Andrew M.
Hickman
ab,
Nikola
Chmel
c,
Neil R.
Cameron
bd,
Daniel J.
Keddie
e and
Tara L.
Schiller
*ab
aWMG, University of Warwick, Coventry CV4 7AL, UK. E-mail: T.L.Schiller@warwick.ac.uk
bDepartment of Materials Science and Engineering, Monash University, 22 Alliance Lane, Clayton 3800, Victoria, Australia
cDepartment of Chemistry, University of Warwick, Coventry CV4 7AL, UK
dSchool of Engineering, University of Warwick, Coventry CV4 7AL, UK
eFaculty of Science and Engineering University of Wolverhampton, Wolverhampton WV1 1LY, UK
First published on 21st July 2021
We investigate the preparation of polysiloxane-based networks under solvent-free, ambient conditions using the Lewis acid catalysed Piers-Rubinsztajn (PR) reaction of hydride-terminated siloxanes with various tetrafunctional alkoxysilanes (tetraethoxysilane, tetrapropoxysilane, tetra-n-buxoxysilane, tetra-s-butoxysilane, tetra-s-butoxysilane, and tetrakis(2-ethylbutoxy)silane) as crosslinkers. We explore the effects of polysiloxane chain length and crosslinker alkyl group on the rheological performance of the elastomers. By analysing the reaction progress by grazing angle Fourier-transform infrared spectroscopy (FTIR) and determining the rheological properties of the resulting materials, we show that the use of linear or branched alkoxysilanes strongly influences the morphology and properties of these network polymers. We have shown the PR process can be tailored to reliably produce homogeneous, polysiloxane network materials. This work provides information on the relative rates of network formation under ambient conditions with an emphasis on the impact of crosslinker alkyl chain length. Our results show that electronics and sterics both play critical roles in influencing the rate of the curing reaction. Crucially, we newly demonstrate the benefit of a having tertiary carbon α to the SiO reaction centre, as is the case for the tetra-s-butoxysilane crosslinker, for delivering exceptionally rapid network cure and a concomitant enhancement in storage modulus of the resultant materials.
Current methods of polysiloxane-based network preparation is comprised of three main techniques: tin-catalysed moisture cure; high-temperature radical cure; and platinum-catalysed hydrosilylation.8 Achieving reproducibility in elastomeric properties is difficult through high-temperature radical cure.7 Tin-based catalysed reactions offer greater accuracy for material properties but as there is potential for environmental harm from tin residues, other routes are more desirable.4,9 Platinum-catalysed hydrosilylation is an efficient reaction, able to proceed at low catalyst loadings of ≤30 ppm and resulting in no by-products.10 Platinum-based catalysts are expensive, with Pt accounting for approximately 30% of the material cost.11 The catalyst is retrievable, however the recovery process is difficult and inefficient, with only 10–15% of Pt catalyst being reusable.12
A newer method for making siloxane bonds is the Piers-Rubinsztajn (PR) reaction. This reaction does not require transition metal catalysts and importantly proceeds efficiently at room temperature.13 Initial use of PR reaction for siloxane bond formation was displayed as polysiloxane production by coupling dihydridosilanes with dialkoxysilanes through a polycondensation reaction.13
The PR reaction proceeds through the complexation of the Lewis acid, B(C6F5)3, with a Si–H intermediate A (see Scheme 1).14,15 Addition of an alkoxysilane to this intermediate leads to the reversible formation of the hydridosilane oxonium complex B (Scheme 1). From intermediate B there are three potential pathways: (i) dissociation back to starting reagents (black pathway, Scheme 1); (ii) reductive elimination of the alkyl group, resulting in the desired siloxane formation and alkane by-product (blue pathway, Scheme 1); and (iii) undesired metathesis of the complex, transferring of the hydride to produce a new hydridosilane and alkoxysilane (red pathway, Scheme 1). Experimental evidence shows negligible metathesis, with siloxane formation the predominant outcome (pathway (ii) Scheme 1).16,17
Scheme 1 The reaction pathways for Piers-Rubinsztajn reaction.17 |
In the context of siloxane-based polymeric materials, the metal-free Lewis acid PR reaction has demonstrated utility for siloxane network formation.18–20 This reaction leads to a gaseous alkane by-product, which influences network formation and can lead to fragile foams.21 With this is mind, we sought to develop methods for reproducible gels, without foaming, under atmospheric conditions with a view to a wider scope of application for these materials.
