Your channel is the gift that keeps on giving.. From a fellow gold miner in west sahara... Here the gold is also so small you need to be the size of a bacteria to se it
Looks like a good extraction. I knew the clay would have visible gold. I have been trying to use what I learned from you with slowly elevating results. Hopefully with more experience and experimenting I will have the right eyes to be able to confidentiality read vains and rocks
One goal is to selectively recover silver while avoiding the formation of a protective lead sulfate layer and minimizing lead deposition on the lead cathode. Here's how the process would work: Electrolysis Setup: One side of the electrolysis cell contains the ore sample, sulfuric acid electrolyte, platinum anode, and lead cathode, separated by the Nafion 117 membrane. On the other side of the membrane, a separate compartment contains ionized water and a silver cathode. Electrochemical Reactions: At the platinum anode, water is oxidized to produce protons (H⁺) and oxygen gas (O₂): In the presence of sulfuric acid, lead ions (Pb²⁺) from the ore sample can undergo reduction at the lead cathode: Simultaneously, the silver ions (Ag⁺) from the ore can pass through the Nafion 117 membrane and migrate towards the silver cathode compartment. Selective Permeability of Nafion 117: The Nafion 117 membrane selectively allows the passage of protons (H⁺) and smaller ions such as silver ions (Ag⁺) while blocking larger ions such as lead ions (Pb²⁺). This ensures that lead ions do not pass through the membrane and remain on the same side as the lead cathode. Silver Deposition: Silver ions that pass through the membrane reach the silver cathode compartment, where they are reduced to elemental silver (Ag) by gaining electrons: Avoidance of Lead Deposition: By controlling the electrolysis conditions and minimizing the concentration of lead ions at the lead cathode, the formation of a protective lead sulfate layer can be mitigated. Additionally, the selective permeability of the membrane helps prevent lead ions from reaching the silver cathode compartment. Conclusion: In this electrolysis setup with the Nafion 117 membrane, the goal is to selectively recover silver while minimizing lead deposition and avoiding the formation of a protective lead sulfate layer. By leveraging the membrane's selective permeability and controlling the electrolysis conditions, it is possible to facilitate the deposition of silver onto the silver cathode while keeping lead separate. This approach helps overcome the challenges associated with lead sulfate formation and enhances the efficiency of silver recovery from the ore sample. The described electrolysis setup has the potential to work effectively for selectively recovering silver while minimizing lead deposition and avoiding the formation of a protective lead sulfate layer. However, the success of the process depends on various factors, including the specific conditions, concentration of ions in the electrolyte, membrane characteristics, and the efficiency of the electrochemical reactions. Here are some considerations: Membrane Efficiency: The Nafion 117 membrane must effectively block the passage of lead ions while allowing silver ions and protons to pass through. Ensuring the membrane's integrity and optimal operation is crucial for the success of the process. Electrolyte Composition: The concentration of sulfuric acid and other components in the electrolyte solution can influence the efficiency of the electrochemical reactions and the behavior of ions at the electrodes. Optimal electrolyte composition should be determined through experimentation and optimization. Electrode Performance: The platinum and silver electrodes must exhibit good catalytic activity for the electrochemical reduction of water, silver ions, and proton reduction. Ensuring the electrodes' cleanliness and proper functioning is essential for achieving desired deposition rates and selectivity. Control of Lead Deposition: Controlling the concentration of lead ions at the lead cathode is crucial for preventing excessive lead deposition and the formation of a protective layer. This may require optimizing parameters such as current density, electrolyte flow rate, and electrode separation distance. Monitoring and Optimization: Continuous monitoring of the electrolysis process and optimization of operating parameters based on observed results are essential for maximizing silver recovery while minimizing lead deposition and sulfate formation. Adjustments may be needed to fine-tune the process for optimal performance. Overall, while the described electrolysis setup holds promise for selectively recovering silver from the ore sample, it may require experimentation and optimization to achieve optimal results. Collaborating with experts in electrochemistry and materials science can provide valuable insights and support in designing and implementing the process effectively. ~ CHEERS 😎
I fond that black sand is perfect for gold recovery gold pass the black sand but regular sand can’t sink so that way gold gets separated from the sand and magnet removes the black sand what’s left is all heavy, material gold platinum, and all another precious metals
