​@Lázár🏳️‍🌈⃠ ... Nile red likes to put on a show 😂 he is in if for the money, he only uploads when he wants to and his chemistry is expensive and inaccessible for most people. For learning and chemistry on a budget this is the best chanel online! No adverts and self promotion ❤

@@Jawstdon’t think it is for the money because he started at his parents garage and the got his dream fume hoodes setup and he pays rent for it, and from time to time he goes back to his parents garage for fun I DONT THINK IT IS A GOOD IDEA TO COMPARE THE CHANNELS BECAUSE NILE RED CAN DO A LOT OF SOLUTIONS AND ELEMENTS HE CANNOT DO but it is still a really good channel but not as good as nile red Edit: srry dictation mistake

​​@@Jawstyoure wrong, just wrong. If he was in for the money he would pump out more videos

Both are awesome Scrap Science is amateur accesible while nile red is fun to watch for the chemistry behind it, even tho it might not be accesible for the amateur I personally find myself rewatching scrapscience, nurdrage, thy's videos many times! they are great and that chemist has confirmed they actually are in some sort of network lmao

He is doing only stupid shit and faking the results. Don’t motivate this retardaned person…

Can you make Sodium Chlorate from lead, then adding salt to water and H2SO4 then electrosis, and can you make explosive with this for replacing Potasium Chlorate?

​@@iamsonedisoncahaya4845adding H2SO4 to NaCl solution makes HCl gas so donr add sulfuric acid and preferably make PbO2 anodes before

Nice

Hi i need a better explanation please 🙏 😊

NaI is harmless in this rea anyway

but at the end of the cell's run the chloride levels are really low so it doesn't participate out much

Pool salt is the most straightforward. And cheap as hell.

i don't mean to be an ass but man the way you write the formulas pains me deeply.

Sodium chlorate is more explosive ..tho

@@impatientpatient8270 considering I see people on yt write it as "KC103" all the time it could be worse

@@dc-gs3ld what a cursed piece of text

Which is better in combination with diesel if you know what I mean…

Evaporated seawater contains about 50% of NaCl, so it would be very impure

​@@foxpaw474official5I use salt from sea water and it still works fine

I'm slowly building up to it, haha. I keep putting it off because I feel like I need to learn more about perchlorate cells before I actually build one. Additionally, given the size of my channel now, I think it's possible that any video I make on perchlorate cells might become one of the most widespread of its kind on KZbin (that's not saying much - there are just so few videos about perchlorate cells here...), so I think it really needs to be a very well-researched production. It'll come eventually!

​@@ScrapScienceplease make a perchlorate cell soon 🙏 there is so little information on youtube and i dont know wich anodes to use how to destroy the remaining chlorate and i think your video could help me qnd other hobby chemists

I've always wondered about these deposited PbO2 anodes. Doesn't something simpler work? Like anodizing some lead in sulfuric acid or copper sulfate or whatever. Make them nice and black with oxide. Or is that too thin?

Interesting... maybe I'll need to make some more at some point then. And yes! I'm a fan of your work on PbO2 anodes. It's a little beyond what I can manage myself, but it's very impressive to watch nonetheless.

​@@6alecapristrudel that will not work because you need either a nonporous or thick mesoporous PbO2 deposite which can only be done with careful electrodeposition. It also needs careful control of the plating current density and bath temperature to make a good enough anode for long term use.

@@CatboyChemicalSociety Ok fair enough. I was just wondering since it seemed so easy lol. I managed to make a PbO2 rod as thick as my pinky finger once by accident. I was making some acid from CuSO4 with this thick rod of solder as anode. It was holding up nicely, but after I plated out the copper I saw that I was leaching tin out of the anode. So I kept going. I got over 20g of tin out of the solder without it changing shape at all. I assume what was left in the rod is some sort of porous PbO2. It was noticeably lighter and cracked instead of bending. Not sure what alloy it was since 60/40 doesn't really leach tin IME. Higher tin content probably.

@@6alecapristrudel indeed its fine in an environment containing SO4 ions because the Pb2+ species is not very mobile in this liquid due to insolubility of PbSO4 and thus the anode will not corrode and instead oxidize to PbO2. but in electrolytes containing chloride/chlorate the ions will be more mobile which will cause them to migrate to the cathode and plate out lead metal. This also causes the anode structure to corrode if the liquid reaches the lead layer but while this process can be halted at pH of 9 it still will occur enough to create these stalactites of PbO2 due to this effect which still corrodes the substrate.

