Open Access

Sol–gel encapsulation of Au nanoparticles in hybrid silica improves gold oxidation catalysis

  • Rosaria Ciriminna1,
  • Valerica Pandarus2,
  • Riccardo Delisi1,
  • Antonino Scurria1,
  • Maria Pia Casaletto1,
  • Francesco Giordano1,
  • François Béland2 and
  • Mario Pagliaro1Email author
Chemistry Central Journal201610:61

https://doi.org/10.1186/s13065-016-0208-6

Received: 16 July 2016

Accepted: 4 October 2016

Published: 13 October 2016

Abstract

Background

The introduction of an heterogeneously catalyzed gold-based alcohol oxidation process of broad applicability using a clean primary oxidant would be highly desirable. Gold is non toxic and carbonyl and carboxyl compounds are widely used to produce medicines, plastics, colorants, paints, detergents, fragrances, flavors, and other valued functional products.

Results

The sol–gel entrapment of gold nanoparticles in hybrid silica improves gold-based oxidation catalysis applied to the selective oxidation of alcohols with aqueous hydrogen peroxide as eco-friendly primary oxidant. Pronounced physical and chemical stabilization of the sol–gel entrapped Au nanoparticles is reflected in catalyst recyclability.

Conclusions

Potential implications of these findings are significant, especially considering that the highly stable, mesoporous glassy catalyst is ideally suited for application in microreactors for carrying out the reaction under flow.

Keywords

Gold Nanoparticle Alcohol oxidation Hydrogen peroxide Sol–gel

Following three decades of intense fundamental research [1], heterogeneous gold catalysis is now applied by the chemical industry to large-scale manufacturing of important monomers, with several Au-based redox syntheses likely to find commercial application in the next few years [2]. Alcohols, in their turn, are starting materials for the synthesis of a variety of aldehydes, ketones and carboxylic acids which are then used to produce medicines, plastics, colorants, paints, detergents, fragrances, flavors, and other valued functional molecules [3]. To accomplish this fundamental reaction, for several decades prior to the recent introduction of heterogeneously catalyzed processes [4], industry has relied on alcohol stoichiometric oxidation with inorganic and organic hazardous oxidants [5].

The ideal oxidant, though, is air or aqueous hydrogen peroxide (added slowly to avoid quick metal-catalyzed decomposition) [6], preferably under solvent-free conditions; whereas the ideal catalyst is non toxic and extensively recyclable. In this respect, the use of gold in place of platinum group metals, especially Pt and Pd, would be particularly advantageous as many aldehydes and ketones products of the oxidative conversion are active pharmaceutical ingredients (APIs) and the latter metals are classified as ‘Metals of significant safety concern’ with allowed residues in APIs <10 ppm if orally administered, and <1 ppm if parenterally administered [7]. Gold, on the other hand, is of limited toxicity.

A major progress in the field occurred in 2009 when Cao and co-workers in China reported that commercial catalyst AUROlite comprised of 1 % Au/TiO2 is an efficient and reusable catalyst for the base-free and solvent-free oxidation of alcohols using aqueous H2O2 as primary oxidant at 90 °C [8]. In Cao’s oxidation system (H2O2–Au/TiO2), secondary alcohols are converted into ketones, whereas primary alcohols are oxidised to carboxylic acids.

Along with Ilharco and Fidalgo, we have recently reported that a catalyst comprised of Au nanoparticles (NPs) sol–gel entrapped in the aggregated mesoporosity of 5 %-methyl modified silica (trademarked SiliaCat Au) selectively catalyzes the oxidation of 1-phenylethanol to acetophenone [9] under the same base- and solvent-free conditions developed by Cao’s team in 2009. Now we report that this hybrid catalyst can be successfully applied to oxidise various secondary or primary alcohols, with striking selectivity differences when compared to Au/TiO2, while retaining its activity in several consecutive runs.

Table 1 compares the reactivity of the catalyst under different conditions for different substrates giving the yields after 3 h of reaction. Entry 1 shows that cinnamyl alcohol is selectively oxidised to cinnamaldehyde only. We repeated then the oxidation of 1-phenylethanol, using 1.5 equiv of H2O2. This time, the yield is reduced from 94.2 % (entry 2, when using 3.2 equiv of H2O2) to 69.5 % (entry 3). The oxidation of 4-methylbenzyl alcohol, namely of a benzylic alcohol with an electron donating group, affords 31 % of aldehyde though 6 % of the corresponding carboxylic acid is also obtained (entry 4). Remarkably, the oxidation of another substrate bearing an electron donating group such as the methoxy substituent in para position in the benzene ring (entry 5) affords 80 % aldehyde, and the same amount of acid (6 %).
Table 1

Oxidation of alcohols with H2O2 over SiliaCat Au

Entry

Substrate

Au (mol%)

H2O2 (eq.)