Clay, acting as a bedrock, prevents gold from sinking deeper into the earth, creating a natural barrier. This unique characteristic of clay, along with its depositional nature, makes it a significant focus in the search for microscopic gold. Clay, composed of microscopic sedimentary particles, conglomerates together through various geological processes, often trapping precious metals like gold within its layers. The deposition of clay occurs in environments where fine particles settle from suspension, typically in calm water bodies like lakes and slow-moving rivers. These conditions allow for the accumulation of sediments, including clay, over time. When gold is present in these environments, it can become entrapped within the clay layers. Searching for gold in clay deposits involves understanding the sedimentary processes that led to their formation. By analyzing clay samples, geologists can identify areas with potential gold concentrations. Techniques such as panning, sluicing, and advanced methods like X-ray fluorescence (XRF) and inductively coupled plasma mass spectrometry (ICP-MS) are employed to detect and quantify microscopic gold particles within clay. Given the fine-grained nature of clay, gold particles trapped within it are often microscopic, making the extraction and identification process more challenging. However, the association between clay and gold deposits is well-documented, providing a valuable insight for prospectors and geologists alike. In essence, clay's depositional characteristics and its ability to act as a barrier make it a prime target for microscopic gold exploration. Understanding these geological processes is key to effectively searching for and recovering gold from clay-rich environments. Happy Hunting! 😎
I found a lot of that clay now I need to figure how to recover all that gold .i using black sand to recover that gold need make tool where I can combine, shaking table and black sand together to recover that gold
@myadventure7069 The reactor I'm constructing will address your issue. I'm currently awaiting some parts. Once they arrive, I'll build and test the reactor, and then create a PowerPoint presentation detailing the parts, assembly, and operation. I might also include a video within the presentation. The reactor will transfer cations through various membranes, starting with a Nafion 117. It involves acids, bases, and electrolysis. I noticed you already have some of the components, so it shouldn't be too challenging. Perhaps @orophilia can assist with titration to avoid wasting expensive chemicals.
I’m waiting to see that it’s very interesting. You can come to my place sometimes if you want to rest. And we can talk and we can go look in that gold. I think if we get together everybody, we will figure out how to get the gold from everywhere.
@@myadventure7069 I don't see any videos related to the system I engineered. The Nafion 117 membrane acts as a proton exchange mechanism, but it also allows small cations like Na+ to pass through. For instance, I can load sodium sulfate on one end, strip the Na+ to produce sulfuric acid, and create sodium hydroxide on the other side. Once I've finished with the sulfuric acid, I use the sodium hydroxide to convert it back to sodium sulfate. Another example is mixing three parts sodium chloride with one part sodium nitrate. By stripping the Na+, I can produce aqua regia and create sodium hydroxide. Other membranes are designed as cation exchange membranes, and some of these can pass larger cations. However, gold cations (such as Au+ or Au3+) are typically much larger and less common than smaller cations like Na+. The ability of a membrane to pass gold cations would depend on the specific properties of the membrane, such as its pore size and the selectivity of its ion exchange sites. For example, certain cation exchange membranes are used in the recovery of precious metals, including gold, from solutions in processes like hydrometallurgy. These membranes are specially designed to selectively allow the passage of larger metal cations while preventing other ions from passing through. You can change the polarity to facilitate the migration of protons (H+) towards the solution containing Au+ or Au3+, leading to the plating out of gold and the generation of HCl. This approach allows the HCl to be recycled for later use. This method assumes you have pretreated the ore with sulfuric acid to remove everything other than the gold and PGMs. Additionally, the nitric acid in aqua regia will decompose and escape as nitrogen dioxide (NO2) gas. This gas can be trapped and converted back to sodium nitrate (NaNO3), allowing for efficient recycling of reagents. The captured NO2 can be reacted with a solution of sodium hydroxide (NaOH) or sodium carbonate (Na2CO3) to form sodium nitrate (NaNO3). Theoretically, you can add a specific ratio of ore and a sodium compound, then initiate the reaction by applying an electric current in an appropriate reactor setup. This approach is commonly used in various electrochemical processes, including metallurgical applications such as ore processing and metal extraction. Hydrometallurgical applications is a better way of looking at this: Initiating a reaction by combining a specific ratio of ore and a sodium compound, then applying an electric current in an appropriate reactor setup, is a fundamental principle in many electrochemical processes, especially in metallurgy. This method is widely employed in various applications, such as ore processing and metal extraction. It allows for precise control over the reaction conditions and facilitates the efficient extraction of desired metals from ores. Fun Stuff!!
