Students can visualise the behaviour of charged particles in solutions and model what happens when the liquid evaporates or when other ions, which may attract the original ones more strongly, are introduced. It is far more attractive and honest to approach the subject of ionic bonding from a precipitation perspective. Even in the case of the reaction of sodium with chlorine, it’s extremely disingenuous to imply that the reaction is as simple as a gaseous sodium atom passing an electron to a gaseous chlorine atom. Most ionic substances have not been formed from direct electron transfer. In order to avoid students picking up misconceptions about ionic bonding, 1,2 Keith Taber recommends that teachers avoid approaching the formation of the ionic bond from an electron transfer perspective, which is often coupled with the popular demonstration of sodium reacting with chlorine. The crystals are best viewed under a collimated light source, such as an overhead projector. This process can take an hour or more, so return to the flask later in the lesson or have a pre-prepared sample to hand. As the water cools, stunning golden hexagonal crystals of lead iodide begin to crystallise to give the ‘golden rain’ effect. Place the flask in some water at 60–70☌ and all the crystals should dissolve – any traces of cloudiness can be removed by the addition of a few more drops of acid. The precipitate can be recrystallised to form more homogeneous crystals. The tiny crystals of lead iodide that form swirl beautifully in the flask and the concentration gradients combine to generate an effect that looks like the atmosphere of a glittering gas giant. Next, quickly add the remainder of the lead nitrate. Slowly adding the lead nitrate solution to the potassium iodide solution produces beautiful yellow swirls that dissipate and redissolve as the lead iodide spreads and dilutes. Gather the students around closely or set up a visualiser. The addition of a few drops of 1M HCl is useful – lead carbonate formed in impure water has a very low solubility and the haziness of its precipitate can ruin the effect. The potassium iodide is in excess to maximise the chances of precipitating lead ions out of solution and reducing the possibility of washing away dissolved lead during disposal. 0.3 g lead nitrate (see hazards of this below)ĭissolve the solids each in 100 cm 3 of distilled water.Thankfully, the ‘seen it before’ mentality is easily avoided with this reaction – the ‘golden rain’ demonstration is a stunning suspension of glistening yellow crystals. I show the reaction again to my older students and ask them to sketch particle diagrams to explain what they are seeing. The younger students see this reaction when I’m introducing ionic bonding. The precipitation of lead iodide from a solution of potassium iodide and lead nitrate is so dramatic and engaging that I use it both with my 11–14 and 16–18 year old students. Before I even try to teach ionic equations I check to see if my students have picked up any misconceptions about how ions behave in aqueous solution.
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