In this paper we consider the impact of crosslinker alkyl chain length on rates of solvent-free gel network formation. The resultant materials, characterised by rheometry and FTIR, provide insights on the factors which influence the properties of the resultant networks.
Following our initial successes, we then sought to prepare siloxane elastomers, without foaming, via the PR reaction. here we investigated the impact of the tetraalkoxysilane crosslinker alkyl chain length on rate of gelation as well as the resultant materials properties. To avoid the foaming seen in the previous samples, we ascertained that the rate of reaction needed to be low enough to allow the bulk of gas evolved from the reaction to escape during network formation, but remain sufficiently high to allow for complete cure. In this context, we first sought to reduce the rate of reaction by lowering the B(C6F5)3 catalyst concentration, in relation to conditions reported in previous studies.21,23 These experiments (see Table S1†) showed that, as expected, the B(C6F5)3 catalyst concentration greatly influences the rate of reaction (including gaseous alkane production). The initial reactions discussed above were undertaken using a relatively high catalyst amount (2 × 10−3 mmol; 20 μL of 0.1 M stock solution). These resulted samples that were brittle and highly-disordered, open celled foams (see Fig. S1(a)†). Brook et al.21 have reported comparable outcomes when studying the same mechanism. In their study an increase in crosslinker alkyl chain length, from methyl to propyl, resulted in reduced foaming with the materials having a more closed cell, disordered appearance, as evidenced by SEM.21
Upon decreasing the amount of B(C6F5)3 catalyst (5 × 10−4 mmol; 50 μL of 0.01 M stock solution) we observed a reduced the rate of cure, with the reactions producing either partially foamed samples or gels with voids (see Fig. 1(a)). Further reduction of catalyst using aliquots (2 × 10−4 mmol; 20 μL of 0.01 M stock solution) proved effective at reducing voids, enabling production of defect-free elastomers (see Fig. 1(b)). Thus, this was the amount of catalyst used for all subsequent elastomer preparations.
In all of the reactions discussed above, n-hexane was used as a solvent; it also acts as a heat sink for the exothermic PR reaction. However, due to its volatility, n-hexane can affect the outcome of the polysiloxane material produced by acting as a blowing agent,21 increasing the likelihood of foamed products. This was observed for our samples.
Upon changing the solvent from n-hexane to n-heptane we observed a reduction in visual gas evolution during the PR curing. This led to a decrease in voids present within the elastomers (not shown). Note, the boiling point of n-heptane is ∼30–40 °C greater than n-hexane,24 and the difference in the latent heats of vaporisation of approximately 10 kJ mol−1; n-heptane reduces the volume of additional gas produced during the PR curing under otherwise the same reaction conditions.
The cured samples prepared using either n-hexane or n-heptane were found to contract following solvent evaporation which led to sample fracture (possibly due to increased strain present within the network in a contracted state). Omission of solvent from the reaction mixtures was investigated in an attempt to overcome this problem. Without solvent, a reduction in swelling and a decreased incidence of sample fracture was observed. While the occurrence of voids was not completely eliminated, solventless reactions were deemed the best approach for preparing our samples; all samples discussed in subsequent sections were prepared without solvent.
Pre- and post-cure grazing-angle FTIR for the samples prepared from PDMS 1a was first undertaken. Absorbance peaks at 2126 cm−1 and 907 cm−1, were not found in the post-cure measurements (see Fig. 2, top), indicating consumption of Si–H27,28 groups. Complete cure was estimated for systems using 1a with ethyl 2, propyl 3, n-butyl 4 or s-butyl 6 (see entries 1–3 & 5, Table 1), achieving almost full consumption of Si–H functional groups PDMS 1a with ethyl 2 (see entry 1, Table 1; Fig. 3(a)) reacted rapidly, indicated by sharp increase in modulus at ∼30 seconds, this was followed by a gradual increase to a plateau modulus of 82 kPa.‡
