalyst was effective for transesterification with other alcohols, especially primary alcohols, demonstrating a possibility of using this catalyst for efficient conversion of plant oil to various fine chemicals.

Introduction

Subjects on efficient conversion of plant oil attract considerable attention to establish the circular economy as well as to reduce concerns of global warming as alternative feedstocks of fossil fuels.[1−5] Plant oils, generally obtained as fatty acids (FAs) and their esters (FAEs) by chemical modifications, have been considered as a useful renewable feedstock for the synthesis of biofuels,[6−10] biobased aliphatic polyesters,[1,3−5,12−15] and fine chemicals (such as surfactants, cosmetic ingredients, and plasticizers).[1,3−5,16,17] There have been many reports concerning the transesterification of FAs and FAEs for the synthesis of biofuels[6,18−28] and their catalysis study for efficient conversion of fine chemicals,[17,29−37] and many catalysis studies applied for organic synthesis[38−40] have also been known.

As described above, the development of plant oil-derived biobased aliphatic polyesters, which display tunable mechanical properties and biodegradability by precise polymerization techniques, attracts considerable attention. There have been two major pathways for the synthesis, (i) condensation polymerization and (ii) acyclic diene metathesis (ADMET) polymerization and subsequent hydrogenation, and the latter pathway requires transesterification of unsaturated long-chain aliphatic carboxylic acid esters with diols for the synthesis of monomers, 1,ω-diene, through the diester linkage (Scheme ). These monomers, especially derived from methyl (or ethyl) 10-undecenoate, were prepared in the presence of excess 1,1′-carbonyl diimidazole,[32]p-toluene sulfonic acid or Sc(CF3SO3)3,[33] NaOMe,[34] or NEt3 and 4,4-dimethylaminopyridine;[35] these monomers can also be prepared by treatment of the acid chloride with diols in the presence of NEt3.[36,37] Development of a simple catalytic transesterification method should be thus required for the efficient conversion of the unsaturated fatty acid esters not only to monomers for the ADMET polymerization but also to fine chemicals.

Scheme 1

Synthesis of Polyesters from Plant Oils (Unsaturated Long-Chain Aliphatic Esters) via (i) Isomerization Alkoxycarbonylation and Polycondensation or (ii) Acyclic Diene Metathesis (ADMET) Polymerization and Subsequent Hydrogenation[11]

We, therefore, herein report that a Cu-deposited V2O5 catalyst could be a promising candidate for the purpose, especially for selective transesterification of ethyl-10-undecenoate (derived from castor oil) with various alcohols, as exemplified with 1,4-cyclohexanedimethanol (Scheme ). The catalyst could be recycled several times by simply adding substrates without decreasing both the activity and selectivity, and various alcohols could also be used by adopting this catalysis.

Scheme 2

Catalytic Transesterification of Ethyl-10-undecenoate with 1,4-Cyclohexanedimethanol in the Presence of a Cu-Deposited V2O5 Catalyst

Results and Discussion

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Metal-Oxide Catalyst

Table summarizes the results of transesterifications of ethyl-10-undecenoate (1) with 1,4-cyclohexanedimethanol (2) in the presence of various metal oxides (preparation of the oxides, see the Experimental Section). These reactions were conducted at 100 °C without a solvent under rather excess 1 for conversion of 2 (1:2 = 4.0:1.0, molar ratio), and the conversions of substrates (1,2) and the reaction products, corresponding monoester (4, Scheme ) and the diester (3), were analyzed quantitatively by GC in the presence of an internal standard (n-dodecane). The experimental details including typical GC chromatograms and their identifications (synthesis of standards and the nuclear magnetic resonance (NMR) spectra etc.) are shown in the Supporting Information.