This exact procedure can be followed with the use of graphite electrodes instead of MMO/titanium if you need. The only extra thing you'll have to do is filter the resulting graphite particles out of solution before you crystallise out your product. I talk a little more about electrode options in my potassium chlorate video, but that's the gist of it. Stainless steel (and mild steel for that matter) can be used as a cathode, but definitely not as an anode.

@ScrapScience thank you very much for the response ! It's much appreciated...

Lead oxide is also pretty easy to make and reasonably durable. But brittle so avoid rapid temperature changes or mechanical shock. If you use graphite, prefer plates over rods. The erosion of the electrode will increase as the amps per unit surface area increases, so you want a shape that keeps the total surface area as stable as possible as it wears out, otherwise a little wear bumps the current/surface ratio up, which accelerates the wear, which bumps the ratio and the whole thing turns to carbon particle sludge distressingly quickly.

@laurenceperkins7468 good advice, thank you !

How ı do chlorate? You have Instagram? I have a question please

Filtering is a little tricky since the oxidising solution tends to eat through paper. If you're careful and don't apply too much pressure to the filter, you can probably still get away with using paper towel or a coffee filter though. Note that the use of carbon will probably make your chlorate yellow even after filtering, but the contamination is generally extremely minor despite the strong colour.

@@ScrapScience thanks mate, sounds good.

First let it settle for a day or so and decant it, to get rid of most carbon particles and after that, I would press a cigarette filter into a tubing, so that it's sealed up with the walls and pump the solution through it. That should be good enough to get it clear again.

​@@ralfvk.4571 Thanks for all the tips! Decanting worked well enough (the solution had been settling for weeks, I've been too busy lately to take care of it earlier sadly). I just filtered the rest through a coffee filter, which worked well enough to get rid of the particulates at least. Sadly, I'll never know how much chlorate I had in solution; as I was boiling it, the ""heat proof"" glass I was using shattered and spilled the solution everywhere. lmao. I'll try again soon (I have a much bigger and higher amperage setup prepared), and maybe attempt that cigarette filter trick. not sure yet.

As a poor people i can aproof that i make Sodium Chlorate from Lead or Battery rod then add mixture salt and H2SO4 then electrosys.

A good way to blow yourself to smitherines! Do not have any flame anywhere near the exhaust tube or cell! 💥🙈

What kind of furnace and how much electricity it takes

This exact procedure can be followed with the use of graphite anodes instead of MMO if you need. The only extra thing you'll have to do is filter the resulting graphite particles out of solution before you crystallise out your product.

​@@ScrapScienceDo graphite pencils work?

What if we put a cloth on the graphite to filter and prevent pollution

@@slimani373 They work, but they fall apart even faster than plain carbon/graphite, because they are technically a mixture of graphite and clay. Adding a fine filter during the electrolysis might work, but the filter itself might start acting as a diaphragm and preventing hydroxide ions from properly migrating towards the anode. Why not just filter the solution after it's finished? It will achieve the same effect as far as purification is concerned.

​@@ScrapScience That is, it is easier to filter and make potassium chlorate or sodium chlorate

The problem isn't inherently the oxidation, because as you've noted, it's possible to remove oxides from solutions. The real issue is the fact that the oxidation of the anode will completely replace the desired reaction of forming chlorate ions. The oxidation of iron (or any other standard metal for that matter) is an easier reaction than the oxidation of chloride to chlorate, so all the energy you put into the cell will go towards destroying your anode, and virtually none will go towards the reaction you want.

Yet graphite also breaks down, albeit much more slowly, what reaction is going on there, and does it dominate ?

Yep, graphite does also break down. This is mostly due to an extremely small degree of oxidation on the graphite structure (a few small sections are oxidised to CO2, breaking apart the surface of the graphite material). In contrast to the reactions that occur on iron, nickel, copper, or any other standard metal, the oxidation of graphite is an extremely minor reaction, allowing most of the input energy to go towards chlorate generation.

Yep, I thought I did. I worked everything out using the solubility products. Still must have done my calculations wrong though.

@@ScrapScience hmmm what calculation method did you use?