Fig. 3 Time-resolved rheology gelation curves over 200 seconds shown by G′ and G′′ for elastomers derived from PDMS 1a and the (a) ethyl 2 note differing transition to plateau by gradual increase in modulus, (b) propyl 3, (c) n-butyl 4, and (d) s-butyl 6 alkoxysilane (also see entries 1–5, Table 1). Note the omitted data as per Table 1. |
Entry | Hydride-terminated PDMS | Tetraalkoxysilane | Conversionc (%) | G′d (kPa) |
---|---|---|---|---|
a PDMS 1aMn = 800 g mol−1, [1a] = 1.7 mmol, [alkoxysilane] = 0.8 mmol, [B(C6F5)3] = 2 × 10−4 mmol. b PDMS 1bMn = 1170 g mol−1, [1b] = 0.85 mmol, [alkoxysilane] = 0.4 mmol, [B(C6F5)3] = 1 × 10−4 mmol. c Conversion % based on consumption of Si–H (2126 cm−1) calculated by % = 100 − (((post-cure absorbance)/(pre-cure absorbance)) × 100). d Peak storage modulus obtained from rheology analysis. e Not measured due to insufficient cure. | ||||
1a | 1a | 2 (ethyl) | 100 | 82.0 |
2a | 1a | 3 (propyl) | 100 | 38.4 |
3a | 1a | 4 (n-butyl) | 100 | 32.6 |
4a | 1a | 5 (2-ethylbutyl) | 38 | —e |
5a | 1a | 6 (s-butyl) | 99 | 137 |
6b | 1b | 2 (ethyl) | 98 | 444 |
7b | 1b | 3 (propyl) | 94 | 241 |
8b | 1b | 4 (n-butyl) | 100 | 337 |
9b | 1b | 5 (2-ethylbutyl) | 38 | —e |
10b | 1b | 6 (s-butyl) | 98 | 428 |
In contrast to the ethyl 2 sample (see entry 1, Table 1; Fig. 3(a)), the propyl 3 and n-butyl 4 gelation curves displayed similar characteristics with a peak in G′ followed by a slight decrease to a plateau of 37.2 kPa and 32.1 kPa respectively (see entries 2 & 3, Table 1; Fig. 3(b & c)). This suggests these are more homogeneous than the ethyl sample, lacking voids.‡ This is also consistent with the qualitative evidence discussed above (for images see Fig. S1†).
The curing of the PDMS 1a/s-butyl 6 sample also displayed sharp increase in modulus (to 137.2 kPa); resulting, after a small decrease, in the highest modulus observed (129.6 kPa) (see Fig. 3(d) and entry 5, Table 1). It was observed that the reaction rate was higher, with the reaction able to proceed at 0 °C; in contrast this temperature retarded the reactions using the crosslinkers 2–5.
The clear difference between s-butyl 6 crosslinker and the other crosslinkers 2–5 is the presence of a tertiary carbon α to the SiO group; the other crosslinkers 2–5 all have secondary carbons in this position (see Scheme 2). Since the predominant reaction pathway (see Scheme 1, (ii)) proceeds via a hydride shift to the alkoxy carbon atom, we postulate that this difference in electronics between 6 and the other crosslinkers (i.e.2–5) at this reaction centre is key. An enhanced ability for the tertiary carbon(s) on 6 to stabilise a (partial) positive charge, which is expected to contribute to the transition state, would account for the observed increase in reaction rate. Indeed, this crude hypothesis is consistent with a detailed mechanistic summary of the PR reaction published by Chojnowski et al.25
Increasing the bulk of the crosslinker alkyl chain (with minimal change to electronics of the carbon α to the SiO- group)using the 2-ethylbutyl 5 (see entry 4, Table 1) resulted in significantly lower % cure in the final ‘cured’ sample; it remained liquid, indicating only partial cure. The FTIR analysis supports this, displaying only partial consumption of Si–H (see Fig. 2, bottom), with the calculated percentage of conversion being 38%.§ A gelation curve was not obtained as 2-ethylbutyl 5 did not cure on the rheometer, this is consistent with the FTIR data. s-butyl 6 exhibited an efficient reaction; resulting in an increased final G′ and a high conversion percentage. This was determined to be the optimal crosslinker (see entry 5, Table 1; Fig. 3(d)).
In this context, the reaction conditions optimised for lower molar mass PDMS 1a were adjusted for a higher molar mass hydride-terminate PDMS 1b (Mn 1170 g mol−1), to ensure reaction volume and stoichiometries were comparable. For these reactions we maintained a similar volume (∼1 mL) and as such the amount of polymer, crosslinker and catalyst were halved (i.e., 0.85 mmol polymer, 0.4 mmol crosslinker and 1 × 10−4 mmol catalyst). Keeping the reaction volume similar allowed for more direct comparison between the samples derived from 1a and 1b polymer groups; samples of larger volume (by using the same number of moles of 1b as 1a) led to more defects in the resultant elastomers, due to the greater distance the gaseous alkane by-product needed to travel to escape the network.
