Note that the overwhelming majority of polyethylene produced in industry, while energetically favorable and exothermic in chemical formation, still requires an inorganic or organometallic catalyst to initiate at lower temperatures and pressures. Typically these are Ziegler-Natta catalysts based on aluminum *titanium chloride* , the Phillips catalyst of a *chromium oxide* silica gel complex, or *antimony oxide* . Invariably, due to the viscous nature of molten PE during production, much catalyst remains in the final product, and will thus leach the metal catalyst into whatever liquid the resulting plastic vessel contains. This is almost certainly what the dithizone is detecting in your plastic water container. Incidentally, the catalyst for PVC, which the spigot may be made of, is mercury chloride, and a common stabilizer used in PVC is *LEAD oxide* .
Oh fuc.. I hate plastics in fresh water pipes and some part's got touch with my drinking water. Some lead isn't even worse thing in different plastic types.
@Muonium1 When PVC is marked as "food safe" is that meant to indicate that a different catalyst has been used? A quick Google finds there was a kerfuffle over the construction of Vermont sugar houses in 2021 due to a leeching issue from non-food-grade PVC pipe. Not many people drink from lead crystal glassware anymore, but plastic is everywhere [citation needed]. I'm a computer engineer with no materials knowledge, but I assume that the migration of lead to the barrier layer could be faster in materials other than glass, meaning the rinsing process Ben described may not be adequate protection.
Thanks for this, I have been wondering why I detect chromium from my RO produced water and i could not figure it out. It is from all the PE filter housing and hoses. Leaching the chromium catalyst in to the water. It is very slight amount barely detected on water measuring strips. And it is the only contaminant I can find in the water. It is still WAY purer than the tap water though.
Ah finally we see the "I asked chatgpt and it was right" project. I saw you post about it on twitter a while ago and wondered if it would ever show up in a video. Very interesting concept and now I understand how the heavy metal tests I've used in the past work! Very cool
@@WeBeGood06 chatgpt regularly gets huge amounts of information wrong and bullshits about knowing things it doesn't know CONSTANTLY. It's completely untrustworthy and little more than a toy for amusement that can *occasionally* provide a useful insight about something. Ask it about detailed topics you are already an expert on, then ask it for citations in the literature to support its claims. It will simply fabricate everything from whole cloth. See the hilariously stupid Mata V. Avianca case from a month ago. The number of people treating it like a search engine is astounding. It's a text pattern generator; it hallucinates, it lies, it confabulates.
@@WeBeGood06It has categories it does great in, and others it fails in. It does best with thoroughly documentated topics that have objective and numerical truth, which makes the source data very consistent. It's efficacy drops a lot when you give it softer science
the dishwasher might make it safer because the rinse aid leaves behind a plastic coating- that is the haze that ruins glasses in the dishwasher after a time
@@LanceBeckman your comment makes no sense: dishwashers have only gotten increasinly energy efficient and better at cleaning difficult to clean stuff. It's like saying "Glasses? People still use glasses? What is this, the 1400s?"
Applied Science is easily in the top 3 technical channels on youtube. He goes to such lengths and documents everything so well. He understands the topics so well he can explain them to about anyone. Chemistry, engineering, electronics… every video is a masterpiece lol
As a grey-haired Chemist, I especially enjoyed seeing him use + explain the UV/VIS spectrometer that fits in the palm of your hand (the LR1). Amazingly powerful UV/VIS capability for only a fraction of the cost $$$ compared to “professional” lab equipment used at US EPA and FDA laboratories like Perkin-Elmer and Agilent. Now I know what I want for my birthday present, an LR1 👍
@@Dinnye01while i've been subscribed to all of your listed channels and while tech ingredients does occasionally get sort of close, in my opinion this channel is just miles ahead of every other one. In terms of the host's expertise level, video subjects and the sheer amount of unique stuff they have published.
You might want to check tartaric acid/tartrate as an extraction solution. Tartaric acid is famous for being found in high doses in wine while also forming extremely stable, soluble complexes with lead, being able to dissolve even lead sulfate. So real wine could extract way more lead than just dilute acetic acid...
That's a great point, there should be no acetic acid in wine unless it has turned. The root Latin words in "vinegar" are Vin = Wine and Eger = sour . Tartaric, malic, citric, and succinic are the primary acids found in wine, this is also why total acidity is more valuable than pH for testing wines acidity. Also as mentioned at the end of the video many other solvents may be drunk from these glasses which may pull out more or less lead.
Or phosphoric acid, being that kids and other non-alcoholics are going to be drinking soda out of these leaded goblets at the china-and-crystal fancy occasions.
I'm curious, I would think that the solvent would not matter much. My rationale is the lead extraction is inhibited by the diffusion through the glass, not the thermodynamics of dissolving.
@@Kycilak My bet is it depends on if the glass has been pre-extracted or not. If it has, likely no difference. If it hasn't then that first drink is going to have way more lead.
My family is from Hungary and my grandfather was a glass man. When they immigrated to Cleveland he continued to cut crystal. If you live in a house in Cleveland that has a chandelier it is possible that he either cut all the crystal or cut a replacement piece. He was a true artist.