When nitrogen dioxide (NO2) reacts with water (H2O), it forms nitric acid (HNO3); that is the first reaction. Adding NaOH converts it to NaNO3, which is the second reaction. Or you can use Na2CO3.
It seems to me that in your video you added hydrochloric acid then when to testing for gold with stannous chloride. You left out adding nitric? Keep up making these great videos. You teaching skills are top notch.
I didn't see you add nitric today but you added urea so you must have. So, what metal is the best metal to precipitate the Au? If you look at the Reactivity Series of Metals on wikipedia, you see that by adding Zinc you are dropping everything less reactive than the Zinc. i.e. Cr, Fe, Ni, Sn, Sb, Bi, Cu, Hg and Au drops. If there was silver or lead they would have dissolved in the nitric but also because of the HCl they precipitated and are lost to the filtrate. Usually you use Tin (Stannous) so in that case you drop Sb, Bi, Cu, Hg and Au. Still messy. But but adding copper instead, only the Hg and Au (and other PGMs) will drop, so that looks like the better option. And now you have copper in solution. Adding Tin now drops the copper to be used next time, as you have demonstrated previously.
That water is with dissolved potassium nitrate I don’t filmed how I add it .why you ewribody so About another metals when you smelt the gold all those metals disappear . My goal is to get the gold first then I do refining.
@@myadventure7069 I am still learning, like you, but I had a battle with e-waste & computer scrap where there are so many base metals, although they are still valuable, but in separating from the gold, silver and other PGMs I made a mess before I learned about the Reactivity Series of metals.
@waynoswaynos yes always wee getting the problems in the beginning . But newer trow away nothing . Dissolve ewerithing in aqua regia and use zinc or aluminum to recover metals . When you get black powder put ewerithing in hydrochloric aside and boil for few minutes . Then what’s left is your PM. Use again aqua regia dissolve that black powder .when ewerithing is done use urea to kill nitric and use stanus chloride or another chemicals to recover gold . Of ode gold be not so clean but you recover the lost gold after you can do refining
I never change nothing always use potassium nitrate, and hydrochloric acid and if you don’t see something, it’s not there but gold get disolved , problem I always do many different things in one time and so rains forget to film it
@@myadventure7069 thanks for the reply mate, i always watch your videos and have learned a lot, i personally use sodium nitrate with hydrochloric acid to dissolve gold
Thank you, my friend, for this very beautiful video. I have a question: how do I recover the zinc that I used after gold was deposited so that I can use it again?
Use aluminum , zinc and aluminum is to reactive and if you want to recover them, you need to add magnesium but keep in mind when zinc, precipitates solution get acid and dissolves zinc again so I in this case you need to kill hydrochloric acid I know tried that but one metal is magnesium, which one recovers zinc, but that is expensive use aluminum for everything you will be fine
@@myadventure7069 Thank you... I hope that if you have time, you will make a video explaining this... how to recover metals after deposition... because it will be a beautiful addition to your channel, which is very interesting and useful.
When you use zinc are you also dropping out of solution other metals (PGM)? With stannous you drop gold then when you drop stannous with zinc you get t metal. Desolving tin with HCL you get tin in solution and black power. The black power (PGM). Great method to separate gold from PGMs. Can you experiment with Black PGM powder?
Man, first I recovering the gold ! Don’t cere to much abouth the purity . Then I smelting all zinck tin and another useless metals burns out . Then if I want I can do refining that gold . Remember nobody gets pure gold in first recovery from the rocks , just recover the gold first then do refining
Hi brother, Thanks for the information and the video. I would suggest that you use HCl to clean your precipitate if you use Zinc to make the drop (first decant the liquid to avoid the nitric) , that way you remove the iron that came down with the gold
Greetings to the popular and popular man. The soil you worked. There is kaolin, which has a metallic luster. I have two mines, one of which has gold-bearing kaolin. And we have to wash this type of soil before acid processing, because kaolin aluminum oxide is similar to your soil, it is about 14%. And it has caused trouble in the extraction of aluminum oxide gold. My other question was that you did not add potassium nitrate in the solution!!? Or I did not notice the addition of potassium nitrate?
