The present invention relates to the formation of gold nanoparticles and, in particular, to direct formation of gold nanoparticles from bulk metal sources through the application of ultrasound.
Gold nanoparticles have been one of the most extensively studied nanoparticle systems over the past few decades and there are now well established syntheses for a wide range of sizes and morphologies including spheres, nanorods, and nanoplates. See J. Watt et al., Chem. Mater. 27, 6442 (2015); S. E. Lohse et al., Chem. Mater. 26, 34 (2014); L. Chen et al., Nano Lett. 14, 7201 (2014); L. Scarabelli et al., The Journal of Physical Chemistry Letters 6, 4270 (2015); K. Park et al., Chem. Mater. 25, 555 (2013); and A. M. Henning et al., Angewandte Chemie-International Edition 52, 1477 (2013). This high level of research interest is largely due to the possession of well-defined surface plasmon resonances (SPRs) which are sensitive to changes in nanoparticle size, shape and crystallinity. See J. Zheng et al., Nanoscale 4, 4073 (2012); K. Park et al., Journal of Physical Chemistry C 118, 5918 (2014); V. Juvéet al., Nano Lett. 13, 2234 (2013); and H. J. Chen et al., Chem. Soc. Rev. 42, 2679 (2013). The ability to fine tune the optical properties means gold nanoparticles show great potential for a number of applications including theranostics, photothermal therapy, and sensor technologies. See J. Qin et al., Nanoscale 7, 13991 (2015); A. J. McGrath et al., ACS Nano (2015); and Z. Wu et al., Small 8, 2028 (2012).
Metallic gold is chemically inert so gold salts are typically used as precursors for nanoparticle synthesis; tetrachloroaurate (HAuCl4) being the most common. Tetrachloroaurate is highly corrosive, with limited exposure known to cause skin and eye damage. It is hygroscopic and requires a dry atmosphere for storage as well as care in handling to ensure uncontrollable hydration does not affect reaction stoichiometry. It's most damaging aspect however, comes from its production, which requires the dissolution of bulk metallic gold in aqua regia; an incredibly harsh acid. Then, in order to form gold nanoparticles tetrachloroaurate is converted back into Au(0) by a reducing agent; usually sodium borohydride (NaBH4). Although widely used for the synthesis of gold nanoparticles, this reaction is inefficient and highly toxic and violates a number of the 12 Principles of Green Chemistry i.e., the reaction has incredibly poor atom economy (only 1 in 12), and generates environmentally harmful side products, as well as typically using a large excess of reducing agent. There are a number of greener approaches that use environmentally friendly reducing agents; however, they still rely on tetrachloroaurate as the gold precursor and display poor atom economy. See R. K. Sharma et al., J. Chem. Educ. 89, 1316 (2012); S. K. Das et al., Green Chemistry 14, 1322 (2012); and N. N. Dhanasekar et al., J. Microbiol. Biotechnol. 25, 1129 (2015).
The present invention is directed to a method to produce gold nanoparticles directly from bulk metal, eliminating the need for the toxic dissolution and reduction steps. Gold nanoparticle formation occurs when bulk gold is subjected to ultrasonication in water in the presence of a surfactant and an alkylthiol species. Ultrasound drives the formation and implosive collapse of cavitation bubbles which impinge violently on the gold metal surface, liberating nanostructures which are stabilized in solution by an organic bilayer. These can then be isolated and digestively ripened in water to give a nanoparticle solution displaying a well-defined surface plasmon resonance. The method can use a number of different bulk gold sources. The method can be applied to an important environmental problem; the recovery of gold from electronic waste. For example, gold nanostructures can be produced directly from cellular subscriber identity module (SIM) cards with no prior manipulation of the SIM cards required, thereby upcycling a waste stream directly to a high value product.
The detailed description will refer to the following drawings, wherein like elements are referred to by like numbers.
According to the present invention, gold nanoparticles can be produced in significant quantities directly from either bulk or larger particulate materials under a range of conditions. The mechanism does not involve a continuous decrease in size, but jumps directly from micron or larger size to the nanoscale. The process likely involves a microjet forming near the surface that ablates material from the surface, some of which forms nanoparticles. By providing an appropriate surfactant in the immediate vicinity of the ablation, the nanoparticles can be protected from agglomeration and collected.