Regarding the plastic carboy: many plastics have organo-metallic additives or surface contaminates which are manufacturing additives. For example, mould release agents, and many other modifier agents. Often these are left on the surface of the plastic product in relatively large amounts, or can leach out slowly over time. We had a huge problem with tin (Sn) additives leaching out of plastics in one project I worked on.
Although NileRed videos are fun, but this is how I’d like a research presentation. To go through all the aspects, mistakes and triumphs, math science and engineering, tip’s tricks and techniques, and so on. Thanks again Ben, and awesome video as always 👍
I've found myself liking Nile Red's videos less and less over recent years. IMO he's clearly appealing to a more casual viewer, and the content feels a little "dumbed down" compared to his older stuff
In the hospital lab they used a multi-stage deionizer and then all the water was distributed via tin pipes. I asked why not glass and was told the deionized water would leach all sorts of impurities out of the glass.
Why not pure Sapphire? I have a Graphics tablet where the entire surface is a huge sapphire panel. It's probably the only scratch resistant thing I have.
@@AmstradExin Most likely a shaping constraint, as all synthetic sapphire applications I am aware of can be made and cut from flat sheets (screens, camera lenses etc)
@@timkurz6086 Borosilicate glass is less likely to leach impurities, but plastic containers or even soda-lime glass are specifically preferrable for boron analysis because it does not leach boron.
@@fatiheneskuru4332 seems logical to me 😂 however i have to admit ive never done boron analysis to this day nor have i heard someone doing that to encounter such a problem!
26:30 : If you made standards for copper, nickel, and other metals, I think you could use a multivariate least squares approach to find the concentration of all trace metals in your sample simultaneously, which would both tell you if there's other stuff in there and give you more accurate estimates of lead that wouldn't be confounded by other metals.
This assumes that the result is a linear mixture of the standards, which may not be the case. Maybe the literature has something to say, but in the absence of that, you'd have to make some samples which were known mixtures of metals to validate the method.
@@bob2859 The data at 22:14 shows that the absorbance for lead is quite linear until you reach saturation. It should definitely be linear in the limit of low concentration.
The idea with the dithizone is to always have an excess of unreacted dithizone, so that the reactions are never starved for it and all of the metal reacts. When all of the metal reacts, the absorbance of the reacted dithizone is directly proportional to the concentration of the metal. So long as each different metal has a different absorbance spectrum when reacted with dithizone, yes, it's possible to measure the concentrations independently in the combined solution. Absorbance spectra add linearly at each wavelength and the contributing spectral curve shapes are known, so you only need a linear transformation to separate them and get the concentration of each metal.
as a analystical chemist i'm so happy u actually addressed the PPM PPB notation. i hate it especially when they use ppm as mg/l. its so inaccurate because of denisty and all
It seems fine for comparisons, like 300ppb lead vs 200 ppb lead, but it’s definitely not good for specifications, because it’s vague. By volume? By mass? Certain units? This doesn’t matter as much when there’s another reference point, but is extremely important for other purposes
As someone who does water lead testing as part of my job - this is really great! The dithizone is a great choice for UA-cam because it gives a color as a function of metal content! With your electronics chops, I'd have thought maybe you'd have designed and built a electrochemical potentiostat to perform anodic stripping voltammetry - which is also usually sensitive down to the 10 is microgram/L range. In that method dissolved lead(II) is reduced to lead metal at an electrode and then "stripped" from the electrode by applying an oxidizing potential to the electrode. Usually a mercury-lead amalgam is used to create the deposit, but bismuth also works and is non-toxic. Other metals such as copper and zinc strip off at different potentials and therefore the method can be used with other metals present and also to quantify those metals. The only downside is that you have to use the method of standard additions to each sample to make your determinations - so it is tedious (perhaps more tedious than the liquid-liquid extraction).
From what I understand, the real danger of lead glass is it's use as a decanter for alcohol, especially if you leave liquor sitting in it for years. From Wikipedia: In a study performed at North Carolina State University, the amount of lead migration was measured for port wine stored in lead crystal decanters.[20] After two days, lead levels were 89 µg/L (micrograms per liter). After four months, lead levels were between 2,000 and 5,000 µg/L. White wine doubled its lead content within an hour of storage and tripled it within four hours. Some brandy stored in lead crystal for over five years had lead levels around 20,000 µg/L.[21]
Excellent video! It would be interesting to run the glass through dishwasher let's say 50times, leave it for a month and then repeat the experiments - to see A) if the dishwasher leached all the mobile lead out of the surface or B) made it worse by making the glass bit more porous(etched by the alkaline dishwasher powder) so there is more surface for the lead to come out in the next drink
Another great video. You don't let yourself get sidetracked, calmly choose a topic that appeals to you, and then kneel down fully into it. Above all, I like the versatility of the topics; well, it's all applied science.
Lead crystal fluoresces a ghostly blue under UVB. An LED UV flashlight is great for uranium glass but won't cause lead crystal to glow. Love your videos!
