Introduction

Hydrogen (H2) is one of the most promising energy carrier alternatives to fossil fuels. However, realizing a H2-powered society is not so easy due mainly to problems related to the storage and transportation of H2. The efforts to develop efficient and convenient H2-generation systems have led to investigations into hydrogen storage materials such as metal hydrides and chemical hydrides. Metal hydrides, such as LiAlH4 and AlH3, react violently when they contact water at ambient temperature, providing the rapid production of large amounts of pure H21,2,3. However, these reactions are difficult to control and can result in an explosion. Chemical hydrides, such as ammonia-borane4,5,6 and formic acid7,8, are leading candidates for new hydrogen storage materials because of their hydrogen content and highly efficient catalysts for producing H2 from these molecules have been reported9,10,11,12,13,14,15,16,17,18,19,20,21,22,23. However, for effective functioning, these catalysts often require heat energy9,10,14 and anaerobic conditions11,12,14,15,22. In addition, these reactions can result in toxic ammonia salt and CO by-products, and the co-production of CO2 gas from formic acid that requires a separation process using membranes to obtain pure H2 gas, which limit their wide utilization for producing H2.

The hydrolytic oxidation of organosilanes can be an efficient H2-production method. Several organosilanes are relatively air-stable and non-toxic. Additionally, polymethylhydrosiloxane (Me3Si(OSiMeH)nOSiMe3, PMHS) and tetramethyldisiloxane (Me2SiHOSiHMe2, TMDS) are by-products of the silicon industry and so are cost-effective24,25, and the resulting silanols are useful as additives for silicon rubber26,27. Therefore, the development of highly efficient catalysts that promote hydrolytic oxidation of organosilanes and can function at ambient temperature under aerobic conditions may provide efficient production of pure H2 without additional energy input. In addition, the use of heterogeneous catalysts should allow easy separation from organosilane, leading to on/off-switching of H2-production. Several heterogeneous catalysts for the hydrolytic oxidation of organosilanes have been reported28,29,30,31,32,33,34,35,36,37. However, these catalysts were developed for the synthesis of organosilanols, and no attention has been paid for the utilization of heterogeneous catalysts for H2-production through hydrolytic oxidation of inexpensive organosilanes such as PMHS and TMDS.

The present report describes the development of an efficient controllable H2-production system using hydrolytic oxidation of organosilanes with newly developed heterogeneous gold nanoparticle (AuNP) catalysts at ambient temperature under aerobic conditions. Addition and removal of the heterogeneous AuNP catalyst from the reaction mixture enabled easy on-demand production of pure H2 without any additional energy input. In the case of hydrolytic silane-oxidation, the AuNP catalysts exhibited the highest turnover numbers and turnover frequencies of up to 3,333,000 and 77/sec, respectively, that have so far been reported. Moreover, the AuNP catalysts were reusable without loss of activity as demonstrated during recycling experiments.

Results and Discussion

We recently reported that gold38,39 and silver40 NPs were capable of promoting hydrolytic oxidation of hydrosilanes to silanols. Hydroxyapatite (HAP)-supported AuNPs with a mean diameter of 3 nm (Au/HAP) prepared by a deposition–precipitation method acted as a highly efficient heterogeneous catalyst. The Au/HAP showed high catalytic activity at ambient temperature under aerobic conditions, producing pure H2 during the reaction39. Thus, we attempted to improve the catalytic activity of Au/HAP by decreasing the size of AuNPs to create more efficient heterogeneous catalysts. The size-control synthesis of AuNPs on HAP was performed using a modification of a previously reported method that used glutathione as a capping reagent for the AuNPs41,42,43. Briefly, glutathione (1.0 mmol) was added to a methanol solution (50 mL) of HAuCl4 (0.25 mmol) and stirred for 30 min at 273 K in air. Next, KBH4 (1.0 mmol) was added to the solution. After stirring 1 h at 273 K, the solid was collected by centrifugation and the precipitate was re-dispersed in water. Different amounts of HAP were added to this dispersion, followed by stirring for 4 h at r.t. HAP is well known to have high adsorption property for amino acid and protein44,45, therefore, the glutathione-modified Au nanoparticles would be easily adsorbed on HAP. Actually, the colloidal Au nanoparticles capped with glutathione was easily adsorbed on HAP by simply stirring the colloidal Au nanoparticles solution in the presence of HAP. The mixture was then filtered, washed with deionized water, and dried in vacuo. Finally, the solid obtained was calcined at 400 °C in air for 8 h to remove glutathione coordinated to AuNPs, giving Au/HAP-NC. The sulfur in Au/HAP-NC was not detected by elemental analysis, confirming the removal of the glutathione capping reagent. The loading amount of Au X wt% are designated as Au/HAP-NC (X wt%).