One day

A chlorate cell is (from a technical perspective, at least) extremely simple - electrolysis of a choride solution with inert electrodes. A chloralkali cell, on the other hand, requires a separator between the anode and cathode, to ensure that the products on each electrode are kept separate. In a chlorate cell, the cathode generates hydrogen and hydroxide ions. The anode will oxidise chloride ions, and with the hydroxide ions freely available to interact with the anode (no separator between the electrodes), this oxidation of chloride in the presence of hydroxide will yield hypochlorite ions. These hypochlorite ions can eventually be oxidised again by the anode to form chlorate ions. In a chloralkali cell, the cathode once again generates hydrogen and hydroxide ions. However, due to the separation of the cathode and the anode (with a porous diaphragm or an ion exchange membrane), the oxidation of chloride ions on the anode is not performed in the presence of the hydroxide ions, leading to the oxidation product of chlorine gas instead. Overall, the anode will make chlorine gas in this setup, whilst sodium hydroxide will accumulate around the cathode.

At that point in the video, I'm just filtering everything, and then placing the filtered solution back into the original beaker to be further boiled down. You've got the correct idea here.

I just pulled them out. The silicone broke with enough force.

@ Thanks! I’m thinking about taking it apart since my cap is corroding.

Yep! That'll do the trick. It's generally pretty difficult to filter out all of the graphite particles though, and your product might still have a slight colour after you crystallise it. This isn't a problem for most purposes though.

For the cathode, many metals can be used (titanium, stainless steel, mild steel, and nickel can all be good options). For the anode, stainless steel definitely won't work, and you are severely limited in your choice of anode material. The only reasonable choices here are platinum, graphite, or the mixed metal oxide I use in this video. Basically every other metal will oxidise, fall apart, and leave you with zero chlorate product. I talk about this in a little bit more detail in my other video on chlorate cells, which you can find in the description here.

Thank you very much for your answer!

The more recrystallisations that are performed, the less NaCl will be included in the product. If exceptionally pure chlorate is required, three or four recrystallisations may be needed (though this will also lose product, so it's a tradeoff). And yes, recrystallisation of the starting salt could be done, but it's not really going to impact the overall process, since most common impurities won't interact through the electrolysis anyway.

Stainless steel will not work for this process when used as an anode. The only easily-purchased anode choices are platinum, MMO (as I've used in this video), and graphite/carbon electrodes. I go into this in more detail in my other video on chlorate cells (link in the description).

Unless you are constantly adding sodium chloride to the cell, sodium chlorate will never crystallise from solution. The chlorate is more soluble than the chloride. Additionally, what electrodes are you using and what current are you running things at? The current will determine your reaction speed.

Are you constantly measuring current? Has the current increased or is this extra gas generation occurring at the same current as before?

@@ScrapScience No, the current and voltage themselves did not increase anything, and as for the electrodes, I use carbon electrodes, and as another note? When I want to extract sodium chlorate from the solution, I do not evaporate half the amount of water because the crystallization process does not work for me, meaning the chlorate does not crystallize at the bottom. No matter how much I evaporate half the amount of water and leave it to cool, I do not find any chlorate crystallization. Instead, I evaporate all of the water until only salt remains. Is this the case? It is true, and even if it is true, how do I separate chloride from chlorate after the total evaporation process?

An increase in gas formation still sounds most likely to be from the cell drawing more current as it increases in temperature (this is common for cells that are supplied with a fixed voltage). However, if you're directly measuring current and confirming that it is not changing, it's a possibility that you've begun generating more oxygen as the choride level drops, though this is still a very strange situation. If you're unable to crystallise chlorate out of the cell upon volume reduction, you probably just haven't made enough. Do diagnose this properly, I'm going to need to know a lot more about your cell: How big is your cell (in mL)? How much current has it been drawing? How long did you run the cell for? How much chloride did you add? And in what intervals? Did you include other additives? What are the surface areas of your electrodes? To answer your final question, simply boiling down the cell solution to dryness will give you your chlorate. However, it will definitely be contaminated with significant chloride impurity (as you've suspected), and will need a recrystallisation if you want a pure product. What do you actually need the chlorate for? It's possible a potassium chlorate cell would be more appropriate for your needs...

It only takes a couple of minutes for the hydroxide concentration to build up to the point where chlorine is retained, so I wouldn't worry about it honestly. Also, doing this makes it somewhat difficult to prevent overshooting the pH. Even just adding an extra half of a gram of NaOH to a cell of this size would push the pH way above the ideal value of 9-10, and possibly damage the anode with the strongly basic conditions. You can definitely do it if you want to minimise the chlorine generated at the start of the cell run, but be careful of overshooting the amount of hydroxide.