Have you tested this yourself? what wavelengths? I regularly see the ice blue glow of certain pieces of glass with a UVA flashlight at 365nm but I don't know for sure if it's lead, or cerium, or something else.
ben, you are a true hero in my eyes and you push me to be the man i aspire to be. the fact that your projects have such depth and involve so much scientific rigor, methodology and forethought, while at the same time being done in your garage with homemade setups, really makes me wonder about the boundaries of DIY. i do not know how you find the time, money and motivation to do these very advanced projects, but it makes me hopeful that i will get to a point in life that i can do the same. please keep being curious and making these awesome videos, because, while this community is not as big as i would like it to be, i am sure you motivate many people like me. i wish you the best of luck!
I just discovered your channel, and this one video convinced me that you are a real gift to humanity. It inspired me to know that there are people like you in the world. Thank you for your generosity in doing this experiment, and sharing it for free with the rest of the world!
I am a retired analytical chemist. Well done! The ultimate in metals work is an inductively coupled plasma mass spectrometer (ICP/MS). Detection limits drop from your levels by a factor of 1000 or more. Typically low limit metals work is done in a metal-free, clean room. There is no exposed metal. All labware is polyprop or PTFE (aka Teflon). Reagents are certified for metals work, or prepared in-house. One comment about your pipettes. Air displacement pipettes like you use are prone to error. Positive displacement pipettes are much better. Also, I bet if you put some high pH extractant in your lead crystal, the lead levels would go back up. Almost forgot. I knew the answer to the cloudy lead solution problem as soon as I saw it. Dissolved CO2 is a real problem in a lot of wet chemical methods.
"I bet if you put some high pH extractant in your lead crystal, the lead levels would go back up." What do you think would happen to make the lead levels go back up?
An interesting question is how usage patterns affect things. If it's your "special crystal" that you pull it a few times per year, you have maximum recharge from migration, but minimum exposure events. If, instead, you use it every day, then you'll be extracting frequently but getting less exposure each time. If the migration is slow enough, then both might be similar in total exposure because the rate of migration matters the most. Alternatively, if the migration is somewhat faster, then the layer of glass which is extracted from might "fill up" for the occasional user so the everyday user gets more exposure, but maybe not excessively more. Finally, if the migration rate is pretty fast, then every extraction leads to roughly the same exposure level so the daily use might be getting a hundred times the exposure of the occasional user. Ben's results suggest that, for his extraction method at least, his glassware isn't in the fast recharge regime. It suggests that it could be in the slow (migration limited) or medium (daily is worse than occasional, but maybe not immensely worse) regime.
The issue is that he used an acidic extraction liquid. The problem is that moast soaps especially for dishwashers are basic. Basic solutios tend to attac glass much more. So every time you put this stuff in the dishwasher you remove a small amount of glass wich could free more lead. So using citric acid is not very realistic I think. Still like always it is a super cool video.
@@electricalychalanged4911 You wouldn't want to put lead crystal into the dishwasher anyway. Even a small amount of surface clouding will ruin the visual effect it is used for...
@@electricalychalanged4911 I thought that he said "acetic", like vinegar. Would you or somebody confirm whether or not vinegar would work, and whether or not it would damage the glass?
@@eugenetswong Vinegar is a week acid pH 4,7. Glass or SiO2 does not react at this pH. But many if not most metal oxides do, forming mostly soluble salts. That goes for lead oxides too. in the concrete case the accessible lead oxide on the surface of the Glass would be dissolved by Vinegar (and most beverages es they tend to be acidic) over time. But after putting anything basic in there pH 8 or higher (like many soaps or cleaning agents, but also some herbal tees and vegetable juices) a very thin layer of glass can be removed which would expose more lead oxide. My argument is that removing the Lead by long exposition to week acids will not make the lead glass safe to use for food in most use cases I think. So can it work? Yes, if no basic stuff touches the glass afterward . Will it damamge the glass? Defiantely not.
There used to be significant amounts of lead additive in some types of PVC plastic, used to improve UV resistance and extrusion characteristics. I think it's mostly been eliminated, at least in the developed world. One problem with it was that if the product (such as vinyl window blinds) were exposed to sunlight the plastic would deteriorate in a thin layer which would turn to (lead-bearing) dust which could be ingested or inhaled, and the process continued with the freshly exposed plastic.
Last cordless drill I bought new came with a charger. The charger cord does have a lead warning. It is still being shipped in (ryobi). The vinyl insulated lunch totes are notorious and used mostly by children. Don't know if those are still around but I would think so. Appently the amount of lead used shot-up in the past 10 years due to re-regulation.
Yeah, people talk about plastic (etc) as if it’s the plastic itself that’s the only problem, but often it’s the additives and there’s little control over what is being used as additives. Or maybe it’s something made of steel, that should be safe, but what if it’s steel with a significant amount of lead in it, and so on.
I'm speculating but I would love to know if polymerisation catalyst could have been the problem. I'm sure that there is some catalyst in final product, but I have no idea if it is in high enough amount and if it would even leach in solution.