Representative images of Au/HAP-NC obtained by transmission electron microscopy (TEM) are depicted in Fig. 1. Au/HAP-NC showed small AuNPs with a very narrow size distribution. Au/HAP-NC (0.5 wt%), Au/HAP-NC (2 wt%), and Au/HAP-NC (3 wt%) had AuNPs with mean diameters of 1.9 nm, 2.3 nm, and 3.1 nm, respectively (Fig. 1a–c), whereas Au/HAP prepared by the deposition–precipitation method had AuNPs with a mean diameter of 3.0 nm with a relatively broad size distribution (Fig. 1d). The lattice fringe had d-spacing attributed to d-spacing Au {111} (Fig. 1e). These results revealed that glutathione allowed the size-selective synthesis of small AuNPs on HAP and that the size of AuNPs can be controlled by the Au loading amounts. Au/HAP-NC was also characterized by Ultraviolet-Visible Absorption Spectroscopy (UV-Vis), X-ray Diffraction (XRD), and X-ray Photoelectron Spectroscopy (XPS) (Supplementary Figures 2–4).

Figure 1
figure 1

TEM images and corresponding histograms for (a) Au/HAP-NC (0.5 wt%); (b) Au/HAP-NC (2 wt%); (c) Au/HAP-NC (3 wt%); (d) Au/HAP. (e) ADF-STEM image of Au/HAP-NC (0.5 wt%).

With the prepared Au/HAP-NC catalysts in hands, the hydrolytic oxidation of dimethylphenylsilane (1) as a model substrate was conducted in dimethoxyethane (DME) at ambient temperature in air. Results are shown in Table 1. Notably, Au/HAP-NC (0.5 wt%) efficiently promoted the oxidation, affording dimethylphenylsilanol (2) in 99% yield along with the generation of equimolar amounts of H2 after 9 min (Table 1, entry 2). The catalytic activity of Au/HAP-NC increased as the size of the AuNPs decreased (entries 1, 4, and 5). The catalytic activity of Au/HAP-NC (0.5 wt%) was much greater than that of previously reported Au/HAP prepared by the deposition–precipitation method (entry 6). Neither bulk Au (non-nanosized Au) nor HAP show any activity (entries 7 and 8), indicating that the AuNPs were the active species. In addition, Au/HAP-NC (0.5 wt%) worked well at scale-up conditions with a lower catalyst loading (0.03 mmol%), giving a turnover number of 3,333,000 and turnover frequency of 77/sec based on the total amount of Au used in the reaction (Fig. 2), both of which were much greater than values previously reported (Supplementary Table 1).

Table 1 Aqueous oxidation of 1 using Au catalysta.
Figure 2
figure 2

Scale-up reaction using Au/HAP-NC (0.5 wt%).

Next, the catalytic activity of Au/HAP-NC (0.5 wt%) for H2-production through the hydrolytic oxidation of PMHS and TMDS was investigated. The time-course for H2-production is shown in Fig. 3. Upon addition of Au/HAP-NC (0.5 wt%) to the DME/water solution of PMHS or TMDS at ambient temperature in air, H2 gas was efficiently generated with initial production rates of 9.8 and 18.9 mL/min, respectively. When Au/HAP-NC (0.5 wt%) was separated from the reaction mixture by filtration, the H2 generation quickly stopped; re-addition of Au/HAP-NC (0.5 wt%) to the filtrate induced re-generation of H2. The generation and suppression of H2 were repeatable, enabling the on/off-switching of H2-production by the introduction and removal of catalyst. The catalytic system of the on/off-switching of H2-production was demonstrated in Supplementary Movie 1; the generation and suppression of the H2 bubble in response to the introduction and removal of Au/HAP-NC (0.5 wt%) could be observed.

