The formation of carbon–sulfur bonds is an important reaction in synthetic chemistry,
as this motif is found in numerous natural products, pharmaceuticals, polymers, and
semiconductors.[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8] The most common methods to achieve (C–S) bond formation have utilized transition-metal
thiol cross-couplings;[9–11] however, these methods typically involve harsh reaction conditions, high temperatures,
and require pre-functionalization of the substrate. It would be more desirable to
directly functionalize the C–H bond without any intermediate transformation. Direct
C–H thiolation has been previously achieved through electrophilic aromatic substitution
(SEAr) utilizing activated sulfenyl sources such as sulfenyl halides or N-thiosuccinimides.[12]
[13]
[14]
[15]
[16] These reactions are limited primarily to electron-rich aromatics and heterocycles
such as substituted indoles. We have recently reported methodologies that function
via a Lewis base/Brønsted acid dual catalytic system that allow for the C–H sulfenylation
of diverse arenes.[17]
[18] One drawback to this approach is that the formation of activated sulfenyl sources
is often cumbersome; thus, methods that could activate readily available thiols in
situ would represent a welcome advancement.
Scheme 1 Previous photocatalytic and electrochemical methodologies for C–H thiolation of thioamides
to benzothiazoles and various electron-rich heterocycles
Over the past decade, radical chemistry, specifically photoredox catalysis and electrochemistry,
has risen as a popular and powerful tool for C–H functionalization.[19]
[20]
[21]
[22] The radical species acts as a highly reactive intermediate, which enables synthetic
transformations which normally cannot be assessed under reaction conditions involving
polar pathways.[23]
In the past five years, there have been multiple accounts of C–H thiolation employing
the use of photoredox catalysis (Scheme [1]). In 2015, Lei showed that benzothiazoles can be synthesized using a Ru(bpy)3(PF6)2/Co dual catalytic system.[24] Similarly, Xu reported a similar benzothiazole transformation from thioamides using
a TEMPO-catalyzed electrochemical C–H thiolation.[25] Alternatively, Barman and Fan both independently reported the use of Rose bengal
and thiophenol for the sulfenylation of 3-substituted indoles and imidazopyridines,
respectively.[26]
[27] Recently, König and Rehbein showed that electron-rich arenes (such as trimethoxybenzenes)
could react with diaryl and dialkyl sulfides with an iridium photocatalyst and a persulfate
salt to provide arylthiols.[28] Herein, we report an oxidative photocatalytic thiolation to synthesize benzothiazoles
through an intramolecular synthesis from thioamides, as well as the intermolecular
sulfenylation of substituted indoles (Scheme [2]).
Scheme 2 Synthesis of benzothiazoles and sulfenylated indoles from oxidative photocatalytic
conditions
Notably, mechanistic studies via cyclic voltammetry and density functional theory
calculations suggest that even though both reactions use similar conditions, they
proceed with markedly different roles for the sulfur, with an electrophilic sulfur
radical in the benzothiazole formation, and a nucleophilic sulfur radical in the indole
sulfenylation.
While studying whether the Lewis basic thioamide in 1a could act as a directing group for ortho- chlorination via SEAr using Hu’s photocatalytic chlorination conditions[29] we observed a significant amount of benzothiazole 1b (Table [1], entry 1). Interestingly, removal of the sodium chloride provided a small increase
in conversion of 1a into 1b, suggesting this chemistry occurred via a substrate oxidative mechanism rather than
sulfur activation through the halogen source (Table [1], entry 2). Removal of both the Ru(bpy)3Cl2 (Table [1], entry 3) and sodium persulfate (Table [1], entry 4) resulted in a significant decrease in conversion; however, there is a
still a small benzothiazole background reaction in the presence of persulfate. We
then continued our optimization with an evaluation of other common photocatalysts.
Because we utilized a 390 nm LED blue light source, we hypothesized that Ru(phen)3Cl2 (Imax = 422 nm) would be in a higher absorbance range relative to Ru(bpy)3Cl2 (Imax = 452 nm). However, conversion of the benzothiazole was low at only 15% (Table [1], entry 5). Switching from a transition metal to an organic photocatalyst 4CzIPN
also provided no improvement in conversion (Table [1], entry 6), possibly due to the reaction being performed in a biphasic solvent system.