@@napalmholocaust9093That was a California warning label because the solder might have contained lead. Long standing joke is "Everything in California causes cancer, especially California." Generally anything imported through California gets one of those tags slapped on them due to California law.
I used to work in R&D at a breathalyzer company. If you want to talk about confusing units, look at that industry. "%bac" can be defined in a lot of ways, just like your example of ppm. Also, we used the same method of diluting a stock solution when we were studying the linearity and sensitivity of our devices. As always, great video, Ben!
Interesting. Would love to have a discussion with you about calibration! I've recently ordered some alcohol sensors (the ubiquitous MQ-3) and I'm curious how to come up with some sort of actual measurement. How do the machines take into account people with different heights and weights? Or is that not considered at all, and it just looks at exactly how much alcohol is in the breath sample. It seems odd to me because different BAC levels show completely different levels of impairment and intoxication in different people -- but at the same time, how can you design a law for e.g. DUI without having some sort of non-subjective standard? It seems like a complex thing to do well.
@@AureliusR Impairment isn't taken into account by many (all?) legal systems, I would say because it's too difficult to measure. Instead alcohol breath or blood concentration limits are set. In New Zealand they are 250 micrograms of alcohol per litre of breath, or more than 50 milligrams of alcohol per 100 millilitres of blood which give a clear pass/fail result. Regarding calibrating an MQ3 presumably you'd want to generate a range of standard alcohol / air concentrations. More difficult than liquid solutions so have fun.
Vintage Orange Tupperware I have from my grandmother supposedly also contains lots of build-in metal supplements to start the day, so I just use them around the shop, not in the kitchen.
Very interesting video. I was just researching this week about lead content in brass which could be found in espresso machines and garden hose fittings.
@@napalmholocaust9093while I don't know exactly what alloy you're referring to, in my experience (as a machinist) the most common free machining brass is ASTM C360, which has an allowable lead content of 3-4%. There are also other "eco brass" alloys available that have near zero lead content, specifically for use in high volume production of plumbing parts and fittings that will come into contact with drinking water.
I agree. I try not to purposefully expose myself to excess lead knowing that I'm probably exposed to it anyway through daily activities. A good goal in life is to keep lead in your bones as low as possible. 😁
I don't understand every detail of the chemistry but your combination of the subject with electronics, programming, and science [observation of the facts compared to a hypothesis] plus general intuition has always been education. My personal growth and career have been advanced by you and a few similar channels. Thank you so much for your time and the contributions you've made to the community.
Serious scientists all have the following tools: XRF Gun, Mass spectrometer, Electron microscope, Oscilloscope, Series of acids, pure forms of as many elements as possible, solder gun, wires, protective eyewear, gloves, lab coats, UV light, IR thermal camera, Series of high speed cameras for various wavelengths, vacuum pumps, vacuum chambers, CNC machines, glass making equipment, windowed high pressure metal pipes that fit together, table top electric kilns in programmable and regular forms, several computers, ultrasonic microphones, various freezers, solutions and solvents (include liquid nitrogen in there) and centrifuges. Those all cost hundreds of thousands of dollars total. Most scientists aren't well off but are also interested in MRI machines, DNA decoders, super computers and just sort of not even think about owning but competing for time on orbitting telescopes. 😄 Point is to really know what's going on with most questions. You don't often wonder, "does this have too much lead in it?" but if you did someone with the tools could answer that, like on this channel. 😊 A fun one today that's asked a lot but rarely meaningfully answered is, "is this computer secure?" Good luck answering that without going over billions of lines of code and looking through hardware with electron microscopes. Some chips come with hardware vulnerabilities built in you can only see by decapsulating them. Software you must test with supercomputers for vulnerabilities not discovered yet. It takes a lab to answer such a simple question because there is a multi-billion dollar industry built to make them not secure. Great channel.
I loved hearing your data analysis process, especially the idea about doing a best fit with the extremal spectra! I have a background in mathematics and physics, but my mom is an abalytical chemist, and hearing theae methods of analysis is always really cool!
It would be interesting to do additional calibrations for common metal ions and then see if a multi-dimensional functional fit can get good accuracy for multiple metals at once.
If they're independent it should be pretty accurate right? But what about the unreacted values I this those are linearly dependant with every metal, or are they not? (Just learning linalg so this may be way off the mark lol)
@@xhivo97 I don't know, there were thoughts as to how these things might interact, but if we can find the ratios of bound values, then we can probably do a correlation to total unbound values. It would be work to calibrate, but if it isn't linear, we should be able to train a ML model.
I was thinking something similar, but different: instead of calibrating against ultrapure water, could the full spectrum functional fit method be used against tap water as a baseline, and just measure lead increases against that baseline?
@@aaronbotsis7218 The problem with tap water is that it tends to be inconsistent. So you would have calibrate the baseline each time you take water fron the tap.
I assume your lead glassware was all new, I would be interested in testing glassware that is decades old as most of us probably have, but inversely hasn't been used in decades. Does the lead always over large enough timescales migrate to even distribution, or is 30 year old glassware with hundreds of uses but none in the last 10 years indistinguishable from non-leaded glassware.