Figure 3
figure 3

Evolution of H2 from TMDS or PMHS using Au/HAP-NC (0.5 wt%).

Reaction conditions: Au/HAP-NC (0.5 wt%) (1.0 g, Au: 0.025 mmol), Si-H (10 mmol), DME (5 mL), water (0.6 mL), air.

This on/off-switchable H2-production system could be applied to a portable hydrogen fuel cell. When the catalyst system (hydrogen generation part) was connected to the power generation part, including a Pt anode, electric power was generated that could be turned on and off at ambient temperature in air atmosphere (Supplementary Movie 2). This is the first report of an on/off-switchable H2-production system using the hydrolytic oxidation of inexpensive organosilanes without the need for any additional energy input. The TEM image of the used Au/HAP-NC (0.5 wt%) catalyst showed that the average diameter and size distribution of the AuNPs were similar to those of Au/HAP-NC (0.5 wt%) before use and that no aggregation of AuNPs occurred (Supplementary Figure 1), proving high durability of Au/HAP-NC (0.5 wt%) against aggregation.

In conclusion, a size-controllable and size-selective synthesis of AuNPs on HAP was developed. The Au/HAP-NC (0.5 wt%) catalyst with a mean diameter of 1.9 nm possessed the greatest catalytic activity for the aqueous oxidation of silanes. The high catalytic activity of Au/HAP-NC (0.5 wt%) was applied to H2-production from inexpensive PMHS and TMDS as hydrogen storage materials at ambient temperature in air. The solid Au/HAP-NC (0.5 wt%) catalyst could be separated, enabling the on/off-switching of H2-production by the introduction and removal of the catalyst. This catalytic system for on/off switchable H2-production from organosilanes can contribute to the development of next-generation green hydrogen fuel cells with on-demand H2-production.

Methods

Synthesis of Au/HAP-NC (X wt%)

Glutathione (1 mmol) was added to a methanol solution (50 mL) of HAuCl4 (0.25 mmol) and stirred for 30 min at 273 K in air. Next, a methanol solution of KBH4 (1.0 mmol) was added. After stirring 1 h at 273 K, the solid was collected by centrifugation and the precipitate re-dispersed in water (100 mL). Different amounts of HAP were added to the dispersion, followed by stirring for 4 h at r.t. The mixture then was filtered, washed with deionized water, and dried in vacuo. Finally, the obtained solid was calcined at 400 °C in air for 8 h to remove the glutathione coordinated to AuNPs, giving Au/HAP-NC. The loading amount of Au X wt% is designated as Au/HAP-NC (X wt%).

Typical reaction procedure

A typical reaction procedure for oxidation of 1 to 2 using Au/HAP-NC (0.5 wt%) was as follows. The Au/HAP-NC (0.5 wt%) (0.02 g, Au: 0.05 mol%) was placed in a reaction vessel, followed by addition of DME (2 mL), water (0.2 mL), and 1 (1 mmol). The reaction mixture was stirred vigorously at 30 °C under an air atmosphere for 8 min. Then, the Au/HAP-NC (0.5 wt%) was filtered and the yield determined by GC analysis.

Measurement of H2

The amount of H2 generated during the reaction was measured using the water displacement method. Qualitative analyses of generated gas were performed by GC-TCD. GC conditions were as follows: thermal conductivity detector (Shimadzu GC-8A); column: molecular sieves 13X (4.0 m); oven temperature: 40 °C; injection and detection temperature: 70 °C; carrier gas: Ar (100 kPa); current: 60 mA; retention time: H2 (5.3 min).

Additional Information

How to cite this article: Mitsudome, T. et al. On-demand Hydrogen Production from Organosilanes at Ambient Temperature Using Heterogeneous Gold Catalysts. Sci. Rep. 6, 37682; doi: 10.1038/srep37682 (2016).

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