Surprisingly, {Ir[dF(CF3)ppy]2(dtbpy)}PF6, which has a higher oxidizing potential in its excited state [(Ir(III)*/Ir(II) = 1.21
V vs SCE] relative to Ru(bpy)3Cl2 [Ru(II)*/Ru(I) = 0.77 V vs SCE] and would be expected to oxidize 1a more effectively, proved markedly worse than the ruthenium catalyst (Table [1], entry 7). Mechanistically, this implies that while the photocatalyst has a significant
effect on the overall conversion of the reaction, its excited state does not directly
oxidize the thioamide but rather likely activates the persulfate as a better oxidizing
agent (see proposed mechanism). Testing solvent conditions, we observed a decrease
in conversion when switching to a more organic composition of MeCN/H2O (9:1), suggesting aqueous media is necessary to help solubilize the persulfate salt
(Table [1], entry 8). To see if circumventing persulfate activation was a possibility, we added
excess amount of sodium persulfate (Table [1], entries 9 and 10); however, we only obtained the acetanilide side product, which
is a common degradation product for thioamides under oxidative conditions. Finally,
we observed that benzothiazole conversion could be improved markedly (up to 79%) by
the addition of two equivalents of pyridine as a base.
Table 1 Optimization of Intramolecular Benzothiazole Synthesis of 2,2-Dimethyl-N-phenylpropanethioamidea
 
|
|
Entry
|
Catalyst
|
Oxidant (equiv)
|
Additive (equiv)
|
Solvent
|
Conversion (%)b
|
|
1
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
NaCl (3)
|
MeCN/H2O (1:1)
|
52
|
|
2
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (1:1)
|
57
|
|
3
|
Ru(bpy)3Cl2
|
none
|
none
|
MeCN/H2O (1:1)
|
0
|
|
4
|
none
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (1:1)
|
5
|
|
5
|
Ru(phen)3Cl2
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (1:1)
|
15
|
|
6
|
4CzIPN
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (1:1)
|
30
|
|
7
|
{Ir[dF(CF3)ppy]2(dtbpy)}PF6
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (1:1)
|
20
|
|
8
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
none
|
MeCN/H2O (9:1)
|
34
|
|
9
|
Ru(bpy)3Cl2
|
Na2S2O8 (5)
|
none
|
MeCN/H2O (1:1)
|
0 (1c obtained)
|
|
10
|
Ru(bpy)3Cl2
|
Na2S2O8 (10)
|
none
|
MeCN/H2O (1:1)
|
0 (1c obtained)
|
|
11
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
pyridine (2)
|
MeCN/H2O (1:1)
|
79
|
aReactions were performed on a.130 mmol scale (approximately 25 mg) with 5 mol% photocatalyst
loading in 1 mL of solvent mixture of MeCN/H2O.
bConversions were measured by NMR integrated spectra; the results are reported as an
average of two trials. See Supporting Information for the details.
We decided to evaluate our conditions from Table [1], entry 11 across a variety of substituted thioamide derivatives (Scheme [3]). To confirm our initial hypothesis, we tested the substrates in the absence and
presence of pyridine and obtained isolated yields of the benzothiazoles. Varying the
electronics at the aryl ring R1 (2a–5a) provided minor decreases in yield relative to the unsubstituted 1a (isolating between 49–63% yield for 2b–5b). Notably, we observed no effect when adding pyridine for naphthyl-based substrate
6a (54% with no pyridine, 55% with pyridine for 6b) and substrate 7a (32% without, 34% with pyridine for 7b). This lack of pyridine effect held for other substrates that possessed these aryl
groups 9a (43% no pyridine, 38% with pyridine for 9b), and 15a (31% no pyridine, 30% with pyridine for 15b). Replacing the thioamide tert-butyl group 1a with a phenyl group in 8a resulted in a marked decrease in yield (79% to 32% of 8b); however other phenyl-containing thioamides resulted in decent yields (i.e., 10a resulted in 68% yield 10b). Finally, when we replaced the thioamide substitution with aliphatic groups other
than tert-butyl (11a–14a), we isolated the corresponding benzothiazoles in good yield (55–73% 11b–14b). Surprisingly, when the thioamide substitution was a methyl (16a) we only isolated the corresponding amide. Alternatively, when we evaluated trifluoromethyl
containing 17a, we observed no reaction of any kind, perhaps due to the thioamide being significantly
more electron poor and possessing a higher redox potential, or a lower innate nucleophilicity.