@@ch94086 Or maybe scratch it with a spoon to simulate stirring a drink. If glass with lead content is softer it might be easier to scratch some of it off.
Thank you do much for making the episode about lead crystal instead of about the machinery to check ppm. The moment is started I was thinking ‘hmm what IS lead crystal’ then you read our minds and focused on it
I'm really glad that I'm not the only one who hates PPM. I know technically it's well defined, but if you haven't read the spec, PPM can mean so many things. Is it PPM in molecule count? Is it PPM in volume? Is it PPM in weight? How would an average person know? Even then, measuring things in Liters vs KGs is dangerous, too, because we're comparing volume with mass, disregarding any density arguments. Personally I'm very partial to always comparing mass to mass. Volume measurements only complicate things therer
I don't see this as being a problem with PPM itself as it is with just being unclear about what you're measuring. PPM is a perfectly fine unit for expressing ratios of numerical quantitiies (that have the same unit, obviously mg/L is not ppm in the first place), but a substance is not a numerical quantity. Using PPM for a concentration without specifying whether it's by volume/mass/mol is like asking for "50 water" without specifying a unit :P
Where ppm and ppb gets me is in metrology. Just state the uncertainty in the units measured, it's needlessly confusing. 10 ppm means less than +/- 10 μg
Right when I was thinking that there may be a chance that the lead content in the glass layer, which was in contact with the water, can slowly recover over time due to diffusion within the material, you started to comprehensively answer exactly that question in your video. That's why I like your content so much. This video was super interesting, TYVM!
Really interesting results. I wonder how much lead was being consumed when they used to add it to sweeten wine back in the day especially compared to the fairly low amount in lead crystal. Also wonder if you dug up some dirt near an old(pre 1972ish) busy highway intersection how much lead is still in the ground from the use of leaded fuel.
I think you could also do a ratiometric approach: divide the absorbance value at one maximum by the other, and plot that against the concentration of lead. In theory as one peak increases the other decreases and the ratio changes, thereby making your measurements independent of things like uneven excitation intensities across samples (since you're looking at the relationship between intensities at 2 wavelengths). This is how some fluorescent biosensors are characterized
You could do that, but it's better to treat the concentrations of unreacted dithizone and dithizone reacted with lead as independent. That's because, as Ben mentioned, you don't know how much residual unreacted dithizone you'll have in the end. It depends on the starting concentration and on how much of it reacts. The concentration of reacted dithizone is what you ultimately care about, and you'd like to measure that without interference from the the concentration of unreacted dithizone. A ratio won't accomplish that. But it is enough to sample the absorbance spectrum at just two wavelengths. Since you know the shapes of the unreacted and reacted absorbance spectra and they add linearly at each wavelength to create the observed absorbance spectrum of the combined solution, it's just a linear transformation to separate them.
Just being a layperson who is entertained by this stuff, I really liked the fairly normalized explanation of the "why". You dove down the rabbit hole of one thing and ended up on this niche topic. I also like your testing that almost ended up on "obvious", but now you have numbers to back it up. The end bit where you whip out the xray gun from years ago... priceless. It showed that one piece was either used or altered in the manufacturing process.
This is just awesome. Knowing all this panic disorder which appears every time led is mentioned - "dont look at it, it can kill you!", I would say it is worth publishing. You have nice results! But all these battles with reviews, registrations, editors, no affiliation, I assume, probably is too much.
Exdellent presentation. It would be interesting to do the entire experiment using the chemicals and water as purchased to see how sensitive the test could be without the extra (significant) work in purifying the reagents.
@@Eduardo_Espinoza No. Lead has a high vapor pressure so it must not be used. Mercury was used in special purpose tubes but no longer. Solid state devices have almost entirely replaced vacuum tubes.
I've been analyzing metals in water by ICPOES and ICPMS for 13 years and I've always wondered how metals were quantified in the days before ICP was practical. This video is fascinating for me. I love all the chemistry videos you do.
I am usually really loving every video you make, but this time I was a bit hesitant to watch it. I finally gave in just to see what it was about, and it was chock full of very interesting things that I didn’t know about lead. In other words, another great and informative video and I should not be hesitant next time I am uncertain about any of the topics that you pick. A very interesting video indeed. Thank you.
The flagon that was labeled "Fine crystal" and contained loads of lead, yet didn't leech any into the water was fascinating. I'll bet there are standards somewhere that limit potential leeching from "food-safe" containers, and some factory somewhere has developed a process to make them safe.
@@Regular6782 I don't know, but I would guess after molding. I think the good stuff is still cut after molding. There is a lot of fine manipulation that can be done with glass. Glass art is really cool.
Fascinating as always! One of the few channels that I have notifications turned on for; always click without even reading the title because I know it will be interesting regardless of subject!
Hm, it might be interesting to see more technical repeats (3 or 4) and calculate standard deviation. Also, it might be interesting to see if you would see an increase in leeched lead after using a dishwasher (they do heat up to some high temperatures after all). Maybe testing some cold solutions could be done? Or breaking off some parts of cristals, then keeping them in high temp for a much longer period of time? But in general it was a very fun video, and it is quite informative. I had no clue that lead was used in cristals.