Table 1

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2): Effect of Metal-Oxide Catalystsa

		conversionb (%)		yieldb,c (%)
run	catalyst	1	2	3	4	3 + 4
1	La2O3	6	3	0.1	0.3	0.4
2	ZnO	10	16	0.6	13	13.6
3	CuO	6	3	0.1	1.3	1.4
4	SiO2	23	22	0.1	2.5	2.6
5	NiO	2	3	trace	1.1	1.1
6	CeO2	15	5	0.2	3.3	3.5
7	Al2O3	10	5	trace	1.2	1.2
8	Co3O4	25	18	0.1	3.9	4
9	ZrO2	8	3	trace	1.7	1.7
10	Fe2O3	25	14	0.1	3.7	3.8
11	TiO2	26	32	0.3	4.0	4.3
12	MnO2	16	22	trace	1.2	1.2
13	Ta2O5	18	12	0.3	4.4	4.7
14	Nb2O5	16	35	0.3	3.1	3.4
15	SnO2	22	15	0.2	3.3	3.5
16	V2O5	40	94	56	8.2	64.2
17	WO3	20	22	0.1	3.0	3.1

Reaction conditions: 50 mg of catalyst, ethyl-10-undecenoate (1, 4.0 mmol, 849 mg), 1,4-cyclohexanedimethanol (2, 1.0 mmol, 144 mg), 100 °C, 23 h.

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

It turned out that V2O5 (nanosized vanadium pentoxide) prepared by thermal decomposition of vanadyl oxalate in air,[41,42] converted 2 to afford the diester 3 in a moderate yield (run 16), whereas the other metal oxides showed low yields (0.4–4.7%); the selectivity in the reaction by ZnO was rather high (85%, based on 2, run 2) compared to that by V2O5 (68%). As introduced in Table (runs 16, 18), the reaction with V2O5 proceeded with a high conversion of 2 even after 3 h (81%) to afford a mixture of the diester (3) and the monoester (4), and further reaction increased the yield of 3 without decreasing the selectivity. It has been known that certain Lewis acids [such as ZrCl4(THF)2, ZrCl4(THF)2, etc.][38] are effective for transesterification of carboxylic acids,[38] and V2O5 has a Lewis acid site as well as a Brönsted acid site.[41,42] It thus seems likely that V2O5 may play a role as a Lewis acid catalyst.

Table 2

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by Metal-Doped/Deposited V2O5 Catalysts: Effect of Metal Deposition on V2O5a

			conversionb (%)		yieldb,c (%)			select. Ad	select. Be
run	catalyst	time	1	2	3	4	3 + 4	(%)	(%)
18	V2O5	3	27	81	28	26	55	68	76
16	V2O5	23	40	94	56	8	64	68	75
19	Ti–V2O5	3	14	50	5	29	34	68	68
20	Ti–V2O5	23	36	99	44	9	53	53	67
21	Zr–V2O5	3	20	72	10	34	44	61	67
22	Zr–V2O5	23	40	99	56	7	63	64	74
23	Nb–V2O5	3	18	62	10	33	43	69	73
24	Nb–V2O5	23	40	99	57	14	71	72	80
25	Ni–V2O5	3	8	30	1	13	14	47	46
26	Ni–V2O5	23	28	86	19	30	48	56	60
27	Mo–V2O5	3	14	50	5	28	33	65	67
28	Mo–V2O5	23	41	98	65	13	78	79	87
29	W–V2O5	3	21	70	15	41	56	80	82
30	W–V2O5	23	43	99	64	1	65	66	75
31	Mn–V2O5	3	11	39	4	27	31	79	80
32	Mn–V2O5	23	38	100	49	1	49	50	65
33	Fe3+–V2O5	3	6	17	2	14	16	91	80
34	Fe3+–V2O5	23	36	100	38	1	39	39	54
35	Fe2+–V2O5	23	41	100	62	10	72	72	82
36	Co–V2O5	3	8	31	2	21	23	75	77
37	Co–V2O5	23	29	92	20	25	45	49	57
39	Cu–V2O5	3	20	64	18	35	53	82	89
40	Cu–V2O5	23	46	99	85	7	91	92	96
41	Sn–V2O5	3	20	65	11	37	48	73	73
42	Sn–V2O5	23	36	99	41	10	51	51	63
43	Zn–V2O5	3	15	53	3	20	23	44	42
44	Zn–V2O5	23	27	91	14	23	37	41	48
45	Ce–V2O5	3	10	35	3	27	31	87	85

Reaction conditions: 50 mg of catalyst (V2O5 doped with 3.5 mol % metals except for Cu–V2O5, where 3.5 mol % Cu is deposited on V2O5), ethyl-10-undecenoate (1, 4.0 mmol, 849 mg), 1,4-cyclohexanedimethanol (2, 1.0 mmol, 144 mg), 100 °C.