The green chemistry approach of the present invention forms gold nanoparticles directly from bulk metallic gold using ultrasonication, bypassing the toxic dissolution and reduction steps outlined above. Ultrasound spans frequencies from 20 kHz to 10 MHz and when applied to a liquid medium drives the nucleation, growth and implosive collapse of cavitation bubbles. See K. S. Suslick and D. J. Flannigan, Annu. Rev. Phys. Chem. 59, 659 (2008); and K. S. Suslick and G. J. Price, Annu. Rev. Mater. Sci. 29, 295 (1999). These bubble collapse events yield extremely high local temperatures (>5000 K) and pressures (>20 MPa), along with free-radical species, which can be used to drive chemical transformations. This phenomenon has previously been used to form nanoparticles from metal salt solutions; yet there are only a few examples of direct formation from bulk sources. See H. Xu et al., Chem. Soc. Rev. 42, 2555 (2013); and A. Gedanken, Ultrason. Sonochem. 11, 47 (2004). Li et al. used ultrasonic cavitation to produce tin nanoparticles from tin granules, and micro- and nanoparticles have been formed from low melting point metals and their alloys. See Z. Li et al., Ultrason. Sonochem. 14, 89 (2007); H. Friedman et al., Ultrason. Sonochem. 20, 432 (2013); and Z. H. Han et al., Ultrasonics 51, 485 (2011). However, these methods required the bulk metal to first be molten and hence high boiling point solvents and a massive input of heat were needed; an impractical and not particularly green solution for the formation of gold nanoparticles.
The method of the present invention occurs simply in water, by the ultrasonication of bulk gold sources in the presence of an alkylthiol species (dodecanethiol) and a surfactant (didodecyldimethylammonium bromide, DDAB). The production of nanoparticles begins with the formation of a dodecanethiol/DDAB organic bilayer on the surface of bulk gold. This is followed by the collapse of cavitation bubbles, which impinge violently on the surface, ejecting nanostructured material that becomes stabilized in solution by the organic bilayer. The nanostructures can be easily isolated and digestively ripened in water to yield a gold nanoparticle solution with a well-defined SPR. A number of different forms of bulk gold can be subjected to ultrasonication according to this method. Finally, the method can be applied to an important environmental problem; the recovery of gold from electronic waste streams. For example, using ultrasonication, gold nanostructures can be extracted directly from the surface of cellular subscriber identity module (SIM) cards, with no prior manipulation of the SIM cards required. This method provides an improvement on current extraction techniques by upcycling gold from an electronic waste stream directly to a high value product, without the need for harsh solvents or reducing agents.
According to the invention, under specific reaction conditions cavitation bubble collapse events can provide the driving force for the formation of gold nanostructures directly from bulk sources. As shown in
Liberated material is expected to be diverse in size and shape as the size distribution of bubbles induced by the ultrasonic field is relatively large. See A. Brotchie et al., Phys. Rev. Lett. 102, 084302 (2009). Furthermore, in a high energy environment such as an ultrasonic field the fate of the material is uncertain. Degradation of large solid particles due to shear forces induced by microstreaming and shock waves can lead to a reduction in particle size and an increase in surface area. See T. J. Mason and D. Peters, Practical Sonochemistry, 2nd Edition ed.; Woodhead Publishing (2002). On the other hand, shockwaves can drive metal particles together at extremely high speeds, leading to interparticle fusion and an increase in particle size. See S. Doktycz and K. Suslick, Science 247, 1067 (1990); D. Radziuk et al., Journal of Physical Chemistry C 114, 1835 (2010); and T. Prozorov et al., J. Am. Chem. Soc. 126, 13890 (2004). This mechanism for particle fusion occurs over a narrow critical size range. Larger particles experience stronger viscous drag reducing the forces of impact; whereas smaller particles have less cross-sectional surface area for the shockwaves to act upon, reducing their velocity in solution. See T. Prozorov et al., J. Am. Chem. Soc. 126, 13890 (2004). These particles possess insufficient kinetic energy for particle fusion and will experience elastic collisions upon impact. Within the narrow size range, particles will experience a sufficient driving force such that a critical velocity is reached and coalescence occurs upon impact. Therefore, in terms of nanoparticle formation successively reducing particle size by cavitation erosion would not be a suitable approach, as a lower limit would eventually be reached leading to particle fusion. For example, Kass used water as a solvent to reduce the size of alumina particles to 1 μm using ultrasonication fragmentation. Upon analysis with SEM it was found that they were agglomerates of particles around 100 nm in diameter. See M. D. Kass, Mater. Lett. 42, 246 (2000).