Yield

Time (h)

1

Cinnamyl alcohol

0.5

3.2

53.6 % (aldehyde only)

3

2

1-phenylethanol

0.5

3.2

94.2 % (ketone only)

3

3

1-phenylethanol

0.5

1.5

69.5 % (ketone only)

3

4

4-methylbenzyl alcohol

1.0

3.2

31 % (aldehyde)

6 % (acid)

3

5

4-methoxybenzylalcohol

1.0

3.2

80 % (aldehyde)

6 % (acid)

3

6

1-nonanol

1.0

3.2

13 % (aldehyde)

4 % (acid)

3

7

Cyclohexanol

1.0

3.2

10 % (ketone)

3

Reaction conditions: 10 mmol substrate, 10 mL H2O, 90 °C, 5 % H2O2 added dropwise during 30 min; the catalyst amount was determined following ICP-MS analysis of the Au load in the catalyst

Finally, the oxidation of primary aliphatic alcohol 1-nonanol (entry 6) mostly affords the aldehyde (13 %) and a limited amount of acid (4 %); whereas the oxidation of cyclohexanol affords 10 % of cyclohexanone as the only oxidation product (entry 7). Reactions in general proceed with high degree of conversion for most substrates by just prolonging the reaction time, though at lower rate than with Au/TiO2 [8]. For example, after overall 12 h of reaction, cyclohexanol is converted in cyclohexanone in 83 % yield.

These findings confirm a peculiar characteristic of the organically modified silica (ORMOSIL) [10] catalyst which is due to the hydrophobized nature of the embedding matrix, namely that in the oxidation of primary alcohols aldehydes are preferably formed, rather than carboxylic acids. This aspect further differentiates the SiliaCat Au catalyst from Au/TiO2 which, under similar reaction conditions, preferably affords carboxylic acids. Such enhanced hydrophobicity, and the chemical sponge nature of the sol–gel encapsulating matrix (whose large inner meoporosity favours diffusion of incoming H2O2 molecules), also explains why slightly more than 3 equiv of H2O2 are required for optimal activity rather than 1.5 such as in the case of Au/TiO2, with the catalytic activity of entrapped gold nanoparticles for H2O2 decomposition being greatly influenced by the ease of adsorption of the molecules over the Au NPs and by the electron transfer from Au to H2O2 [11] both of which are enhanced in the case of SiliaCat Au.

Accordingly, Table 2 shows that recycling of the catalyst in the oxidation of 4-methoxybenzyl alcohol progressively affords more acid reaction product, going from 6 to 13.2 % (entries 1 and 3). We ascribe this finding to progressive accumulation of water molecules which partly remain entrapped within the sol–gel cages with ongoing reaction and washing cycles, as the catalyst after each run is washed with water (4 × 15 mL) and then with EtOAc (3 × 20 mL) prior to drying in an oven at 60 °C overnight.
Table 2

Oxidation recycles of two alcohol substrates with H2O2 over SiliaCat Au

Entry

Substrate

Au (mol%)

H2O2 (eq.)

Yield

Recycle

1

4-methoxybenzyl alcohol

1.0

3.2

80 % (aldehyde)

6 % (acid)

1

2

4-methoxybenzyl alcohol

1.0

3.2

68.6 % (aldehyde)

10.4 % (acid)

2

3

4-methoxybenzyl alcohol

1.0

3.2

62.5 % (aldehyde)

13.2 % (acid)

3

4

1-phenylethanol

0.5

1.5

69.5 % (ketone only)

1

5

1-phenylethanol

0.5

1.5

70.3 % (ketone only)

2

6

1-phenylethanol

0.5

1.5

68.4 % (ketone only)

3

Reaction conditions: 10 mmol substrate, 10 mL H2O, 90 °C, 5 % H2O2 added dropwise; substrate:H2O2:Au = 100:150:1. The catalyst amount was determined following ICP-MS analysis of the Au load in the catalyst

Finally, the results of the consecutive oxidation of 1-phenylethanol with the same catalyst washed and reused show that the catalyst is fully recyclable with no loss in activity between subsquent reaction runs (entries 4–6).