Boiling the solution definitely won't decompose the sodium chlorate, so there are no worries there. However, a metal pot probably isn't the best, as it might be oxidised by the chlorate. Boiling it in glassware is the best way to go. It's probably not really necessary to put it back in the cell, since you're not really seeing decomposition here.

@@ScrapScience I vaguely recall that a yellowish tinge is the color of hypochlorite, so just means it's concentrating, but hasn't converted yet.

In the case of having an equal stoichiometric amount of sodium chloride and sodium chlorate in solution, you're completely correct that chloride would crystallise first if you boiled down the solution or cooled down a saturated mixture. However, we didn't have equal amounts of each in solution. We had a little bit of the chloride and a LOT of the chlorate. In this case here, we could rely on the difference in solubility curves between the two salts (which you can find here: shorturl.at/rOR48 ) to get our crystallisation to work. When crystallising, we aimed to boil down the solution (reducing its volume) to the point just before the chloride crystallised. At this point, we stopped heating the solution and allowed it to cool. The solubility of chloride is almost independent of temperature, as you will see from the linked graph, so none crystallised on cooling. However, the chlorate solubility sharply decreased with cooling, so since we had so much in solution, we forced the chlorate to drop out even though it's more soluble. Boiling alone won't give you the chlorate, but if you stop boiling at the right time, you can just crystallise the chlorate by taking advantage of the temperature solubility curves.

If you want to know about the basics of the process, you should watch my video on the potassium chlorate cell. It's linked in the description, and goes over most parts of the general process. This particular video is more of a sequel to that one, where the process is modified for the sodium salt. As for the voltage and current, the general rule is that you should use whatever voltage will give you 20 mA per square centimetre of exposed anode area (for graphite electrodes specifically). If this requires more than 5 volts, you should ignore this rule and keep the supply at a 5 volt potential. A current and voltage controlled power supply is best here, since you can then set the maximum voltage to 5 V, and the maximum current to 20 mA per square centimetre of exposed anode area. For the amount of water you need, this will depend on how you want to run the cell, and how big you want the cell to be. Do you want a batch process where you will be slowly working through your 500 g of starting material? Or do you want to do everything in one go? The simplest way to go about this is to just use enough water to dissolve everything, and electrolyse from there. For the runtime, this is a subject too complex to explain in a KZbin comment. It will rely on the quantity of starting material, the current, and the efficiency of your cell, among other things. You'll have to do some research and some stoichiometric calculations here. I haven't yet found a good resource for doing these calculations, but this is a relatively good start: www.chlorates.exrockets.com/runtime.html

If you went with those carbon rods from batteries you are probably still running the 500g salt cell 4 months later 😂

Nice...

also a fun fact, I bought my KCl from a chemical supplier it sait 99% pure but it had anti-caking agents in it so I have to filter this stuff every time I use it :P

Ouch, unlucky... It's always annoying to have to filter your solution before you even start a synthesis.

how was that a fuckng year ago AAAAAAAAAAAA

Boiling and recrystallisation is much, much faster than evaporation. I'd definitely consider it the most convenient option, even if it's not technically as easy as evaporation.

After I filtered the crystals, I just rinsed the crystals with ice cold water as they were sitting on the filter paper. This rinsed away any adhered NaCl solution. (The rinsing water needed to be cold to avoid redissolving too much of the product)

@@ScrapScience Ahh ok I understand, makes sense colder the better to an extent. Catching up on terminology lol. Thanks for your response!!

@@ScrapScience little update. Whatever I manage to precipitate or crystalize out of solution, I'm assuming is 25-30% purity. No matter how many times I try to recrystalize, it is contaminated with what I assume is sodium chloride. My starting solution is saturated to the point of recrystalizing the chloride approximately 10°c below ambient temperature (~5°). Is this caused by not enough time under electrolysis, insufficient current/voltage (3.3v @ 2A CC) or starting solution?

Either way is fine, though adding a solution is generally a better option.

Yeah, definitely. I just wasn't too concerned about the efficiency for this one, and I didn't have a smaller cathode.

Would a porous membrane help? Or a using a salt bridge setup?

@@petrlaskevic1948 if you do that you'll end up with hydroxide on one side and hypochlorite on the other.