Therefore, forming gold nanoparticles directly from bulk metals using ultrasonication presents a number of unique challenges. Nanoparticles would need to be formed directly below the particle fusion threshold and stabilized in solution to prevent coalescence. Furthermore, the current understanding of cavitation erosion cannot be readily applied to gold. Gold is an incredibly ductile and malleable metal that is resistant to oxidation and ejection of material typically requires high energy ablation methods employing focused ion or laser beams. See H. Wender et al., Nanoscale 3, 1240 (2011); and J. P. Sylvestre et al., J. Phys. Chem. B 108, 16864 (2004). However, according to the present invention, simple organic additives can lead to the formation of nanostructures from bulk gold under ultrasonication. First, the surface of the bulk gold is modified by a self-assembled monolayer (SAM) of dodecanethiol, a process that is promoted by ultrasonication. See H. Dai et al., Electrochim. Acta 53, 3479 (2008). Dodecanethiol SAMs form on gold surfaces initially through physisorption followed by chemisorption, yielding a covalent Au-S interaction. See C. Vericat et al., Chem. Soc. Rev. 39, 1805 (2010). Then, with DDAB present in solution a surface organic bilayer is expected to form. Liberated material takes the form of nanostructures which are stabilized in solution due to the charged amine functionality of DDAB. See S. E. Lohse and C. J. Murphy, Chem. Mater. 25, 1250 (2013).
Transmission electron microscopy (TEM) experiments were performed on the as-sonicated reaction product. As shown in
In order to improve atom economy, the sub-micron sized particulate was recovered by centrifugation and added again to a mixture of dodecanethiol and DDAB in water. This was subjected to further ultrasonication and again led to the formation of nanostructured gold. By doing this, the bulk gold precursor could be continuously consumed, and could theoretically reach a quantitative yield.
The effect the organic additives had on the formation of the nanostructures was investigated. Firstly, ultrasonication was performed on gold powder with no alkylthiol or surfactant present i.e., in water only. No change in the color of the reaction solution was observed after 6 h ultrasonication time. This was confirmed by the lack of absorption peaks in the corresponding UV-vis spectra, indicating no nanostructures were formed. The same lack of absorbance was observed when either DDAB only or dodecanethiol only were added to the reaction mixture, indicating the presence of the organic bilayer is critical for the formation of nanostructures. To confirm the importance of bilayer formation dodecanethiol was substituted with either DL-dithiothreitol or 1,8-octanethiol. DL-dithiothreitol does not form well packed monolayers due to the presence of bulky hydroxyl groups and dithiols are known to be much more sensitive to formation conditions. See C. Vericat et al., Chem. Soc. Rev. 39, 1805 (2010). To confirm, ellipsometry experiments were performed on Si wafers sputtered with Au that had been subjected to ultrasonication for 20 min in model reaction solutions. Ellipsometry showed the gold surface sonicated with dodecanethiol had a thin film thickness of 1.62 nm, indicating a well-formed monolayer. See H. Dai et al., Electrochim. Acta 53, 3479 (2008) and J. C. Love et al., Chem. Rev. 105, 1103 (2005). Measurements on DL-dithiothreitol and 1,8-octanedithiol solutions showed thin film thicknesses of 0.40 nm and 0.08 nm, respectively, indicating either monolayers were not formed or the thiols were in the lying down phase. See C. Vericat et al., Chem. Soc. Rev. 39, 1805 (2010). When bulk gold was subjected to ultrasonication in the presence of these alkyl thiols and DDAB a dramatic decrease in the absorption intensity, and hence nanostructure yield, was observed. The quaternary ammonium surfactant species, along with counter-ion, were then changed and little effect on nanostructure formation was observed. Cetyltrimethylammonium bromide (CTAB) and cetyltrimethyl ammonium chloride (CTAC) gave similar absorption profiles to the reaction with DDAB. This indicates the quaternary ammonium surfactants role is limited to bilayer formation; varying the type of surfactant does not directly affect the nature of the gold surface.
For effective application of gold nanoparticles, a well-defined SPR is typically desired. To achieve this, a simple non-toxic digestive ripening step was employed that does not require harmful organic solvents, as shown schematically in
To demonstrate the versatility of this method, it was applied to a number of different sources of bulk gold.
The effect that ultrasonication had on the different gold surfaces was then investigated by performing time-dependent SEM experiments. Microscopy was performed on samples that had undergone ultrasonication for 0 h (i.e., an unsonicated surface), 20 min, 2 h, 4 h, and 6 h. The degradation of the powder source used in
In order to fully characterize a single cavitation pit a combination of high magnification SEM and focused ion beam (FIB) milling were used. As shown in
SEM was then used to investigate the surface of the bulk gold source which had been subjected to ultrasonication for 6 h with no organic additives i.e., in water only. Visible surface rearrangement characteristic of melting was present; however, the average macroscopic particle size was unchanged. In comparison, when additives are present, the average particle size reduces significantly with ultrasonication time. This indicates that the gold sources are experiencing a similar environment within the ultrasonic field yet only when organic additives are present is material liberated from the surface.
The above results indicate that the dodecanethiol/DDAB bilayer renders the surface of bulk gold susceptible to degradation from collapsing cavitation bubbles. The organic bilayer introduces a tensile stress to the surface, which reduces the energy barrier to material ejection. The strength of this effect is reduced when bilayer formation is less complete i.e., when DL-dithiothreitol or octanedithiol are used. The role of DDAB is limited to its behavior as a surfactant; in bilayer formation on the gold surface, stabilizing the liberated nanostructures and transporting dodecanethiol to the gold surface in the early stages of the reaction. When no organic additives are present, localized surface rearrangement due to melting is observed; however, no nanostructure formation or bulk material loss is observed.