The SiliaCat Au catalyst is comprised of agglomerates or compacts of spheroidal silica microparticles 100–400 nm in diameter with a large concentration in 7–20 nm Au nanoparticles [9]. The vast inner mesoporosity (broad range of mesopore with average dimension ~20 nm) clearly shown in the TEM microphotograph (Fig. 1) originates the large specific surface area (460 m2 g−1) and total pore volume (1.49 cm3 g−1).
Fig. 1

TEM image of SiliaCat Au (5 % methylated)

Contrary to Pd(0) catalyst of the SiliaCat series [12], the encapsulation process requires the presence of polyvinyl alcohol (PVA) with practically all valued gold in the HAuCl4 precursor ending entrapped in the final xerogel, as proved by the load valued assessed via ICP-MS on the final xerogel. The relatively mild calcination step at 250 °C aims to eliminate the PVA used to prevent agglomeration of the AuNPs during the material’s synthesis. The XRD analysis of SiliaCat Au before calcination at 250 °C (Fig. 2) reveals the presence of the reflections of metallic Au (fcc structure). No changes in the Au crystallite size occurred upon calcination, as estimated by the Scherrer equation.
Fig. 2

XRD pattern of SiliaCat Au catalyst

The XPS pattern in Fig. 3 reveals the surface chemical composition of the ORMOSIL surface. The Si 2p photoelectron peak is located at a binding energy (BE) of 103.8 eV and the O 1 s peak is detected at BE = 532.7 eV [13]. The C 1 s peak at BE = 285.1 eV corresponds to the presence on the surface of carbon atoms in C–C, C–H bonds.
Fig. 3

XPS wide spectrum of SiliaCat Au catalyst

A very feeble Au 4f photoelectron signal is detected, suggesting that only traces of gold are present on the surface of the samples, in agreement with the nature of the sol–gel encapsulation phenomenon in which the dopant species are entrapped within the sol–gel cages [14]. The thermal treatment at 250 °C of the as-prepared sol–gel catalyst is at least partly effective in the removal of the PVA, leading to a direct exposure of the surface of the hybrid silica matrix. Indeed, results of the XPS surface quantitative chemical analysis before and after calcination show an increase of the Si concentration and a corresponding decrease of the C atomic percentage upon calcination, as shown in Table 3.
Table 3

XPS surface chemical composition of SiliaCat Au before and after calcination. Elemental concentration is expressed as  % atomic percentage

Sample

C 1 s (%)

O 1 s (%)

Si 2p (%)

Au 4f7/2

Si/O

Si/C

SiliaCatAu

14.6 

61.3

24.1 

0.1

0.39

1.65

Calcined SiliaCatAu

12.0

61.8

26.2

0.1

0.42

2.18

The XPS curve-fitting of the Si 2p spectrum of the SiliaCat Au sample inserted in Fig. 4 reveals the presence of second component at BE = 105.1 eV (14.4 % peak area), along with the principal component at BE = 103.8 eV assigned to Si–O bonds (85.6 % peak area). The former component at BE = 105.1 eV is attributed to the presence of surface Si–CH3 bonds, which are prevalent on the surface of a fully methylated ORMOSIL matrix, when said component at higher binding energy becomes predominant in the Si 2p curve-fitting, as shown in Fig. 5.
Fig. 4

XPS curve-fitting of the Si 2p spectrum of the SiliaCat Au sample

Fig. 5

XPS curve-fitting of the Si 2p spectrum of the fully methylated ORMOSIL sample

The removal of the non entangled PVA molecules by calcination yields sol–gel cages with surfaces covered by a population of methyl groups (and weakly interacting –OH groups). These groups are concentrated at the sol–gel cage external surface, where they enhance the hydrophobicity and the electron density at the surface of the entrapped Au nanoparticles. This favors the first mechanistic steps in the gold-mediated oxidation of alcohols with H2O2, namely the dissociation of H2O2 and formation of the alcoholate [8].

In conclusion, SiliaCat Au successfully mediates the clean oxidation of various alcohols under solvent-free and base-free conditions to the corresponding carbonyl compounds (ketones and aldehydes) using aqueous hydrogen peroxide as primary oxidant at 90 °C. The catalyst has activity comparable to state of the art (AUROlite) Au/TiO2 catalyst, but the selectivity is reversed, with formation of aldehyde favored also in the case of primary alcohols due to the hydrophobized nature of the encapsulating matrix.