@@chemistryofquestionablequa6252 Oh right, so you need to mix the hypochlorite with the hydroxide to make chlorate while blocking the chlorate from reducing to chloride at the cathode, (which is done by adding dichromate, if you have it) What if you generated hypochlorite on one side, hydroxide on the other, turned off the electricity when both solutions are concentrated, and then mixed the two solutions to make chlorate. Would that work? With potassium ions, the formed chlorate would precipitate in potassium chlorate.

@@petrlaskevic1948 I suppose you could, hypochlorite disproportionates to chlorate and chloride when boiled, but you'd get terrible yields and make a lot of extra work for yourself.

Mixed metal oxide and carbon electrodes will only convert chloride to chlorate, and will not make any appreciable amount of perchlorate, so this isn't an issue for this type of cell. When using platinum or lead dioxide (which are able to make perchlorate), it still isn't too big of an issue. The presence of the initial chloride in the cell diminishes the efficiency of making perchlorate to a large extent, so you generally don't generate any unless you allow the cell to continue running for a very long time. If you were to run the cell for that long (which will ruin the electrodes to a large extent), the conversion to perchlorate is also accompanied by a sharp increase in voltage, so it's easy to spot when it starts.

I'm going to cast some extreme doubts on that, but alright...

At 40 amps, it definitely will go much faster. However, It's important to take the limits of a cell into account. For my cell here, 40 amps would be too much for my electrode surface area, would heat up the cell excessively, and would fry any of the electrical connections I'm relying on. With a bigger cell and electrodes that can handle it, 40 amps is an excellent idea if you want large quantities of chlorate.

@@ScrapScience Thank you very much, please tell me how much faster the process will go in one day is it possible?

I don't really understand your question. It will be nearly impossible to make this much chlorate in a day with a cell like this. You'll need a larger, better designed cell if you want to make reasonable amounts of product in such a short time.

Glad you enjoyed! I'm not actually aware of any reasonably easy methods of measuring the purity of the chlorate (if you're aware of any, let me know!). However, given the flat nature of the sodium chloride solubility curve, we can be confident that the process of crystallising the product by cooling the solution will be extremely selective for separating out the chlorate. Seeing as we did two stages of this crystallisation, the final yield should have very minimal chloride content (though to completely eliminate it, I'll probably do one or two more recrystallisations...).

i have a question. what is the difference between naclo3 and kclo3? i've heard that sodium is a bit less reactive and unstable. i want to use sodium chlorate for flas powder but i am a bit scared that it wouldn't be good enough (to sensitive to explosion) and probably to weak. the problem is that potassium chlorate is way too expensive compared to sodium. do you have any idea to help me with? thanks@@ScrapScience

There are no reliable signs that will always tell you when the chloride concentration is low. You will need to work this out by calculations involving your expected cell efficiency, quantity of chloride, and cell current. I don't really understand anything else you're asking here, sorry.

A great question! This is rather complicated to explain in a single KZbin comment, but I'll give it a try. In the case of having an equal stoichiometric amount of sodium chloride and sodium chlorate in solution, you're completely correct that chloride would precipitate if you boiled down the solution or cooled down a saturated mixture. However, we didn't have equal amounts of each in solution. We had a little bit of the chloride and a LOT of the chlorate. In this case here, we could rely on the difference in solubility curves between the two salts (which you can find here: shorturl.at/rOR48 ) to get our crystallisation to work. When crystallising, we aimed to boil down the solution (reducing its volume) to the point just before the chloride crystallised. At this point, we stopped heating the solution and allowed it to cool. The solubility of chloride is almost independent of temperature, as you will see from the linked graph, so none crystallised on cooling. However, the chlorate solubility sharply decreased with cooling, so since we had so much in solution, we forced the chlorate to drop out even though it's more soluble. Boiling alone won't give you the chlorate, but if you stop boiling at the right time, you can just crystallise the chlorate by taking advantage of the temperature solubility curves.

@@ScrapScience ingenious! Thanks for explaining, this is completely clear to me now!

Generally, yes. Chloride should precipitate first if you increase the concentration of both. However, in this case, we don't just have a mixture of the chloride and chlorate - the cell is actively converting the former into the latter. At the beginning of the run, we have a saturated solution of chloride, and we then start turning this into chlorate. As we do this conversion, we physically add more and more chloride to the cell to account for the amount we're converting, keeping the chloride concentration close to the saturation limit. Repeating this process for a while keeps the chloride levels relatively constant (not enough to start crystallising out), while the chlorate concentration steadily increases. Eventually, after enough chloride addition and enough electrolytic oxidation, we have such an excess of chlorate in solution (>100g/100mL) that it must start crystallising out. That's the basic idea anyway. It gets a little more complicated when you have to take solubility products into account.