The hypothesis that nanostructure formation occurs due to cavitation erosion and material ejection is supported by the observation that an increase in surface area of the bulk gold source leads to an increase in nanostructure yield. A larger surface area is able to accommodate a larger number of cavitation events. The exception to this is the gold powder that possesses a spherical morphology and high surface area yet gave a relatively low nanostructure yield. In this case, the curved surface dissipates the energy of the collapsing bubble, reducing the force of any potential impact. See T. J. Mason and D. Peters, Practical Sonochemistry, 2nd Edition ed.; Woodhead Publishing (2002); and E. A. Neppiras, Physics Reports-Review Section of Physics Letters 61, 159 (1980). On the other hand, the planar surfaces of the foils and hexagonal and plate-like powder are well-suited to experience the full force of micro-jet impact, and a good yield of gold nanostructures is formed. The increase in nanostructure yield with decreasing foil thickness can be explained by the tearing, ripping, or puncturing of the foil. Such imperfections are more readily formed in thinner foil which then act as cavitation generation sites; triggering more cavitation activity leading to greater mass loss. See M. Dular et al., Ultrason. Sonochem. 20, 1113 (2013). Interestingly, although the absorption intensity varied significantly between bulk gold sources the shape of the absorption profile did not. This would indicate that the nature of the liberated material is more strongly dictated by the bubble collapse event itself than the overall morphology of the bulk gold source.
TEM analysis revealed the ejected material to consist of relatively large sub-micron particles, rod-like and spheroid nanoparticles 5-100 nm in size, and small ˜2 nm nanoparticles. This large size distribution is expected, due to the large distribution of bubble sizes formed in water upon the application an ultrasonic field. See A. Brotchie et al., Phys. Rev. Lett. 102, 084302 (2009). The critical velocity for melting upon particle impact was calculated to be 628 ms−1 for Au. See T. Prozorov et al., J. Am. Chem. Soc. 126, 13890 (2004). This indicates that the critical size range for particle fusion is between 3.3 μm and 20 μm. The gold powder in
The relatively tight size distribution of the nanoparticles ˜2 nm in size would indicate that simple material ejection cannot explain their formation. These nanoparticles most likely form in a manner analogous to laser ablation, where cavitation collapse is accompanied by atomization; followed by the growth of nanoparticles from the ‘bottom-up’. See V. Amendola and M. Meneghetti, PCCP 15, 3027 (2013). The observation of agglomerations of small gold nanoparticles supports the idea that these nanoparticles are growing from free monomer in solution, as this type of behavior has previously been seen in nanoparticles grown from HAuCl4 under an ultrasonic field. See Z. Zhong et al., J. Mater. Chem. 16, 489 (2006).
The results above indicate that the ultrasonication method is applicable to a wide range of bulk gold metal sources, as long as there is a suitable surface to induce asymmetric cavitation bubble collapse. Therefore, the method can be applied to liberate gold nanoparticles from an environmentally important electronic waste stream; cellular subscriber identity module (SIM) cards. Electronic waste can contain significantly more Au content when compared to traditional ores and is set to become an important metal source as consumption continues to rise. See Y. He and Z. Xu, Rsc Advances 5, 8957 (2015). Recovery and recycling are energy intensive and typically require the removal of any non-metal supports followed by dissolution in cyanide or aqua regia. See J. Cui and L. Zhang, J. Hazard. Mater. 158, 228 (2008). The ultrasonication method of the present invention is well-suited for SIM cards as they possess a large planar surface of exposed gold in the form of the electrical contact. The composition of a typical SIM card was first investigated using FIB milling, as shown in
An unaltered SIM card complete with plastic support, as shown in
To isolate the Au nanoparticles from any additional impurities, a room-temperature gold selective thiol-mediated organic phase transfer was performed. The UV-vis spectrum of the resulting solution is shown in
The present invention has been described as a method for the direct formation of gold nanoparticles using ultrasound. It will be understood that the above description is merely illustrative of the applications of the principles of the present invention, the scope of which is to be determined by the claims viewed in light of the specification. Other variants and modifications of the invention will be apparent to those of skill in the art.
This application claims the benefit of U.S. Provisional Application No. 62/321,415, filed Apr. 12, 2016, which is incorporated herein by reference.
This invention was made with Government support under contract no. DE-AC04-94AL85000 awarded by the U. S. Department of Energy to Sandia Corporation. The Government has certain rights in the invention.
Number | Date | Country | |
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62321415 | Apr 2016 | US |