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

Based on alcohol (2).

Based on ester (1).

A series of metal-doped or metal-deposited V2O5 catalysts were thus prepared (details in the preparation procedure are described in the Experimental Section) to improve both the activity and selectivity. Table summarizes the results in the presence of various metal-doped or metal-deposited catalysts (3.5 mol % on V2O5). It turned out that improvements in the yields (3 and 4) were observed when the reactions were conducted in the presence of Nb–V2O5, Mo–V2O5, and Cu–V2O5 catalysts after 23 h (runs 24, 28, 40), whereas the catalysts doped on Mn and Fe3+ initially showed improvement in the selectivity after 3 h (runs 31 and 33), but the yields (total 3 and 4) became low after 23 h (49 and 39%, respectively). No (significant) improvements in both the activity and the selectivity were observed by adding Ti, Zr, Ni, Co, Sn, Zn, and Ce. It should be noted that the reaction by Cu-deposited V2O5 catalyst afforded the diester (3) in a high yield (85%) with high selectivity (92% on the basis of 2, 96% on the basis of 1). It seems that the reaction proceeds with a rather low selectivity (after 3 h, run 39) at the initial stage, but further reaction afforded esters with high selectivity (run 40).

Table summarizes the time course in the transesterification of 1 with 2 in the presence of the Cu–V2O5 catalyst (less catalyst loading from Table ), and the results in the presence of the V2O5 catalyst are also placed for comparison. Figure also shows the plots of the yields and the selectivities over the time course. It turned out that Cu–V2O5 showed improvement in the selectivity compared to V2O5 (runs 46–48 vs runs 49–51), whereas the conversion of 2 after 3 h was low (run 46 vs run 49). Further reaction over V2O5 afforded the products (3 + 4) with a slight decrease in the selectivity (run 48). In contrast, as described above, the reaction by the Cu–V2O5 catalyst initially proceeded with a rather low selectivity (90% on the basis of 2, run 49), which is, however, apparently higher than that by V2O5 (60%, run 46), and further reactions proceeded with high selectivity affording esters in a high yield (91%, run 51) after 16 h; the conversion of 2 reached 90% after 6 h (run 50). It is thus clear that the deposition of Cu on V2O5 was effective, especially in terms of selectivity.

Table 3

Time-Course Dependence in Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Cu-Deposited V2O5 Catalysta

			conv.2b	yieldb,c (%)			select. Ad	select. Be
run	catalyst	time	(%)	3	4	3 + 4	(3 + 4)d	(3 + 4)e
46	V2O5	3	65	7	32	39	60	68
47	V2O5	6	87	14	27	41	48	54
48	V2O5	16	97	33	16	49	50	58
49	Cu–V2O5	3	42	10	27	37	90	91
50	Cu–V2O5	6	90	47	38	85	95	96
51	Cu–V2O5	16	96	73	17	91	95	97

Reaction conditions: 25 mg of catalyst (deposited with 3.5 mol % Cu on V2O5), ethyl-10-undecenoate (1, 4.0 mmol, 849 mg), 1,4-cyclohexanedimethanol (2, 1.0 mmol, 144 mg), 100 °C.

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

Based on alcohol (2).

Based on ester (1).

Figure 1

Time course for transesterification of ethyl-10-undecenoate (1) with 1,4-cyclohexanedimethanol (2) by a Cu-deposited V2O5 catalyst. Data are shown in Table .

On the basis of the results in Tables and 3, Cu–V2O5 catalysts with different Cu contents were prepared to explore the effect of Cu on both the activity and the selectivity. The results conducted for 3, 6, and 16 h are summarized in Table . To check the initial selectivity as well as to explore the catalyst performance, the reactions were conducted with low catalyst loading (10 mg) compared to those conducted in Tables and 3 (25 or 50 mg). TON (turnover numbers) on the basis of the molar amount of metals (Cu and V) was used to evaluate the performance in this catalysis, although all of these metals do not play a role as catalysts.