Scheme 3 a Reactions were performed on a 0.130 mmol scale (approximately 25 mg of a) with 5 mol% Ru(bpy)3Cl2, 2 equiv of Na2S2O8, 2 equiv of pyridine, in 1 mL solvent mixture of MeCN/H2O. b Isolated yields were reported as an average of two trials.
Scheme 4Cyclic voltammetry (CV) measurements of substrate 1a with variation in potential scan rate (a) and with pyridine additive (b). Both processes
show two oxidation peaks in an irreversible process. Increasing the scan rate shows
disappearance of the second oxidation peak, implying a chemical reaction step between
the first and second oxidation towards product formation. Titration of pyridine shows
a lowering of both oxidation potentials. CV experiments were run vs Ag wire reference
electrode, a glassy carbon working electrode, and a platinum counter electrode, followed
by standard conversions to saturated calomel electrode (SCE). (c) A proposed mechanism
for intramolecular benzothialation is shown, with electron-density maps derived from
density functional theory (DFT) structure optimizations. The key experiments suggest
an initial oxidation at the sulfur to form the thiyl radical cation, which then undergoes
intramolecular cyclization. Coordination of the pyridine additive to the substrate
lowers the first half-wave oxidation due to coordination with the N–H thioamide bond,
providing a more favorable single-electron-transfer process.
To explain the subsequent transformation, we propose the following mechanism (Scheme
[4]), which is supported by several key experiments. Due to the increase in yield upon
addition of pyridine, we believe there is a Lewis base effect wherein the pyridine
coordinates to the N–H thioamide bond, providing extra stability to the radical cation
that forms upon initial oxidation. This hypothesis is substantiated through cyclic
voltammetry experiments on substrate A. In pure acetonitrile without the presence of additive base, we observed two half-wave
oxidation potentials at 1.5 V and 1.9 V vs SCE, meaning both values are out of the
range of the Ru(bpy)3Cl2 reduction potential in its excited state [Ru(II)*/Ru(I) = 0.77 V vs SCE]. Upon titration
of pyridine, we noticed a distinct shift in the two oxidation potentials to 1.2 V
and 1.5 V vs SCE. Interestingly, the first oxidation potential of A with pyridine is now within the range of the ground-state reduction potential of
Ru(bpy)3Cl2 [Ru(III)/Ru(II) = 1.29V vs SCE]. This suggests that, in its excited state, the photocatalyst
reduces persulfate to the SO4
2– anion and the SO4
•– anion radical, followed by the resultant Ru3+ complex oxidizing the thioamide substrate to radical cation B. Additionally, we utilized density functional theory (DFT) calculations to predict
the electron-density maps for several thioamide intermediates and consequently predict
the most favorable sites for oxidation. In the first map, we see a large concentration
of electron density at the sulfur relative to the rest of the molecule A, implying it is the most favorable site for initial oxidation; this pathway is also
supported by recently reported work from Nicewicz on allylic thioamides.[32]
[33]
At this point, B will likely undergo radical cyclization to C. This is supported by CV scan-rate experiment; as we sweep from 0.1 V/s to 5 V/s,
the second half-wave oxidation peak begins to diminish and completely disappears at
the highest scan rate. One explanation for this observation is there is a new intermediate
reaction between the first and second oxidation (i.e., thioamide cyclization) and
that faster voltage sweeps can kinetically outpace the reaction, thereby hindering
subsequent oxidation. Additionally, the predicted electron map of B suggests that the sulfur is now more electron deficient compared to the aryl ring;
thus, it is likely that the cyclization will occur via the arene acting as a nucleophile
and the sulfur acting as an electrophilic radical. Due to the comparable yields of
electron-deficient thioamides without the presence of pyridine (i.e., 10a), we believe that the additive is beneficial towards initial oxidation but not necessary
as persulfate can also promote formation of the thiyl radical cation; it is the subsequent
radical cyclization which drives the reaction favorably towards the benzothiazole
product. Upon cyclization, the electron-density map shows a more electron-rich intermediate
which should be easily oxidized by the persulfate radical anion to give Wheland arenium
ion D, which will rapidly undergo aromatization to the final product E.