Hello. I am devoted to you. And if we were close, I would send you soil with high gold grade by truck. In my mine, there is molybdenum in veins of 20-30 cm. My friend, you must consider the presence of aluminum oxide in kaolin as a disturbing factor and remove it with hydrochloric acid. I wish you success. amelie
Need think something to recover that gold in combination with black sand and shaking table with black sand, I can recover the and smallest particles of gold. I tried today on dust, and I got the gold back so black sand, and some kind of shaking we can recover all the gold whatever is in the sand.
@@myadventure7069 in a week I’ll be back in LA. I’m going to build a machine for concentration of gold from sand. I think it will work very well. We’ll collect some buckets of sand and see what we find
Very nice 👍👍👍👍👍 please make video more
Your channel is the gift that keeps on giving.. From a fellow gold miner in west sahara... Here the gold is also so small you need to be the size of a bacteria to se it
very educational video, i hope one day i can visit u in the US to learn
more from u ,thanks a lot u are excellent teacher.
Nice professor.
Thank you.
I like long videos.
Keep them coming!
I call you Master, I have been watching your videos but this one is very clear to me. I wish I get gold with this zinc method thanks.
I am interested in your next video. Precipitating with multiple metals should be very educational.
Was not too long. You’re doing the stuff I want to do. Learning and enjoying.
May iPhone memory almost finished🤣🤪😝🤪that’s stop me from making long videos
Please make a video of you smelting it 😊
It's cool to see you watching Roman as I am subbed to you both lol only I am a whole lot closer to him than I am Australia
Looks like a good extraction. I knew the clay would have visible gold. I have been trying to use what I learned from you with slowly elevating results. Hopefully with more experience and experimenting I will have the right eyes to be able to confidentiality read vains and rocks
One goal is to selectively recover silver while avoiding the formation of a protective lead sulfate layer and minimizing lead deposition on the lead cathode. Here's how the process would work:
Electrolysis Setup:
One side of the electrolysis cell contains the ore sample, sulfuric acid electrolyte, platinum anode, and lead cathode, separated by the Nafion 117 membrane.
On the other side of the membrane, a separate compartment contains ionized water and a silver cathode.
Electrochemical Reactions:
At the platinum anode, water is oxidized to produce protons (H⁺) and oxygen gas (O₂):
In the presence of sulfuric acid, lead ions (Pb²⁺) from the ore sample can undergo reduction at the lead cathode:
Simultaneously, the silver ions (Ag⁺) from the ore can pass through the Nafion 117 membrane and migrate towards the silver cathode compartment.
Selective Permeability of Nafion 117:
The Nafion 117 membrane selectively allows the passage of protons (H⁺) and smaller ions such as silver ions (Ag⁺) while blocking larger ions such as lead ions (Pb²⁺). This ensures that lead ions do not pass through the membrane and remain on the same side as the lead cathode.
Silver Deposition:
Silver ions that pass through the membrane reach the silver cathode compartment, where they are reduced to elemental silver (Ag) by gaining electrons:
Avoidance of Lead Deposition:
By controlling the electrolysis conditions and minimizing the concentration of lead ions at the lead cathode, the formation of a protective lead sulfate layer can be mitigated. Additionally, the selective permeability of the membrane helps prevent lead ions from reaching the silver cathode compartment.
Conclusion:
In this electrolysis setup with the Nafion 117 membrane, the goal is to selectively recover silver while minimizing lead deposition and avoiding the formation of a protective lead sulfate layer. By leveraging the membrane's selective permeability and controlling the electrolysis conditions, it is possible to facilitate the deposition of silver onto the silver cathode while keeping lead separate. This approach helps overcome the challenges associated with lead sulfate formation and enhances the efficiency of silver recovery from the ore sample.
The described electrolysis setup has the potential to work effectively for selectively recovering silver while minimizing lead deposition and avoiding the formation of a protective lead sulfate layer. However, the success of the process depends on various factors, including the specific conditions, concentration of ions in the electrolyte, membrane characteristics, and the efficiency of the electrochemical reactions.
Here are some considerations:
Membrane Efficiency: The Nafion 117 membrane must effectively block the passage of lead ions while allowing silver ions and protons to pass through. Ensuring the membrane's integrity and optimal operation is crucial for the success of the process.