The PDMS 1b derived samples prepared using the ethyl 2, propyl 3, or n-butyl 4 crosslinkers readily cured, yielding conversions of 98%, 93% and 99%, respectively (see Table 1, entries 6, 7, and 8 respectively). These three samples post-cure were solid materials, with no tackiness from unreacted starting reagents. The PDMS 1b/2-ethylbutyl 5 sample did not completely cure, with the sample again remaining in a liquid state (see entry 9, Table 1). From FTIR analysis, the conversion was calculated to be 38%, comparable to the PDMS 1a/2-ethylbutyl 5 sample (see entry 4, Table 1), which also exhibited partial curing.
The ethyl 2 sample displayed the highest initial G′, with a steep increase to 444 kPa, followed by a gradual decrease to 388 kPa (see Fig. 4(a) and entry 6, Table 1). Changing the crosslinkers alkyl chain to propyl 3 resulted in a decrease in the initial gelation storage modulus, peaking at 241 kPa. The initial peak in G′ of the propyl 3 system (see Fig. 4(b) and entry 7, Table 1) was followed by a decrease to 151 kPa, similar to observations for the ethyl 2 system. The storage modulus (G′) of the n-butyl 4 sample (peaked at 337 kPa see Fig. 4(c) and entry 8, Table 1), however the transition from the initial steep period to peak G′ was more gradual, indicating a reduction in reaction rate in comparison to ethyl 2 and propyl 3 systems. After the modulus peaked, a gradual decrease was seen again, reaching 224 kPa. The s-butyl 6 sample initial curing led to a peak G′ of 428 kPa (see Fig. 4(d) and entry 10, Table 1), the best from all crosslinkers tested. Interestingly, the gelation curve did not exhibit the same gradual decrease in storage modulus as seen in samples using PDMS 1b and the ethyl 2, propyl 3 and n-butyl 4 (see entries 6 and 7, Table 1). This system (1b/6) does display a higher storage modulus relative to crosslinkers 3 & 4, similar to the analogous system using the smaller PDMS (1a/6). Further investigation is required into s-butyl 6 systems to understand why this phenomenon occurs, which is outside the scope of our current work.
Fig. 4 Time-resolved rheology gelation curves over 200 seconds shown by G′ and G′′ for elastomers derived from PDMS 1b and the (a) ethyl 2, (b) propyl 3, (c) n-butyl 4, and (d) s-butyl 6 alkoxysilane (also see entries 6–10, Table 1). Note the omitted data as per Table 1. |
Time-resolved rheological studies showed gelation curves with a rapid increase in modulus, after a short induction period, followed by a plateau for each of the crosslinkers ethyl 2, propyl 3, n-butyl 4 and s-butyl 6. The ethyl 2 derived samples displayed a noticeable difference in their gelation curves, exhibiting a more gradual transition to the plateau. Samples containing s-butyl 6 displayed a larger increase in modulus comparative to any of the linear counterparts. Use of a larger branched alkyl chain crosslinker (2-ethylbutyl 5) reduced the rate of reaction considerably, leading to incomplete curing in both systems.
This work has provided an insight into the influence of crosslinker alkyl chain on PR silicone elastomer formation. We have shown that increasing the size of the alkyl group away from the SiO reaction centre, reduces the rate of reaction. In contrast we have demonstrated that altering the electronics of crosslinker, by changing the group directly bonded to the SiO reaction centre from secondary to tertiary, greatly enhances the reaction rate. In this context, the s-Butyl 6 displays both a more rapid cure and a higher storage modulus than the other crosslinkers tested and is the ideal choice for further investigations in PR elastomer preparation.
Footnotes |
† Electronic supplementary information (ESI) available. See DOI: 10.1039/d1py00872b |
‡ This differing modulus plateau may be due to forceful gas evolution of ethyl 2 reducing contact with the plates. The shear from the rheology plates promotes mixing and once the gas escapes the system, better contact can be established with the solid material, leading to a gradual increase in storage modulus. |
§ Conventional gelation theory states that an A2B4 system (where A is an α,ω-hydride terminated PDMS and B is a tetraalkoxysilane) three-dimensional structure forms beyond 33% conversion.31,32 entry 4, Table 1 has an estimated conversion of 38%; although beyond the theoretical 33% required for network formation, there is a margin of error in the calculation. In addition, FTIR only analyses a small region of the sample, both of which will contribute to variations in conversion data. The decrease in estimated percentage conversion, compared to other formulations, is likely due to the increase in steric hindrance by the larger, branched alkyl chain, leading to a reduction in rate of the PR reaction. |
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