We also explored whether our methodology for intramolecular C–H thiolation could be
applied to other arenes for intermolecular functionalization, specifically the sulfenylation
of electron-rich heterocycles such as indoles. Our initial experiment utilized our
optimized conditions for benzothiazole synthesis without pyridine, using 18a melatonin as the substrate and 4-methyl thiophenol as the sulfenylating reagent,
and obtained 29% yield of 18b (Table [2], entry 1). Upon addition of pyridine (Table [2], entries 2 and 3), we observed a similar trend as the yields increased to 40%. Just
like the previous reaction, removal of the photocatalyst diminishes the yield significantly
to 8% (Table [2], entry 4), however, there is still a background reaction from just persulfate exclusively.
Interestingly, reintroduction of the photocatalyst but cutting the persulfate equivalent
in half reduced the overall yield to 5% (Table [2], entry 5). As expected, complete removal of persulfate provides no reaction (Table
[2], entry 6).
Table 2 Optimization of Intermolecular Sulfenylation of Melatonin with 4-Methyl Thiophenol
(18a)a
|
|
Entry
|
Catalyst
|
Oxidant (equiv)
|
Additive (equiv)
|
Solvent
|
Conversion (%)b
|
|
1
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (0)
|
29
|
|
2
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (1)
|
31
|
|
3
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
40
|
|
4
|
none
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
8
|
|
5
|
Ru(bpy)3Cl2
|
Na2S2O8 (1)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
5
|
|
6
|
Ru(bpy)3Cl2
|
none
|
MeCN/H2O (1:1)
|
pyridine (2)
|
0
|
|
7
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
MeCN/H2O (9:1)
|
pyridine (2)
|
30
|
|
8
|
Ru(bpy)3Cl2
|
Na2S2O8 (2)
|
MeCN
|
pyridine (2)
|
15
|
|
9
|
CzIPN
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
25
|
|
10
|
9-Mesi-Acri
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
8
|
|
11
|
{Ir[dF(CF3)ppy]2(dtbpy)}PF6
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
pyridine (2)
|
52
|
|
12
|
{Ir[dF(CF3)ppy]2(dtbpy)}PF6
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
K2HPO4 (2)
|
61
|
|
13
|
{Ir[dF(CF3)ppy]2(dtbpy)}PF6
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
K3PO4 (2)
|
28
|
|
14
|
{Ir[dF(CF3)ppy]2(dtbpy)}PF6
|
Na2S2O8 (2)
|
MeCN/H2O (1:1)
|
KOH (2)
|
68
|
aReactions were performed on a 0.130 mmol scale (approximately 25 mg 18a) with 5 mol% photocatalyst loading in 1 mL of solvent mixture of MeCN/H2O.
bConversions were measured by NMR integrated spectra; the results are reported as an
average of two trials. See Supporting Information for more details.
Similar trends also hold for changing the ratio of solvents, as we see almost no variation
going from 1:1 to 9:1 MeCN/H2O, and a lowering of 15% yield switching to completely acetonitrile (Table [2], entries 7 and 8). After evaluating a number of photocatalysts (Table [2], entries 9–11), we observed that {Ir[dF(CF3)ppy]2(dtbpy)}PF6 gave a much higher yield at 52% compared with Ru(bpy)3Cl2. Finally, variation of the base to potassium hydroxide (Table [2], entries 12–14) provided an increase of yield to 68%. Interestingly, we noticed
a trace amount of a disulfenylated side product 18c when the iridium photocatalyst is used, suggesting that at some point the thiophenol
reagent (or product sulfide) is oxidized and reacts with a second equivalent of thiophenol.
Scheme 5 Sulfenylation of various substituted indoles. Both the mono- and disulfenylated product
were obtained on a substrate-dependent basis, with most substrates providing exclusively
the monosulfenylated product. Reactions were performed on a 130 mmol scale (approximately
25 mg) with 2.5 mol% photocatalyst in 1 mL of solvent mixture of MeCN/H2O. Isolated yields are reported as an average of two trials. See Supporting Information
for more details.