Electrolyte Composition: The concentration of sulfuric acid and other components in the electrolyte solution can influence the efficiency of the electrochemical reactions and the behavior of ions at the electrodes. Optimal electrolyte composition should be determined through experimentation and optimization.
Electrode Performance: The platinum and silver electrodes must exhibit good catalytic activity for the electrochemical reduction of water, silver ions, and proton reduction. Ensuring the electrodes' cleanliness and proper functioning is essential for achieving desired deposition rates and selectivity.
Control of Lead Deposition: Controlling the concentration of lead ions at the lead cathode is crucial for preventing excessive lead deposition and the formation of a protective layer. This may require optimizing parameters such as current density, electrolyte flow rate, and electrode separation distance.
Monitoring and Optimization: Continuous monitoring of the electrolysis process and optimization of operating parameters based on observed results are essential for maximizing silver recovery while minimizing lead deposition and sulfate formation. Adjustments may be needed to fine-tune the process for optimal performance.
Overall, while the described electrolysis setup holds promise for selectively recovering silver from the ore sample, it may require experimentation and optimization to achieve optimal results. Collaborating with experts in electrochemistry and materials science can provide valuable insights and support in designing and implementing the process effectively.
~ CHEERS 😎
Like your idea for the tool and black sand trap. Also add when panning.
I fond that black sand is perfect for gold recovery gold pass the black sand but regular sand can’t sink so that way gold gets separated from the sand and magnet removes the black sand what’s left is all heavy, material gold platinum, and all another precious metals
@@myadventure7069 #46.79 not magnetic.but#45.45.46.76.
77 and 78 are magnetic.
@somsackvongsa7077 I don’t understand what you say
Clay, acting as a bedrock, prevents gold from sinking deeper into the earth, creating a natural barrier. This unique characteristic of clay, along with its depositional nature, makes it a significant focus in the search for microscopic gold. Clay, composed of microscopic sedimentary particles, conglomerates together through various geological processes, often trapping precious metals like gold within its layers. The deposition of clay occurs in environments where fine particles settle from suspension, typically in calm water bodies like lakes and slow-moving rivers. These conditions allow for the accumulation of sediments, including clay, over time. When gold is present in these environments, it can become entrapped within the clay layers.
Searching for gold in clay deposits involves understanding the sedimentary processes that led to their formation. By analyzing clay samples, geologists can identify areas with potential gold concentrations. Techniques such as panning, sluicing, and advanced methods like X-ray fluorescence (XRF) and inductively coupled plasma mass spectrometry (ICP-MS) are employed to detect and quantify microscopic gold particles within clay. Given the fine-grained nature of clay, gold particles trapped within it are often microscopic, making the extraction and identification process more challenging. However, the association between clay and gold deposits is well-documented, providing a valuable insight for prospectors and geologists alike.
In essence, clay's depositional characteristics and its ability to act as a barrier make it a prime target for microscopic gold exploration. Understanding these geological processes is key to effectively searching for and recovering gold from clay-rich environments.
Happy Hunting!
😎
I found a lot of that clay now I need to figure how to recover all that gold .i using black sand to recover that gold need make tool where I can combine, shaking table and black sand together to recover that gold
@myadventure7069 The reactor I'm constructing will address your issue. I'm currently awaiting some parts. Once they arrive, I'll build and test the reactor, and then create a PowerPoint presentation detailing the parts, assembly, and operation. I might also include a video within the presentation.
The reactor will transfer cations through various membranes, starting with a Nafion 117. It involves acids, bases, and electrolysis. I noticed you already have some of the components, so it shouldn't be too challenging. Perhaps @orophilia can assist with titration to avoid wasting expensive chemicals.
I’m waiting to see that it’s very interesting. You can come to my place sometimes if you want to rest. And we can talk and we can go look in that gold. I think if we get together everybody, we will figure out how to get the gold from everywhere.
@@myadventure7069
I don't see any videos related to the system I engineered. The Nafion 117 membrane acts as a proton exchange mechanism, but it also allows small cations like Na+ to pass through. For instance, I can load sodium sulfate on one end, strip the Na+ to produce sulfuric acid, and create sodium hydroxide on the other side. Once I've finished with the sulfuric acid, I use the sodium hydroxide to convert it back to sodium sulfate.