Table 4

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Cu-Deposited V2O5 Catalyst: Effect of Cu Deposition on V2O5 and Reaction Temperaturesa

	catalyst	temp.	time	conv.2b	yieldb,c (%)			select. Ad	select. Be	TONf
run	(mol %)-Cu	(°C)	(h)	(%)	3	4	3 + 4	3 + 4	3 + 4
52	0	100	3	42	1	13	14	32	33	1.4
53	0.5	100	3	25	6	16	22	86	92	2.5
54	2.5	100	3	20	5	13	18	91	90	2.1
55	3.5	100	3	20	5	13	18	89	92	2.1
56	4.5	100	3	25	6	16	21	86	86	2.5
57	6.5	100	3	17	2	11	13	75	75	1.4
58	10	100	3	22	3	12	15	68	65	1.6
59	0	100	6	72	3	19	23	32	36	2.3
60	0.5	100	6	60	19	32	51	85	88	6.4
61	2.5	100	6	51	15	29	44	86	87	5.3
62	3.5	100	6	49	16	29	45	92	95	5.5
63	4.5	100	6	50	16	28	44	87	87	5.4
64	6.5	100	6	48	11	29	41	85	84	4.6
65	10	100	6	57	22	27	49	85	91	6.4
66	0	100	16	90	9	21	30	33	39	4.5
67	0.5	100	16	99	72	13	85	86	91	14
68	2.5	100	16	97	69	15	84	87	93	14
69	3.5	100	16	97	73	17	90	93	94	15
70	4.5	100	16	98	73	14	87	89	92	14
71	6.5	100	16	99	68	17	85	86	93	14
72	10	100	16	99	67	18	86	86	93	14
73	3.5	60	16	trace						0
74	3.5	80	16	29	8	19	27	93	98	3.2
75	3.5	100	16	97	72	17	89	92	96	15
69	3.5	100	16	97	73	17	90	93	94	15
76	3.5	120	16	>99	81	8	89	89	92	15

Reaction conditions: 10 mg of catalyst (deposited with 0–10 mol % Cu on V2O5), ethyl-10-undecenoate (1, 4.0 mmol), 1,4-cyclohexanedimethanol (2, 1.0 mmol).

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

Based on alcohol (2).

Based on ester (1).

TON (turnovers) = (molar amount of 1 reacted for transesterification)/(molar amount of Cu and V).

It turned out that conversion of the diol (2) in the reaction after 3 h decreased upon addition of Cu (even with 0.5 mol % deposition) with an increase of the selectivity of esters (3,4) on the basis of 2; the selectivity decreased with further deposition (>6.5 mol %, runs 57, 58). The reactions proceeded without significant deactivations in all cases (runs 52–72), affording the esters (3,4) in better selectivity (86–93% based on 2). In terms of yields and selectivity, the Cu–V2O5 catalyst with 3.5 mol % Cu deposition thus showed better catalyst performances (runs 55, 62, and 69). As also shown below (Table ), the catalyst with low Cu deposition (0.5 mol %) showed a lower selectivity compared to that with 3.5 mol %.

Table 5

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Cu-Deposited V2O5 Catalyst: Catalyst Recycling Experiments (1)a