With our optimized conditions, we evaluated a number of substituted indoles and report
the isolated yields of both the mono- and disulfenylated product, with a majority
of substrates providing exclusively the monosulfenylated product in 9–36% yield (Scheme
[5, 19–24]). Similar to melatonin, N-methyl 3-methylindole (20a) also gave a mixture of monosulfenylated 20b and disulfenylated 20c (28% and 14%, respectively) Additionally, we tested a number of benzenethiol reagents
(25a–27a) and varied the electronics off the aryl ring; this gave attenuated yields ranging
from 16–31% yield (25b–27b). While these yields are moderate compared to other conditions (both via traditional
SEAr, and photocatalysis), we find it notable that this sulfenylation worked on biologically
relevant scaffolds such as melatonin and tryptophan. We also found this transformation
mechanistically interesting as the conditions were nearly identical to those of the
benzothiazole synthesis and performed a series of mechanistic studies.
Scheme 6 (a) Stern–Volmer quenching plots of the {Ir[dF(CF3)ppy]2(dtbpy)}PF6 with melatonin, 4-methylbenzenethiol, and 4-methyl diphenyl disulfide, shown with
Ksv values. (b) Proposed mechanism pathways for the intermolecular sulfenylation of indoles.
Deprotonated thiophenol can nucleophilically attack the oxidized indole (pathway 1)
or homolytically couple to the radical indole to obtain the substituted product.
We first determined the experimental redox potentials of melatonin and 4-methylbenzenethiol
sulfenylating reagent. We observed that the melatonin 18a has a first half-wave oxidation potential of 1.10V vs SCE while the latter has a
higher half-wave oxidation potential of 1.49 V vs SCE (see Supporting Information).
Consequently, in its excited triplet state, the {Ir[dF(CF3)ppy]2(dtbpy)}PF6 photocatalyst would be out of the potential range for oxidation of 4-methylbenzenethiol,
and initial oxidation likely occurs at melatonin to form the cation radical F. Stern–Volmer quenching studies between the iridium photocatalyst, melatonin, and
4-methylbenzenethiol supports this hypothesis as melatonin (Ksv = 4.2 M–1L) is quenched at a much higher rate than the thiophenol (Ksv = 0.1 M–1L) (see Scheme [6] and Supporting Information). Additionally, we ran the photocatalytic reaction in
the absence of indole, observing a significant amount of the disulfide byproduct,
which is known to undergo homolytic cleavage under UV light to form the thiyl radical.[35] To test whether the disulfide was an intermediate, we evaluated the reaction using
phenyl disulfide as the sulfur source, observing comparable yields to that of thiophenol.
Stern–Volmer quenching of the photocatalyst with 4-methyldiphenyl disulfide provided
a slight increase (Ksv = 0.6 M–1L) relative to the thiophenol but still significantly less than melatonin. To confirm
out findings, we ran a sulfenylation cross experiment using both 4-methylbenzenethiol
and phenyl sulfide, observing the methylated indole as the main product via mass spectrometry
(see Supporting Information). Based on these experiments, two plausible simultaneous
mechanisms can occur. Once indole cation radical F is formed, deprotonated thiophenol can nucleophilically attack F to form radical intermediate G, which will be oxidized by persulfate and aromatize to form the sulfenylated product
18b (Scheme [6], pathway 1). Alternatively, under photocatalytic conditions, thiophenol can be converted
into disulfide which can homolytically disassociate to form the thiyl radical. The
radical can undergo radical coupling with F to form Wheland intermediate H, followed by aromatization to form product 18b. Both pathways can occur simultaneously; however, we believe that the nucleophilic
pathway is predominant as shown by Stern–Volmer quenching studies and sulfenylation
cross experiment.
In conclusion we have developed an operationally simple and economical method to synthesize
benzothiazoles via photocatalytic C–H thiolation and have extended these conditions
to indole sulfenylation.[36] We performed mechanistic studies that suggest that the sulfur displays divergent
activities (nucleophilic or electrophilic radical) in the two reactions.