I totally agree with ditching the parts per x amount notation, but why no go even further and use molarity instead of g/L? I mean, if you measure 1 mg/L of Pb and 1 mg/L of Cu, there is actually more than 3 times more Cu atoms than Pb atoms in that solution.
Not related to this video, but just in case you haven't heard about the papers for LK-99 you should definitely try that next Ben. It hasn't been replicated yet, but its supposedly a room temperature, ambient pressure superconductor (Tk > 120C) and the synthesis according to the paper is totally something you can do with the tools you already have. You already did YBCO and this just requires firing at 925C in 1 micron vacuum, and the precursors are pretty basic and available. It would be really cool if you were one of the first to reproduce it and it was documented on video in such a great way.
this is amazing. its exactly the experiment i've wanted to run for a long time, especially with the software gathering wavelength vs amplitude data using a calibrated sensor. i see a lot of experiments that just eyeball or use a comparison card for measuring with dyes! we can do SO much better! this video is almost exactly how i would have done it, except for you took it even farther with figuring a linear transformation from one dye state to the other. i assumed it would not be linear! i thought the optics would be quite non linear, with the low amount of reacted dye being extremely sensitive relative to the high end. i will remember the method you used to generate that awesome linear curve using the entire frequency range instead of the single point. i have done similar experiments before, but my method was to essentially quantize the measurements and take a whole bunch of single point measurements at different points in the wave form (instead of just 515 nm) and then analyzing that. your method is way better!
excellent stuff. any idea how accurate your spectroscopy fitting technique is relative to modern techniques, mass spec and x-ray? have you found a technique that could've been used in the pre mass spec era that wasn't thought of because of the lack of available spectrometer, solvers and compute?
About 20 years ago a kindly grandmother in a gun store in Florida explained that the transmittance through one brand of riflescope was hindered very slightly by the lead in the glass; it must have been there to improve the index of refraction now that you mention. Thank you for the science!
Nice video, I've got a question: Why didn't you *test and verify your method against a lab* with an atomic absorption spectroscopy? This would also help determine if you really need the cyanide to mask other ions (in tap water samples) or if your method is good enough for accurate results.
i would be interested to see the lead quantity after reverse osmosis, like you mentioned that it works well, but a numerical lead concentrate would be great before and after. its more relevant to the regular viewer
I recall I was a kid and my parents kept asking to the greengrocers if their fruit and greenies were grown along some road. The conscience of lead pollution from vehicle exhausts was spread among people but nobody seemed to be able to confront the issue of lead. The ancient Roman writer Plinio referred to lead pipe workers to assume a pallor on the face as consequence of their kind of work. Thanks for the video...
If you also measure the spectrum of the other metals, your linear combination method will give you all the concentrations. Also, using the backslash operator, which does a pseudo inverse, is faster and easier.
You're making the very big assumption that all the metal ions react with dithizone independently. There's no guarantee that a solution of multiple metal ions will produce a color that is a linear combination of the individual spectra for the metals.
Very cool video! Btw we still use the Dithizone method (visually as a limit test) to test for lead in pharmaceutical raw materials (USP and FCC describe it). But for finished drug products, natural drugs and food we switched to ICP-MS. Since it is easier, selective for tons of heavy metals and more sensitive. Though you can go pretty low adapting the Dithizone method as you described.
Nice project. A way to improve the plot would be to use a proper color scale, like viridis. That way color in the image maps to concentration of the sample, instead of nothing useful. It makes it much easier to follow the plot. Other colormaps work as well, but I like viridis, because it looks nice and preserves contrast even for color blind people (and black-white printers, lol)
It looks like he used Google Sheets to graph his results. This is the first time that I have heard of the viridis colour scale. Could it be implemented with GSheets?
It’s awesome to see numbers on this! I have lead-crystal whiskey decanters but due to the worry of lead leeching into the spirits I would never use them as long term storage. (Usually just put the spirits in them for a few hours as they are being consumed by myself/guests.) Also, on evenings I plan to use them I let them soak in the sink in water with some vinegar in it earlier in the day. It’s cool to see that the random tip I read online years ago has some validity to it. Also, I know you postulated on it at the end but do you think ethanol would exacerbate leeching in any appreciable way?
I've wondered about this for a while. I was gifted a very nice lead crystal bottle,meant for use in a personal bar. Something you'd see somebody keep whisky in,in an old movie or something...but I was very hesitant to actually store any alcohol in it,for fear of leaching lead out of the glass. I kept it as a nice decoration,and decided I'd avoid using it for anything consumable. I'm quite curious now,and am wondering how alcohol might affect the outcome.
Won't the acidity of the extraction solution be quite important? And chemical composition. e.g. What happens if you store your port in a lead crystal decanter?