		substrates	time	conv.2b	yieldb,c (%)d,e			select.d	TONe
run	catalyst	1:2 (mmol)	(h)	(%)	3	4	3 + 4	3 + 4
77	V2O5	4.0:1.0	6	87	14	27	41	48	2
78	V2O5	4.0 + 4.0:1.0 + 1.0	6 + 6f	70	13	30	43	61	4.1
79	V2O5	4.0 + 4.0:1.0 + 1.0	6 + 16f	89	29	43	72	80	7.3
80	V2O5g	4.0 + 2.0:1.0 + 1.0	6 + 16g	59	2	19	21	36	4.2
81	Cu–V2O5	4.0:1.0	6	90	47	38	85	94	4.8
82	Cu–V2O5	4.0 + 4.0:1.0 + 1.0	6 + 6f	92	50	40	90	97	10
83	Cu–V2O5	4.0 + 4.0:1.0 + 1.0	6 + 16f	98	84	12	96	98	13
84	Cu–V2O5	4.0 + 8.0:1.0 + 2.0	6 + 16h	96	74	18	91	95	18
60	Cu–V2O5i	4.0:1.0	6	63	19	32	51	85	6.4
85	Cu–V2O5i	4.0 + 2.0:1.0 + 1.0	6 + 16f	91	57	24	81	89	25
62	Cu–V2O5j	4.0:1.0	6	49	16	29	45	92	5.5
86	Cu–V2O5j	4.0 + 2.0:1.0 + 1.0	6 + 16f	89	54	30	84	94	25

Reaction conditions: 25 mg of catalyst (deposited with 3.5 mol % Cu on V2O5), ethyl-10-undecenoate (1, 4.0 mmol), 1,4-cyclohexanedimethanol (2, 1.0 mmol), 100 °C.

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

Based on alcohol (2).

TON (turnovers) = (molar amount of 1 reacted for transesterification)/(molar amount of Cu and V).

After the reaction for 6 h, 1 (4.0 mmol) and 2 (1.0 mmol) were added, and the results were evaluated after an additional 16 h.

Catalyst (V2O5) (10 mg), 1 (2.0 mmol), and 2 (1.0 mmol) were added after 6 h, and the results were evaluated after an additional 16 h.

After the reaction for 6 h, 1 (8.0 mmol) and 2 (2.0 mmol) were added, and the results were evaluated after an additional 16 h.

Catalyst (10 mg; deposited with 0.5 mol % Cu on V2O5).

Catalyst (10 mg; deposited with 3.5 mol % Cu on V2O5).

As summarized in Table , the transesterification did not proceed (or the activity was negligible) at 60 °C (run 73), and the activity increased at high temperatures (80–120 °C, runs 69, 74–76). Since the selectivity decreased at 120 °C, the reactions conducted at 100 °C seem preferred in this catalysis. The results are reproducible under these conditions (runs 69, 75).

Recycled Experiments in Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Cu-Deposited V2O5 Catalyst

To explore the catalyst performance (long-lived, recyclable), ethyl-10-undecenoate (1) and 1,4-cyclohexanedimethanol (2) were further added to the reaction mixture in the presence of a Cu-deposited V2O5 catalyst after 6 h, and the solution was stirred for an additional 6 or 16 h. The results are summarized in Table , and the results using V2O5 are also presented for comparison.

Note that the reactions by the Cu–V2O5 catalyst exhibited high 2 conversion after the additional 6 h even upon further addition of substrates (1,2) without a decrease in the selectivity (runs 81, 82), and further stirring for the additional 16 h afforded the esters (3,4) with high selectivity (98%, run 83). Moreover, the selectivity seems to improve in the additional (recycled, re-feeded) runs (runs 82, 83), probably because, as suggested from the results in Tables –4, the reaction showed a rather low selectivity at the initial stage. Interestingly, the reaction with increased addition of 2 (2.0 mmol in run 84 in place of 1.0 mmol in runs 82, 83) also reached high conversion to afford the esters with high selectivity. These results thus suggest that the present catalyst (Cu–V2O5) can be used in the recycled runs, although it seems difficult to recover the catalyst quantitatively by simple filtration in this reaction scale (slurry conditions with tiny catalyst powder with a small amount).

A similar trend was observed when these reactions were conducted under conditions with low catalyst loading (runs 62, 86). Interestingly, similar reactions using V2O5 (runs 77–79) and Cu(0.5 mol %)-deposited V2O5 (runs 65, 85) catalysts also showed improvements in the selectivity, whereas observed selectivities were apparently lower than those by the Cu(3.5 mol %)-deposited V2O5 catalyst. As also observed in Table , the Cu–V2O5 catalyst with 3.5 mol % Cu deposition thus showed better catalyst performance.