@@ScrapScience Thank you, that makes sense, but if I did a recrystallisation by dissolving the product in the water and boiling it should I expect the chloride to now precipitate out first since the concentration would now be increasing for both? Or will the chlorate still precipitate first because of the solubility curve. Edit: also to add, wouldn’t it be better to not boil down your final solution and instead just keep topping it off with the chloride, decant the top and take the crystals? So instead of taking 2 weeks for you to start getting the chlorate you just add some chloride to the super concentrated chlorate solution and get some more on demand?

For your first point: Yeah, if you crystallise exclusively by boiling down a mixture of sodium chloride and chlorate, you'll get the chloride crystallising out first. However, the difference in solubility curves is extremely useful if you don't quite crystallise out any chloride in the boiling step. If you manage to boil down the solution to the point just before the chloride crystallises, you can stop there and allow the solution to cool. The solubility of chloride is almost independent of temperature, so none will crystallise on cooling. However, the chlorate solubility sharply decreases with cooling, so you force the chlorate to drop out. Again (to summarise that lengthy explanation), boiling alone won't give you the chlorate, but if you stop boiling at the right time, you can just crystallise the chlorate by taking advantage of the solubility curves (as you're referring to in that last sentence). For your edit: Are you talking about doing future runs of the chlorate cell? In that case, yes, the final decanted solution from this cell would be an ideal starting solution to make a new chlorate cell. It's already saturated in chlorates and ready to go for more electrolysis.

This video is about making sodium chlorate from sodium chloride. I have another video about making potassium chlorate from potassium chloride, which is linked in the description. If it's ever difficult to understand what I'm saying, subtitles should also be available for this video.

@@ScrapScience tank you

It depends on the electrodes you're using. Generally, no.

That’s an extremely broad question. First of all, 12 volts is way too high for this process. A current-controlled supply is ideal, and standard cells will probably require 3-5 volts for a reasonable current draw. The runtime of the cell will depend on many factors, including: - The size of the cell - The set current - The desired quantity of chlorate - The anode/cathode choice - The current density on the anode/cathode - The temperature of the cell - The pH control For any given cell, you can calculate the theoretical production rate. This requires some understanding of stoichiometry and how charge transfer relates to current, and isn’t something I can explain in a single KZbin comment. You’ll need to do some research here if this type of calculation isn’t familiar to you.

@@ScrapScience I am wondering about 5% or 1 liter water 1% rate of naclo production, do you have any information about what are the required rates?

I don't understand your question here. What are the percentages and volumes referring to? And what do you mean by rates?

@@ScrapScience do you know the production of sodium hypochlorite me 5% or 1% concentrate with electric

Okay, so we're talking about hypochlorite. Designing your own system is pretty useless in my opinion. You can buy hypochlorite generators for like $10 online.

It's a little difficult to explain the basics of this kind of calculation in a KZbin comment, so I'll direct you towards a website that gives good explanations on how to make predictions of the cell runtime and production rate: www.chlorates.exrockets.com/runtime.html

@@ScrapScience Hmm could there be something wrong there's no chlorate crystalizing even though I pumped the amps to 10 but there's definitely hypochlorite being made am I just too impatient I checked the calculations and I will use them next time because I don't really remember how much salt I used.

The time things take to crystallise will depend on the volume of the cell, how much salt you initially added, the temperature of the cell, whether or not you're topping up with more salt as you go, and whether you're running a sodium or potassium cell, among other things. Without knowing how much salt you added to begin with (or any of the other factors mentioned above), it's pretty much impossible to predict when you'll get crystals. If you're running a sodium cell, it will take a long time to get crystals (if you get any at all). Generallym, you'll only get sodium chlorate crystals if you add more chloride than is required for a saturated solution. If you're running a potassium cell however, the crystals are much easier to get, and will usually come out within a few days of running a cell this size.

@@ScrapScience I added some more salt yesterday. Does the voltage increase when the chloride concentration is decreasing and is it possible that only hypochlorite is being made but not chlorate

And thanks for answering to my questions!

You don't need to keep the temperature high or do pH control to build a working cell. Doing these things will increase efficiency (if you perform both techniques), but they are complicated to set up and are definitely not essential.

Does this mean that it is only the concentration of the solution that determines whether the brine becomes sodium hypochlorite or sodium chlorate during electrolysis?