Really cool application of analytical chemistry, i was doing similiar stuff all the time at uni, however dithizone we only used for qualitative analysis of heavy metals. One thing i want to comment on: You measured absorbance for the certain wavelengths of the lead dithizone comlex. There is a law called lambert-beer-law that correlates absorbance to concentration. With a calibration curve you dont need to use that law mathematically to determine the concentration, in fact doing it the way you did is way more accurate due to cancelling out alot of errors, however you have to keep in mind, that the lambert-beer-law is a logarithmic correlation and therefore this kind of curve you get is very typical for these high absorbances you measured. In general you want to dilute your samples of your calibatrion curve and your actual test samples in a way that the absorbance stays in the linear fraction of the lambert-beer-law. Typically that is between 0,2-1,4 absorbance, if you exceed that you are measuring in the non-linear fraction of the curve and you cant really use a linear regression, which would be ideal. As far as i can tell, that is an additional issue for your absorbance drop in the higher range of your curve along side the saturation of dithizone with lead ions. All in all you did a great job with that in my eyes really bad methode with dithizone. As you mentioned the dithizone still having absorbance in the wave length you wanna use for the complex is not ideal. But im really glad you tried to cancel such errors out as good as possible!
I've always wondered about this but for BPA or other contaminants in plastic. Is it be depleted over time? If you throw your sports team souvenir cup in a bucket of water for a week is it safe to use? It seems like it would be. It would be interesting to cut one of your crystal vessels in two, leave one half in 5% acetic acid for a year and the other half in a cupboard, then retest to revisit the question of surface soluble lead regeneration.
I fucking love this guy more than any comment reader would want to see. My mans legit be giving me real information for free and showing me exactly what its worth in his own voice and reason.
One scenario that makes thinking about concentrations in terms of µL/L a bad idea is when you are dealing with non-linear densities of liquids. For example, when you try to make dilutions of D+ glucose in pure water (basically sugar water), adding 1 mL of pure water to 1mL of your sugary water will NOT result in 2mL. The key term you want to Google for is: "volume change upon mixing"
That's only really a concern if you're attempting to work backwards from the mixed solution. If you're trying to figure out how much of X to mix in Y, it doesn't matter if the volume changes upon mixing.
Here in India paint still contains lead. Although 90ppm limit was introduced in 2017 it is self certified by companies so still there is no regulation. So there is no way of buying good paint except for importing.
I love your videos! I rarely understand, most of your videos are way over my head but I pick up little things here and there. Not only that but it's just so cool that your doing all this at home.
Excellent video! A wide variety of skills and knowledge used here. I don’t have a use for lead concentration but the techniques used to work through the problem are valuable to see and for me to learn!
I would absolutely love to see Ben conduct a lk99 replication study, I think I would trust his result more than many other unknow academic researcher , if anything because he already succeed in making superconductor in a home shop ..
He wouldn't bother, because it's almost certainly a non-result that was manipulated to get more lab funding. Hence why no single other lab has been able to reproduce the results.
Absolutely AMAZING Project! I was thinking about this a while back (some holiday drinks in the fancy glasses). Somewhat comforting to know the risk is pretty low, and neat trick on the pre-leaching! I’m inspired to (once i have the capability) do more of that leaching testing. See of you could get *all* the Lead out, maybe do some TEM and/or AFM work with lead glass slides maybe to physically *see* the atoms move. Also testing material properties (especially “singing water glass” tone) changes with leaching would be neat. All in all though really cool project, and I can’t thank you enough for also Open Sourcing all the Data/Code!, absolute LEGEND!
Ben I just saw you at opensauce live and I just want to say you are a personal inspiration. You are the pinical of great, enjoyable, technical science content on YT.
I love your channel. You have great content. Never really thought about consuming lead from glassware I'm too poor to afford, but I really enjoy and respect the level of detail and in-depth information you pack into your videos.
I used to wash glassware with HF, which removes a little of the glass surface and that reduces contamination from the last run, but it might reveal a fresh surface of lead crystal.
Great video. This reminds me of my undergraduate research, where I needed to devise a way to measure small amounts of osmium in the presence of larger amounts of uranium.
Dude is really putting master's thesis amount of work into a single YT video.
Note that the overwhelming majority of polyethylene produced in industry, while energetically favorable and exothermic in chemical formation, still requires an inorganic or organometallic catalyst to initiate at lower temperatures and pressures. Typically these are Ziegler-Natta catalysts based on aluminum *titanium chloride* , the Phillips catalyst of a *chromium oxide* silica gel complex, or *antimony oxide* . Invariably, due to the viscous nature of molten PE during production, much catalyst remains in the final product, and will thus leach the metal catalyst into whatever liquid the resulting plastic vessel contains. This is almost certainly what the dithizone is detecting in your plastic water container. Incidentally, the catalyst for PVC, which the spigot may be made of, is mercury chloride, and a common stabilizer used in PVC is *LEAD oxide* .
Saved me writing a much less exhaustive comment.
Oh fuc.. I hate plastics in fresh water pipes and some part's got touch with my drinking water.
Some lead isn't even worse thing in different plastic types.
@Muonium1 When PVC is marked as "food safe" is that meant to indicate that a different catalyst has been used? A quick Google finds there was a kerfuffle over the construction of Vermont sugar houses in 2021 due to a leeching issue from non-food-grade PVC pipe. Not many people drink from lead crystal glassware anymore, but plastic is everywhere [citation needed]. I'm a computer engineer with no materials knowledge, but I assume that the migration of lead to the barrier layer could be faster in materials other than glass, meaning the rinsing process Ben described may not be adequate protection.