On the basis of the results in Table , the catalyst reusability was checked in this transesterification by the repeat addition of substrates (1, 2.0 mmol; 2, 1.0 mmol) into the reaction mixture after every 16 h (at 100 °C) without the addition of the catalyst. The results after five repeated runs are summarized in Table . The conversions, selectivities, and the turnover numbers in the total and independent runs are shown for evaluating catalyst performances in each recycled run. Figure also shows plots of TON, conversions, and selectivity in each runs.

Table 6

Transesterification of Ethyl-10-undecenoate (1) with 1,4-Cyclohexanedimethanol (2) by a Cu-Deposited V2O5 Catalyst: Catalyst Recycling Experiments (2)a

		yields, selectivity, and TON (total)						yields, selectivity, and TON (independent run)
	recycle	conv.2b	yieldb,c (%)			select.d	TONe	conv.2b	yieldb,c (%)			select.d	TONe
run	runs	(%)	3	4	3 + 4	3 + 4		(%)	3	4	3 + 4	3 + 4
87	fresh	97	73	17	90	93	15	97	73	17	90	93	15
88	1f	96	69	20	89	93	29	93	65	22	87	94	14
89	2f	94	57	30	87	93	39	88	31	48	79	90	10
90	3f	92	52	34	86	93	50	85	29	48	78	92	10
91	4f	92	53	33	86	93	65	81	50	25	75	92	11
92	5f	91	51	33	84	92	74	77	39	31	69	90	10

Reaction conditions: 10 mg of catalyst (deposited with 0–10 mol % Cu on V2O5), ethyl-10-undecenoate (1, 4.0 mmol), 1,4-cyclohexanedimethanol (2, 1.0 mmol), 100 °C, 16 h.

Quantitative analysis by GC using internal standards.

Yields on the basis of 1,4-cyclohexanedimethanol (2).

Based on alcohol (2).

TON (turnovers) = (molar amount of 1 reacted for transesterification)/(molar amount of Cu and V).

After the reaction, 1 (2.0 mmol) and 2 (1.0 mmol) were added into the reaction solution for the recycled runs.

Figure 2

Plots of conversion of 1,4-cyclohexanedimethanol (2), selectivity of esters (3,4), and TONs vs number of catalyst recycled runs in transesterification of ethyl-10-undecenoate (1) with 2 by Cu-deposited V2O5 catalysts. Data are shown in Table .

It turned out that the reactions proceeded without a significant decrease in selectivity (90–94% in runs 88–91), whereas the conversion of 2 seemed slightly decreasing over recycled runs. TON value did not change after two recycled runs (up to five recycled runs, runs 89–91). Reasons for decreases in the activity (TON after 1st recycled run) and the conversion of 2 could be considered as due to the remaining 2 in each runs (which increase the initial molar amount of 2), the changes in the molar ratios (1 and 2), and decrease in the catalyst (and substrate) concentration. Interestingly, no significant decreases in the selectivity could suggest that Cu could be remained on V2O5 to perform the high selectivity. Considering these points, we could conclude that the catalyst performance remained up to five reaction runs, and a TON of 74 has thus been achieved in these catalysis runs.

Transesterification of 1 with 2-phenyl ethanol was conducted under the same conditions [molar ratio of 1:PhCH2CH2OH = 2.0:6.0 (mmol)], and the substrates were further added to the reaction mixture to explore the catalyst performance and reusability; the re-feeding of substrates was conducted twice (Scheme ). The selectivity on the basis of the alcohol initially increased upon feeding but did not change in the second feed [selectivity = 84% (1st run), 94% (2nd run), and 93% (3rd run), calculated on the basis of molar amount of the ester vs conversion of alcohol] without a decrease in the activity (TON), suggesting that the catalyst performance was preserved in this catalysis. The results thus suggest a wide substrate scope, as described below.

Scheme 3

Catalytic Transesterification of Ethyl-10-undecenoate with 2-Phenyl Ethanol in the Presence of a Cu-Deposited V2O5 Catalyst

Substrate Scope in the Transesterification of Ethyl-10-undecenoate (1) with Alcohols by a Cu-Deposited V2O5 Catalyst

On the basis of the results described above, transesterifications of 1 with various alcohols were thus conducted under the same conditions (100 °C, 24 h), and the results are summarized in Scheme .