Another example is mixing three parts sodium chloride with one part sodium nitrate. By stripping the Na+, I can produce aqua regia and create sodium hydroxide. Other membranes are designed as cation exchange membranes, and some of these can pass larger cations. However, gold cations (such as Au+ or Au3+) are typically much larger and less common than smaller cations like Na+. The ability of a membrane to pass gold cations would depend on the specific properties of the membrane, such as its pore size and the selectivity of its ion exchange sites.
For example, certain cation exchange membranes are used in the recovery of precious metals, including gold, from solutions in processes like hydrometallurgy. These membranes are specially designed to selectively allow the passage of larger metal cations while preventing other ions from passing through.
You can change the polarity to facilitate the migration of protons (H+) towards the solution containing Au+ or Au3+, leading to the plating out of gold and the generation of HCl. This approach allows the HCl to be recycled for later use. This method assumes you have pretreated the ore with sulfuric acid to remove everything other than the gold and PGMs.
Additionally, the nitric acid in aqua regia will decompose and escape as nitrogen dioxide (NO2) gas. This gas can be trapped and converted back to sodium nitrate (NaNO3), allowing for efficient recycling of reagents. The captured NO2 can be reacted with a solution of sodium hydroxide (NaOH) or sodium carbonate (Na2CO3) to form sodium nitrate (NaNO3).
Theoretically, you can add a specific ratio of ore and a sodium compound, then initiate the reaction by applying an electric current in an appropriate reactor setup. This approach is commonly used in various electrochemical processes, including metallurgical applications such as ore processing and metal extraction.
Hydrometallurgical applications is a better way of looking at this:
Initiating a reaction by combining a specific ratio of ore and a sodium compound, then applying an electric current in an appropriate reactor setup, is a fundamental principle in many electrochemical processes, especially in metallurgy. This method is widely employed in various applications, such as ore processing and metal extraction. It allows for precise control over the reaction conditions and facilitates the efficient extraction of desired metals from ores.
Fun Stuff!!
When nitrogen dioxide (NO2) reacts with water (H2O), it forms nitric acid (HNO3); that is the first reaction. Adding NaOH converts it to NaNO3, which is the second reaction. Or you can use Na2CO3.
Hello, what did you add to the solution to precipitate the gold?
Super Master ku 👍❤❤❤
Congratulations sir 🎉. Useful Tips. 🎉
It seems to me that in your video you added hydrochloric acid then when to testing for gold with stannous chloride. You left out adding nitric? Keep up making these great videos. You teaching skills are top notch.
I don’t use nitric acid ! I use potassium nitrate + hydrochloric aside
I didn't see you add nitric today but you added urea so you must have. So, what metal is the best metal to precipitate the Au? If you look at the Reactivity Series of Metals on wikipedia, you see that by adding Zinc you are dropping everything less reactive than the Zinc. i.e. Cr, Fe, Ni, Sn, Sb, Bi, Cu, Hg and Au drops. If there was silver or lead they would have dissolved in the nitric but also because of the HCl they precipitated and are lost to the filtrate. Usually you use Tin (Stannous) so in that case you drop Sb, Bi, Cu, Hg and Au. Still messy. But but adding copper instead, only the Hg and Au (and other PGMs) will drop, so that looks like the better option. And now you have copper in solution. Adding Tin now drops the copper to be used next time, as you have demonstrated previously.
That water is with dissolved potassium nitrate I don’t filmed how I add it .why you ewribody so About another metals when you smelt the gold all those metals disappear . My goal is to get the gold first then I do refining.
@@myadventure7069 I am still learning, like you, but I had a battle with e-waste & computer scrap where there are so many base metals, although they are still valuable, but in separating from the gold, silver and other PGMs I made a mess before I learned about the Reactivity Series of metals.
@waynoswaynos yes always wee getting the problems in the beginning . But newer trow away nothing . Dissolve ewerithing in aqua regia and use zinc or aluminum to recover metals . When you get black powder put ewerithing in hydrochloric aside and boil for few minutes . Then what’s left is your PM. Use again aqua regia dissolve that black powder .when ewerithing is done use urea to kill nitric and use stanus chloride or another chemicals to recover gold . Of ode gold be not so clean but you recover the lost gold after you can do refining
@@myadventure7069 Thank you my friend, useful advice for every one.
هل يوجد الذهب في الاحجار الكلسية التي يصنع منها الإسمنت
Hi dear friend
Do you take a video for dissolving Gold ore using bleach leaching and precipitate ?
