 | Colloidal gold: Encyclopedia II - Colloidal gold - Synthesis
Colloidal gold - Synthesis
Generally, gold nanoparticles are produced in a liquid ("liquid chemical methods") by reduction of hydrogen tetrachloroaurate (HAuCl4), although more advanced and precise methods do exist. After dissolving HAuCl4, the solution is rapidly stirred while a reducing agent is added. This causes Au3+ ions to reduce to un-ionized gold atoms. As more and more of these gold atoms form, the solution becomes supersaturated, and gold gradually starts to precipitate in the form of sub-nanometer particles. The rest of the gold atoms that form stick to the existing particles, and, if the solution is stirred vigorously enough, the particles will be fairly uniform in size.
To prevent the particles from aggregating, some sort of stabilizing agent that sticks to the nanoparticle surface is usually added.
Colloidal gold - Turkevitch et al. method
Pioneered by J. Turkevitch et al. in 1951 and refined by G. Frens in 1970s, this recipe is the simplest one available. Generally, it is used to produce modestly monodisperse spherical gold nanoparticles suspended in water of around 10–20 nm in diameter. Larger ones can be produced, but this comes at the cost of monodispersity and shape.
- Take 5.0×10−6 mol of HAuCl4, dissolve it in 19 ml of deionized water (should be a faint yellowish solution)
- Heat it until it boils
- While stirring vigorously, add 1 ml of 0.5% sodium citrate solution; keep stirring for the next 30 minutes
- The colour of the solution will gradually change from faint yellowish to clear to grey to purple to deep purple, until settling on wine-red.
- Add water to the solution to bring the volume back up to 20 ml (to account for evaporation).
The sodium citrate first acts as a reducing agent, and later the negative citrate ions are adsorbed onto the gold nanoparticles and introduce the surface charge that repels the particles and prevents them from aggregating.
To produce bigger particles, less sodium citrate should be added (possibly down to 0.05%, after which there simply would not be enough to reduce all the gold). The reduction in the amount of sodium citrate will reduce the amount of the citrate ions available for stabilizing the particles, and this will cause the small particles to aggregate into bigger ones (until the total surface area of all particles becomes small enough to be covered by the existing citrate ions).
Colloidal gold - Brust et al. method
This method was discovered by Brust and Schifrinn in early 1990s, and can be used to produce gold nanoparticles in organic liquids that are normally not miscible with water (like toluene).
- Dissolve 9.0×10−4 mol of HAuCl4 (about 0.3051 g) in 30 ml of water
- Dissolve 4.0×10−3 mol of tetraoctylammonium bromide (TOAB) (about 2.187 g) in 80 ml of toluene
- Add the HAuCl4 solution to the TOAB and stir vigorously for about 10– minutes. The colour of the aqueous phase should become clear, and the colour of the organic phase (the toluene) should become orange.
- While stirring vigorously, add (preferably dropwise, but really doesn't matter) sodium borohydride (NaBH4); the colour should change from orange to white to purple to eventually reddish, although the latter colours will be poorly discernible, since the solution will be quite concentrated and thus will look very dark.
- Keep stirring the solution for up to 24 hours to ensure monodispersity (especially if NaBH4 was not added dropwise; otherwise just an hour or two is enough).
- Separate the organic phase, wash it once with dilute H2SO4 (sulfuric acid) to neutralize it, and several times with distilled water.
Here, the gold nanoparticles will be around 5–6 nm. NaBH4 is the reducing agent, and TOAB is both the phase transfer catalyst and the stabilizing agent.
It is important to note that TOAB does not bind to the gold nanoparticles particularly strongly, so the solution will aggregate gradually over the course of two weeks or so, which can be very annoying. To prevent this, one can add a stronger binding agent, like a thiol (in particular, alkanethiols seem to be popular), which will bind to gold covalently, and hence pretty much permanently. The neat thing with alkanethiol protected gold nanoparticles is that one can precipitate them and then later resuspend them, which is in fact a superior purification mechanism than the last step in the process above.
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