Scheme 4

Substrate Scope in the Transesterification of Ethyl-10-undecenoate (1) with Other Alcohols in the Presence of a Cu (3.5 mol %)-Deposited V2O5 catalyst,,,,,

Reaction conditions: 10 mg of catalyst (3.5 mol % Cu-deposited V2O5), ethyl-10-undecenoate (1, 2.0 mmol), alcohol (4.0 mmol), 100 °C, 24 h. Yields and selectivity on the basis of ethyl-10-undecenoate (1).

Alcohol 6.0 mmol.

Alcohol 8.0 mmol.

1 (4.0 mmol) and alcohol (1.0 mmol): yield and selectivity on the basis of 1,9-nonanediol.

Reaction 16 h.

Temperature at 150 °C.

The primary alcohols, cyclohexyl methanol, benzyl alcohol, and 2-phenyl ethanol afforded the corresponding esters (5a–c) in high selectivity, and similar trends were observed in the reaction with n-hexanol, 2-methylthioethanol, 3-buten-1-ol, 10-undecen-1-ol to afford the corresponding esters (5e–h), whereas the reaction with 4-methoxybenzyl alcohol showed low activity and selectivity. Although the reaction with 2-ethylbutanol, (oxolan-2-yl)methanol also afforded esters with high selectivities (5j,k), both the conversion and the selectivity were low in the reaction with 2-(2-ethenoxyethoxy)ethanol (for the synthesis of 5i), cyclohexanol (for 5), hexan-3-ol (for 5m), and with 1-phenyl ethanol (for 5n) under these conditions (further optimization of the conditions might be required). As expected in the reaction of 1 with 2, the reaction with 1,9-nonanediol afforded the diester (5o) in high yields. These results thus demonstrate that the present catalyst showed a wide substrate scope, especially for the reaction with primary alcohols (with less steric bulk).

Concluding Remarks

We have shown that transesterification of ethyl-10-undecenoate (1) with 1,4-cyclohexanedimethanol (2) in the presence of a Cu-deposited V2O5 catalyst proceeded with high selectivity to afford esters, and notable decreases in the activity and selectivity were not observed in the five catalyst recycled runs by addition of substrates into the reaction mixture. Deposition of Cu on V2O5 plays a role in exhibiting the high selectivity, and 3.5 mol % seems suitable in this catalysis. The activity was affected by the reaction temperature (100 °C is the most suitable), and the diester, cyclohexane-1,4-diylbis(methylene) bis(undec-10-enoate) (3), was obtained from the monoester, (4-(hydroxymethyl)cyclohexyl)methyl undec-10-enoate (4), over longer reaction hours. The present catalyst was effective for the reaction of 1 with various alcohols, especially primary alcohols, suggesting a scope of efficient conversion of plant oils to fine chemicals and monomers for the synthesis of polyesters in this catalysis. We highly believe that the present catalyst can also be used for various fatty acid esters (FAEs), and we thus believe that the results could introduce a promising possibility of development of the catalysis process, including the design of more efficient catalysts.

Experimental Section

General Procedures

All reactions were carried out in oven-dried glassware. Commercially available chemicals were used without further purification. Chemicals of reagent grades such as ethyl-10-undecenoate >97.0% (GC) and 1,4-cyclohexanedimethanol >99.0% (GC) were purchased from Tokyo Chemical Industry, Co., Ltd., and dodecane (>99.0%), oxalic acid >98% (Titration), ammonium vanadate (V) (special grade reagent), copper(II) nitrate trihydrate >99.0% (Titration) were purchased from Fujifilm Wako Pure Chemical Industries, Ltd., and were used as received. Analytical thin-layer chromatography (TLC) was performed on a Merck TLC silica gel 60 F254 plate, and visualization was accomplished with phosphomolybdic acid stain.