What did you use with the hydrochloric acid? i didnt see any nitrate this time
Potassium nitrate I add in water and forget to show it
I never change nothing always use potassium nitrate, and hydrochloric acid and if you don’t see something, it’s not there but gold get disolved , problem I always do many different things in one time and so rains forget to film it
@@myadventure7069 thanks for the reply mate, i always watch your videos and have learned a lot, i personally use sodium nitrate with hydrochloric acid to dissolve gold
@geoffdennis3518 any nitrate works !
Thank you, my friend, for this very beautiful video. I have a question: how do I recover the zinc that I used after gold was deposited so that I can use it again?
Use aluminum , zinc and aluminum is to reactive and if you want to recover them, you need to add magnesium but keep in mind when zinc, precipitates solution get acid and dissolves zinc again so I in this case you need to kill hydrochloric acid I know tried that but one metal is magnesium, which one recovers zinc, but that is expensive use aluminum for everything you will be fine
@@myadventure7069 Thank you... I hope that if you have time, you will make a video explaining this... how to recover metals after deposition... because it will be a beautiful addition to your channel, which is very interesting and useful.
@Musallem77l just smelt it . I show many times with microwave right now. I’m trying to save little bit more than smelt in one time everything .
@@myadventure7069 ..thanks
Gold..!👍👍👍💪💪💪😁😁😁
When you use zinc are you also dropping out of solution other metals (PGM)? With stannous you drop gold then when you drop stannous with zinc you get t metal. Desolving tin with HCL you get tin in solution and black power. The black power (PGM). Great method to separate gold from PGMs. Can you experiment with Black PGM powder?
Man, first I recovering the gold ! Don’t cere to much abouth the purity . Then I smelting all zinck tin and another useless metals burns out . Then if I want I can do refining that gold . Remember nobody gets pure gold in first recovery from the rocks , just recover the gold first then do refining
😊😊😜
Black powder Pt, Pd, Rh?
Gold ,maybe some pt,pd,rh. Anyway I need do refining .
Pt.pd. rh are magnetic
No they not magnetic
Couple of RUclips videos for separating and recovering PGM. Interested?
👍
your videos are so facinating
👍🏻It's not a problem for the clips to be long
Hi brother,
Thanks for the information and the video.
I would suggest that you use HCl to clean your precipitate if you use Zinc to make the drop (first decant the liquid to avoid the nitric) , that way you remove the iron that came down with the gold
When you smelting the gold zinc ,tin burns out . So gold almost cleen then you do refining anyway to get 99,9 gold 🤑
Nees❤❤❤❤❤❤
nees❤❤❤❤
Greetings to the popular and popular man. The soil you worked. There is kaolin, which has a metallic luster. I have two mines, one of which has gold-bearing kaolin. And we have to wash this type of soil before acid processing, because kaolin aluminum oxide is similar to your soil, it is about 14%. And it has caused trouble in the extraction of aluminum oxide gold. My other question was that you did not add potassium nitrate in the solution!!? Or I did not notice the addition of potassium nitrate?
You see me adding water ? There was dissolved potassium nitrate I just forget to film that. I always dissolving potassium nitrate in water
Hello. I am devoted to you. And if we were close, I would send you soil with high gold grade by truck. In my mine, there is molybdenum in veins of 20-30 cm. My friend, you must consider the presence of aluminum oxide in kaolin as a disturbing factor and remove it with hydrochloric acid. I wish you success. amelie
you are the richest person because you have gold n gold everywhere around you, excellent work
@@mohammadusmani5351 Hi. I hope you have good gold reserves. Which country are you in?
I am in Pakistan, yes here is big mines of precious minerals
teach us to make smoked salmon
Wow….Nice! lol.
Great idea to try 4 different metals to drop the gold.
There is gold everywhere up there! We will try to concentrate it and see what the best method is.
Need think something to recover that gold in combination with black sand and shaking table with black sand, I can recover the and smallest particles of gold. I tried today on dust, and I got the gold back so black sand, and some kind of shaking we can recover all the gold whatever is in the sand.
@@myadventure7069 in a week I’ll be back in LA. I’m going to build a machine for concentration of gold from sand. I think it will work very well. We’ll collect some buckets of sand and see what we find
Man there is a tons and tons that sand .
@@myadventure7069 Sand is easy, no further processing needed, just concentration and dissolving.