Concentration of your initial chloride doesn't have much to do with it. With no pH control, you will oxidise chloride to hypochlorite, and then when the concentration of hypochlorite gets high enough, you will oxidise it into chlorate. This is two steps of anodic oxidation. With pH controlled to 6.7 and temperatures around 70 C, you will still start generating hypochlorite, but then the hypochlorite will automatically disproportionate to produce chlorate (a more efficient reaction). This is one step of anodic oxidation and one step which is purely thermally driven. I have another video on chlorate cells which goes deeper into the chemistry here: kzbin.info/www/bejne/eaKwdqGohsdop5o

I see. Thank you very much.

Only with very pure chlorate, the correct electrodes (MMO anodes will not work), and an additive to prevent back-reduction. I'll eventually make a video about this.

@@ScrapScience Thank you, I hope you make that video

Yep, you got it. Just a bit of heat shrink around the rods prevents a short.

On a short timescale, the cell heats up a little due to ohmic resistance. As a result, the conductivity increases and you need less voltage to pass the same amount of current.

MMO and titanium. I talk about this at 1:21, and go into it more extensively in my video on potassium chlorate cells.

Thats not how it works

@@user-vj8dz8ht2c thanks, i learn alot from that reply! i will correct my mistake from now on👍😁

@@user-vj8dz8ht2c I just watched NightHawkInLight about making infared cooling paint, I learned that crystals forms through concentrations and that impurities are just starting point of nucleation for the crystals. You are right.

No worries! Answers are as follows: 1) If it's the type of jar I'm thinking of, the white coating is not enough to stop the lid from being attacked by the chlorine and oxidising solution. You need a jar with a plastic lid if you want to avoid corrosion. The jars I use in my own chlorate cell videos have a thick (~5mm) plastic disc underneath the metal that is capable of protecting it. I found them in a garage sale and I've actually been unable to find anything else like them... 2) Most ATX power supplies will provide appropriate current for any moderately sized chlorate cell. I've never seen one that would be inadequate for the task. For my own cells, I used the 12 volt output hooked up to a buck converter to give me controllable voltage and current. The exact current you need will depend on the surface area of your electrodes, the size of your cell, and your personal preference. 3) That will depend on the size of your cell and how much chlorate you want. This isn't really something that can be explained in a KZbin comment alone, so you'll need an understanding of stoichiometry to do these calculations. As a starting point, this website gives an overview of runtime for a certain quantity of starting chloride material: www.chlorates.exrockets.com/runtime.html 4) Is the fibreglass sheet fibrous or solid? As long as liquid can flow through it, it should work. You just want to use it as a filtering medium. 5) I talk about the crystallising and drying stages from 14:03 to 17:50. In particular, I show my method of drying the crystals at 17:01. Hope that helps!

Thank you so much , i will not bother you again about this matter and i will mention you in the description & video 😊​@@ScrapScience

Yes

It's possible. The small amount of iodate content in iodised salt won't affect the process to any large degree. Your final product will likely be contaminated with traces of iodate, but this is unlikely to be a big deal and can be fixed with good recrystallisation techniques.

Because I only built the cell to handle around 4-5 amps.

@@ScrapScience Thank you. It could have been thought that the slowness is necessary for the reaction to go well.

You can, but your solution (and product) will be filled with microscopic particles of graphite due to the slow erosion of the electrodes. These particles are very difficult to filter out, and will make your chlorate product appear darker. Additionally, the graphite electrodes eventually need replacing. If you don't mind either of these caveats, graphite electrodes are fine to use for this process.

how about after i finish the electrolysis process using the graphite electrodes i filter the solution using coffee filters then i let it sit for a few days, after that i think the sodium chlorate will cristalis and the left impurities would stay in the solution ???🙂@@ScrapScience with the added bonus that the chlorate would be more than 99% pure at this case

No clue. Sorry. I'd never even heard of potassium chlorate's use as such before now.

To some degree, yes. However, this effect won't kick out much, and definitely won't even come close to crystallising a significant portion of the sodium chloride. The overwhelmingly more important factor is the fact that we're removing chloride from the solution by turning it into chlorate, and this happens faster than the solubility of chloride decreases.

How do we know that all chlorides have been converted?​@@ScrapScience

@slimani373 you don’t want all of the chloride to be converted. That will damage the anode significantly. Instead, the cell needs to be stopped when there’s still some chloride in there, and chlorate needs to be crystallised out to separate it as a product, as I show in the video.