All NMR spectra were acquired on a Bruker AV500 spectrometer (500.13 MHz for 1H, 125.77 MHz for 13C) under an ambient temperature using CDCl3 as the solvent. All chemical shifts were reported in parts per million (ppm) with reference to SiMe4 at 0.00 ppm. The GC analysis was performed on a Shimadzu gas chromatograph (GC-2014) equipped with a flame ionization detector (FID) and DB-1MS column (30 m × 0.250 mm × 0.25 μm) with N2 as the carrier gas under the following thermal conditions. Injector temperature and flame ionization detector temperature was set to 300 and 280 °C, respectively, the column temperature began with a 5 min hold at 110 °C, followed by a linear ramp of 20 °C min–1 to 280 °C and held for 25 min at that temperature. Atmospheric pressure chemical ionization (APCI) mass spectrometry was carried out on a Bruker Micro TOF II-SDT1.

Preparation of V2O5[41]

NH4VO3 (4.97 g, 42.4 mmol) and oxalic acid (11.5 g, 128 mmol) were dissolved in 20 mL of water, and the aqueous solution was stirred for 10 min to obtain the blue vanadium (IV) oxalate solution. Then, the vanadium oxalate solution was heated at 120 °C to evaporate the water. The resulting blue solid was calcined at 300 °C for 4 h twice to obtain the V2O5.

Preparation of Other 3.5 mol % Different Metal-Doped V2O5 Catalysts (3.5 mol % M–V2O5)[41]

V2O5 catalysts doped with different metals (Ni, Ti, Fe2+, Fe3+, Co, Zn, Mn, Zr, Nb, Mo, Sn, Ce, W) were prepared using the impregnation method. In general, V2O5 catalyst doped with 3.5 mol % (with respect to V2O5) metal [NiCO3, Ti[OCH(CH3)2]4, Fe(C2O4)·2H2O, Fe(NH3)3(C2O4)3·3H2O, Co(CO2)2·2H2O, Zn(NO3)2·6H2O, Mn(CO3)2, Zr(H2N2O8), Nb(HC2O4)5·xH2O, (NH4)6Mo7O24·4H2O, Sn(C2O4), Ce2(C2O4)3·9 H2O, (NH4)6H2W12O40·nH2O] was prepared by dissolving a prescribed amount of metal precursor in the blue vanadium(IV) oxalate solution. The vanadium(IV) oxalate solution was prepared by dissolving oxalic acid (128 mmol, 11.5 g) and ammonium vanadate (42.4 mmol, 4.97 g) in 20 mL of water, followed by 10 min stirring at room temperature. The mixture was stirred at 120 °C until the complete removal of water. The obtained solid was calcined at 300 °C for 4 h twice to obtain the metal-doped V2O5 catalysts.

Preparation of the Cu-Deposited V2O5 Catalyst (0.5, 2.5, 3.5, 4.5, 6.5, and 10 mol % Cu–V2O5)

To prepare the 3.5 mol % Cu–V2O5 catalyst, 0.12 mmol of copper precursor [Cu(NO3)2·3H2O (28.8 mg)] was dissolved in 20 mL of water, and then 3.29 mmol V2O5 (300 mg) was added to this solution. The mixture was stirred at 120 °C until the complete evaporation of water. The obtained solid was calcined at 300 °C for 4 h, twice to obtain the Cu (3.5 mol %)–V2O5 catalyst. The other Cu–V2O5 catalysts (0.5, 2.5, 4.5, 6.5, and 10 mol % of Cu with respect to V2O5) were prepared by the same procedure.

General Procedure for the Transesterification of Ethyl-10-undecanoate

An oven-dried reaction tube equipped with a magnetic stirring bar was charged with a prescribed amount of catalyst (10 mg), ethyl-10-undecenoate (1, 4.00 mmol, 849 mg), and 1,4-cyclohexanedimethanol (2, 1.00 mmol, 144 mg). The reaction mixture was then heated under solvent-free conditions at 100 °C for a prescribed time in an Eyela Personal Synthesizer (ChemiStation). After completion of the reaction, the mixture was cooled down to room temperature, diluted with 5 mL of CHCl3, and the catalyst was separated out by centrifugation. The centrifugate was analyzed with a gas chromatogram using dodecane as an internal standard to determine the conversion and the yield.