Beyond interesting applications in photonics due to entrapped plasmonic nanoparticles [15], the robust and highly porous nature of the glassy organosilica matrix of the SiliaCat catalyst is ideally suited for application to reaction in microreactors under flow [16]. SiliaCat Au, with its high activity and particularly pronounced chemical stability, may be ideally suited to provide the fine chemical and pharmaceutical industries with an economically and technically viable solution to oxidise alcohols getting rid of harmful oxidants and toxic catalytic species altogether.

Experimental section

Catalyst preparation

The SiliaCat Au catalyst was prepared via sol–gel hydrolytic polycondensation of tetraethoxysilane/methyltriethoxysilane (TEOS/MTES) mixtures, in the presence of HAuCl4, and PVA as protecting agent. A mixture of TEOS (95 mol %) and MTES (5 mol %) is hydrolyzed by treatment with HCl 0.05 N. A solution of HAuCl4 monohydrate (0.20 g) in 3 wt% aqueous PVA is then added with NaBH4 (0.05 g), followed by addition of the as-obtained Au nanoparticles to the hydrolized silicon alkoxides mixture. Gelation is promoted through the addition of aqueous NaOH. The purple alcogel thereby obtained is left to dry at room temperature and then powdered. PVA was removed by calcination at 250 °C, with the methyl groups in the organosilica matrix being thermally stable [17]. The catalytic load, obtained with an ICP-MS instrument (Agilent Technologies 7500ce Series Spectrometer) equipped with a collision cell, was 0.1 wt% Au.

General oxidation procedure

The oxidation of all alcohol substrates was carried out with aqueous H2O2 (5 wt%) as oxidant over the SiliaCat Au catalyst. No organic solvent was employed and air was not excluded from the reaction mixture. In a typical catalytic run, 5 % H2O2 (18 g) was added dropwise to a suspension of the catalyst (Au 1 mol %) in a mixture of substrate (1 mmol) and deionized water (10 g) contained in a 50 mL two-neck round bottom flask, kept at 90 °C using a thermostatic oil bath. After 3 h the catalyst was filtered and the aqueous reaction mixture extracted with ethyl acetate (EtOAc). The organic phase was then analyzed by GC-FID (Shimadzu-GC 17 equipped with a Supelcowax 10 column) to determine the conversion in carbonyl (or carboxyl) compound. The catalyst was extensively washed (with water and then with acetonitrile), dried at 60 °C overnight and reused as such in a subsequent reaction run.

Structural analyses

The geometric structure of the samples was investigated by X-ray Diffraction (XRD) by using a Bruker D5000 powder diffractometer, equipped with a Ni-filtered radiation of the Cu anode (Cu Kα λ = 1.5418 Å; 40 kV and 35 mA). Diffraction patterns were registered in the angular range 10° < 2θ° < 90°, using a step size of 0.03° and a time step of 3 s. The assignment of the crystalline phases was based on the ICSD database.

The surface chemical composition of the samples was analyzed by an advanced surface-sensitive technique, such as X-ray photoemission spectroscopy (XPS), by using a VG Microtech ESCA 3000 Multilab spectrometer, equipped with a standard Al Kα excitation source (hν = 1486.6 eV) and a nine-channeltrons detection system. The hemispherical analyser operated in the CAE mode, at a constant pass energy of 20 eV Photoemission spectra were collected in an ultrahigh vacuum (UHV) chamber with a base pressure in the range of 10–8 Torr during data collection. The binding energy (BE) scale was calibrated by measuring C 1 s peak (BE = 285.1 eV) from the surface contamination and the accuracy of the measure was ±0.1 eV. Data analysis was performed by a nonlinear least square curve-fitting program (VGX900 software) using a properly weighted sum of Lorentzian and Gaussian component curves, after background subtraction according to Shirley and Sherwood [18].

The TEM micrographs were obtained by using a Hitachi H-8100 electron microscope operated at 200 kV with a LaB6 filament. The samples were dispersed in ethanol and dropped onto a Formvar-coated Cu grid and left to evaporate.

Declarations

Authors’ contributions

RC and VP devised and carried out the catalyst preparation, RD and AS performed the catalytic experiments, MPC conducted the XPS and FG the X-ray analyses. FB and MP wrote and reviewed the manuscript. All authors read and approved the final manuscript.

Acknowledgements

This article is dedicated to Professor Alexandra Fidalgo Abrantes (Universidade Europeia, Lisboa) for many years of fruitful co-operation in sol–gel materials and natural products research.

Competing interests

The authors declare that they have no competing interests.

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Authors’ Affiliations

(1)
Istituto per lo Studio dei Materiali Nanostrutturati, CNR
(2)
SiliCycle Inc., 2500, Parc Technologique Blvd

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