As the material I recieved few days ago is very nice and illustrative, I decided to share my refining venture of the lot.
85,5 grams of AgPd contact cuttings, on ferrous carrier (altough looks like copper, it is only copper plated ferrous alloy).
Beads itself are 29-30% Pd by weight. So I expect around 15-18g of Pd in this batch.
I started by dissolving the ferrous carriers in dilute nitric acid (ca 25%) - great caution should be taken during this step as reaction is very exothermic and tend to runaway and foam a lot. When cold, nothing spectacular happen, but after the solution warm itself due to heat of the reaction, it goes exponential - to the boiling point in less than 2 minutes in my case
I was aware of this, so I prepared large 2L beaker for the reaction of only around 20-30g of iron. When reaction ceases, you are left with ferrous colloid goo, which is then diluted with cold distilled water and concentrated sulfuric acid is cautiously added in small portions with stirring until it gets liquified and vast majority of iron hydroxy-nitrates goes into the solution as ferric sulfate.
If you don´t overadd nitric, you are left with just beads of the AgPd alloy, and only trace AgPd goes into the solution - you conveniently scavenge traces of Pd with DMG later, and if you are after tidbits of silver, you can add NaCl solution and let the solution settle for few days and harvest the AgCl. Simply decant the iron solution from the beads and you done majority of the cleaning process from base metals
Be aware of the fact that nitric undergo deep reduction when reacting with iron, so mainly NO is produced as reaction byproduct, and you exchange nitrates to sulfates when you add sulfuric acid - reviving the free nitric, which is then able to react. So overall, very little nitric is consumed, if done cautiously and properly - that way nitric is only used as oxidant, and all iron and other base metals are left in solution as sulfates.
In my case, I just used straight dilute nitric at the start, because ammount of material was small and I did not have time to play around with sulfuric aditions to save around 20 mL of nitric
Then, beads are dissolved in 50% nitric. Unless you do not heat the solution strongly, the reaction is very slow.
After full dissolution, I diluted the brownish red solution (I love that colour ) with distilled water and poured the AgPd solution slowly into vigorously stirred ca 15% HCL. You need to use ammount that conveniently converts AgNO3 to AgCl and also Pd(NO3)2 to H2PdCl4, and you should be left with excess HCL in solution - otherwise bigger ammount of not very soluble PdCl2 form, which stay locked in the AgCl and it is quite a pain to macerate it out of the precipitate.
Then, AgCl was filtered on fritted glass filter, sucked from majority of the reddish brown liquor, placed in the beaker again and covered with ca 5% HCL to start washing the precipitate from locked Pd. I gave this procedure 3 rounds, and in the last wash, I obtained only slightly orange filtrate, and tan coloured AgCl (obviously some Pd remained in it). It need to be said that this procedure is nowhere 100% efficient, but it is quick for obtaining bulk of the Pd in more than 95% purity (which is sufficient to me to sell it).
There are better ways how to resolve these two elements, but I wont discuss them here now.
Tomorrow, I will proceed to formate reduction of the Pd in the solution
Material on the left, AgPd beads with majority of the iron carriers gone on the right.
Dissolution of the beads on the left, and filtration of pay-juice on the right
In the end of the day, nice to see that colour again we will see how moch we could squeeze out of it.
85,5 grams of AgPd contact cuttings, on ferrous carrier (altough looks like copper, it is only copper plated ferrous alloy).
Beads itself are 29-30% Pd by weight. So I expect around 15-18g of Pd in this batch.
I started by dissolving the ferrous carriers in dilute nitric acid (ca 25%) - great caution should be taken during this step as reaction is very exothermic and tend to runaway and foam a lot. When cold, nothing spectacular happen, but after the solution warm itself due to heat of the reaction, it goes exponential - to the boiling point in less than 2 minutes in my case
I was aware of this, so I prepared large 2L beaker for the reaction of only around 20-30g of iron. When reaction ceases, you are left with ferrous colloid goo, which is then diluted with cold distilled water and concentrated sulfuric acid is cautiously added in small portions with stirring until it gets liquified and vast majority of iron hydroxy-nitrates goes into the solution as ferric sulfate.
If you don´t overadd nitric, you are left with just beads of the AgPd alloy, and only trace AgPd goes into the solution - you conveniently scavenge traces of Pd with DMG later, and if you are after tidbits of silver, you can add NaCl solution and let the solution settle for few days and harvest the AgCl. Simply decant the iron solution from the beads and you done majority of the cleaning process from base metals
Be aware of the fact that nitric undergo deep reduction when reacting with iron, so mainly NO is produced as reaction byproduct, and you exchange nitrates to sulfates when you add sulfuric acid - reviving the free nitric, which is then able to react. So overall, very little nitric is consumed, if done cautiously and properly - that way nitric is only used as oxidant, and all iron and other base metals are left in solution as sulfates.
In my case, I just used straight dilute nitric at the start, because ammount of material was small and I did not have time to play around with sulfuric aditions to save around 20 mL of nitric
Then, beads are dissolved in 50% nitric. Unless you do not heat the solution strongly, the reaction is very slow.
After full dissolution, I diluted the brownish red solution (I love that colour
) with distilled water and poured the AgPd solution slowly into vigorously stirred ca 15% HCL. You need to use ammount that conveniently converts AgNO3 to AgCl and also Pd(NO3)2 to H2PdCl4, and you should be left with excess HCL in solution - otherwise bigger ammount of not very soluble PdCl2 form, which stay locked in the AgCl and it is quite a pain to macerate it out of the precipitate.Then, AgCl was filtered on fritted glass filter, sucked from majority of the reddish brown liquor, placed in the beaker again and covered with ca 5% HCL to start washing the precipitate from locked Pd. I gave this procedure 3 rounds, and in the last wash, I obtained only slightly orange filtrate, and tan coloured AgCl (obviously some Pd remained in it). It need to be said that this procedure is nowhere 100% efficient, but it is quick for obtaining bulk of the Pd in more than 95% purity (which is sufficient to me to sell it).
There are better ways how to resolve these two elements, but I wont discuss them here now.
Tomorrow, I will proceed to formate reduction of the Pd in the solution
Material on the left, AgPd beads with majority of the iron carriers gone on the right.
Dissolution of the beads on the left, and filtration of pay-juice on the right
In the end of the day, nice to see that colour again
we will see how moch we could squeeze out of it.Attachments
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