For the following reasons: 1. This is a well-known reaction. 2. Sodium chloride's solubility curve against temperature is basically flat, so it would not generally crystallise out when decreasing the temperature of the solution. 3. Sodium chloride does not act in the way shown at 21:30.

@ScrapScience agreed. But if your adding sodium chloride to the cell keeping it saturated hot. Then when it cools to room temp some salt will precipitate if not all used up and converted to sodium chlorate. I made that mistake the first time in ran a cell.

Temperature has minimal effect on a cell that isn't pH controlled. Chlorate is produced regardless of temperature under these conditions - NaOH is only ever a minor constituent in solution. If you'd like a complete description of the chemistry going on here, you can find it in my other video on chlorate cells: kzbin.info/www/bejne/eaKwdqGohsdop5o

@@ScrapScience Wow! Thx 🙏

I don't know what you're talking about here. Are you asking about using lead as an anode material?

Technically, yes from a chemical perspective, but 12 volts is far too much for this kind of process. Most energy will be dissipated as heat (making your cell extremely hot), and the combination of high temperatures and high current density will likely destroy your anode very quickly.

It is true that the anode was quickly destroyed, which is a steel nail. I need a way to shorten the time

A steel anode will not work to generate chlorate I'm afraid. The only viable anode choices that will give you a meaningful yield in this process are platinum, graphite, and 'mixed metal oxide' (which I use here). Using pretty much any other commonly available material as an anode will result in the oxidation of the electrode instead of the generation of chlorate.

@@ScrapScience Thank you very much

@@ScrapScience Thank you, dear brother, for your cooperation with me, and I need you to answer my question: How much time do I need to convert 100 grams of sodium chloride into sodium chlorate using graphite electrodes and mobile charger.

Nope, after the electrolysis finished running, I just boiled the solution straight from the cell.

Yeah, I didn't re-dry the potassium salt before the test, that might be it. However, the potassium salt isn't actually hygroscopic, it's just the sodium salt in that regard, so it shouldn't have mattered anyway... Maybe I just didn't dry it well enough to begin with.

@@ScrapScience IDK I'm not much of a chemist, honestly just hoping I say something insightful.

why 30v? Another good way is that you can use a generic PC power supply (that outputs 12v) along with a dc-dc converter (you can get 20A ones for about $10)

@@nicktohzyu That is just the range the supplies come in. They are fully adjustable, constant voltage and constant current from zero to their limits(30v, 10A in this case). I know he uses constant current mode a lot and these do it well. These are simple linear supplies, so tend to survive a lot of abuse well. Mostly just want him to have two supplies and far less dodgy leads. :)

Haha, I appreciate the thought, there's really no need to send any money though :). The cardboard box power supply has been here for such a long time, I always forget how dodgy it looks... It's always been pretty handly to be able to supply 20-30 A on occasion, and since it still works, I've always prioritised other things when it comes to lab purchases, but maybe it's time for an upgrade. Better leads as well... that's a thought. The connections tend to corrode so fast (when using them for electrochemistry) that I always buy the cheapest ones I can find because they rust like crazy in a few months anyway. Maybe the big copper clamps and some banana plugs might be a better way to go. I'll definitely look into a better power supply/connectors, that'll make a good choice for the next lab upgrade. :)

@@ScrapScience Nothing wrong with using an old PC supply as first stage, will be using a dozen of them in an big LED exhibit over the next few months, the only difference is all the connections will be crimped and soldered. But PLEASE upgrade your leads! Both the ones to the cells and from the main PSU to your DC-DC box. Those test leads really are never good at the best of times(I know, I've used and destroyed plenty!). I'd suggest some of the silicon wire used by RC plane/drone makers, it's cheap from all the normal places, highly resistant to temperature, very flexable and made for heavy currents. And you can even re-use the croc clips from these cheap leads, when they corrode, cut them off and solder new ones on. :) (And save the propper crimped/solderd connectors for the PSU/switcher end, away from the corrosive stuff.:)

@@ScrapScience what about painting on a conformal coating (like nailpolish etc) whenever you connect up a cell, then just tear it off after you're done?

The inert anode in this case is a mixed metal oxide (MMO) anode - also known as a dimensionally stable anode (DSA). It is a titanium substrate coated with a mixture of ruthenium dioxide and iridium dioxide. Platinium also works. So does graphite.