Thanks for this, I have been wondering why I detect chromium from my RO produced water and i could not figure it out.
It is from all the PE filter housing and hoses.
Leaching the chromium catalyst in to the water.
It is very slight amount barely detected on water measuring strips.
And it is the only contaminant I can find in the water.
It is still WAY purer than the tap water though.
@@cajampa 👍🏻👍🏻
Ah finally we see the "I asked chatgpt and it was right" project. I saw you post about it on twitter a while ago and wondered if it would ever show up in a video. Very interesting concept and now I understand how the heavy metal tests I've used in the past work! Very cool
I would really like to see this repeated for bright green fluorescent uranium glass.
By my estimation chatgpt gets it right most of the time. Seeing the chatgpt got it wrong videos are self selecting.
@@WeBeGood06 chatgpt regularly gets huge amounts of information wrong and bullshits about knowing things it doesn't know CONSTANTLY. It's completely untrustworthy and little more than a toy for amusement that can *occasionally* provide a useful insight about something. Ask it about detailed topics you are already an expert on, then ask it for citations in the literature to support its claims. It will simply fabricate everything from whole cloth. See the hilariously stupid Mata V. Avianca case from a month ago.
The number of people treating it like a search engine is astounding. It's a text pattern generator; it hallucinates, it lies, it confabulates.
@AppliedScience, what version of ChatGPT, was this 3.5 or 4?
@@WeBeGood06It has categories it does great in, and others it fails in. It does best with thoroughly documentated topics that have objective and numerical truth, which makes the source data very consistent. It's efficacy drops a lot when you give it softer science
Would have been cool to see if scrubbing the crystal freed up additional lead, to simulate regular dishwashing. Great content as always.
the dishwasher might make it safer because the rinse aid leaves behind a plastic coating- that is the haze that ruins glasses in the dishwasher after a time
People still use dishwashers? Is this 1995?
@@LanceBeckman your comment makes no sense: dishwashers have only gotten increasinly energy efficient and better at cleaning difficult to clean stuff. It's like saying "Glasses? People still use glasses? What is this, the 1400s?"
@@LanceBeckman : What do you use? Hands? Is this the ancient era? Can you get your hand washing water to an equal heat?
Yeah, I was thinking the same thing. Was wondering how long term use would change it too.
A joy to hear a video so well narrated.
You must be new here...
All Ben videos are perfectly narrated.
@combcomclrlsr The extraction and narration remind me of @JamesHoffman 's coffee videos.
Absolutely!
I love this channel. He thinks about just about every atom of what's going on.
Everything is fascinating! Studied physics which included also some chamical analysis.
Applied Science is easily in the top 3 technical channels on youtube. He goes to such lengths and documents everything so well. He understands the topics so well he can explain them to about anyone. Chemistry, engineering, electronics… every video is a masterpiece lol
top 3? what are the other two then? in my world it's literally the best technical channel out there.
@@Alexander_Sannikov Nighthawkinlight is really,really good too, would be my top 3 choice
@@Alexander_SannikovTech ingredients, Nile Red, Alpha Phoenix, Breaking taps, Practical Engineering, Nile Red, Electroboom... the list is long.
As a grey-haired Chemist, I especially enjoyed seeing him use + explain the UV/VIS spectrometer that fits in the palm of your hand (the LR1). Amazingly powerful UV/VIS capability for only a fraction of the cost $$$ compared to “professional” lab equipment used at US EPA and FDA laboratories like Perkin-Elmer and Agilent. Now I know what I want for my birthday present, an LR1 👍
@@Dinnye01while i've been subscribed to all of your listed channels and while tech ingredients does occasionally get sort of close, in my opinion this channel is just miles ahead of every other one. In terms of the host's expertise level, video subjects and the sheer amount of unique stuff they have published.
You might want to check tartaric acid/tartrate as an extraction solution. Tartaric acid is famous for being found in high doses in wine while also forming extremely stable, soluble complexes with lead, being able to dissolve even lead sulfate. So real wine could extract way more lead than just dilute acetic acid...
That's a great point, there should be no acetic acid in wine unless it has turned. The root Latin words in "vinegar" are Vin = Wine and Eger = sour . Tartaric, malic, citric, and succinic are the primary acids found in wine, this is also why total acidity is more valuable than pH for testing wines acidity. Also as mentioned at the end of the video many other solvents may be drunk from these glasses which may pull out more or less lead.
Or phosphoric acid, being that kids and other non-alcoholics are going to be drinking soda out of these leaded goblets at the china-and-crystal fancy occasions.
I'm curious, I would think that the solvent would not matter much. My rationale is the lead extraction is inhibited by the diffusion through the glass, not the thermodynamics of dissolving.
@@Kycilak My bet is it depends on if the glass has been pre-extracted or not. If it has, likely no difference. If it hasn't then that first drink is going to have way more lead.
Doesn't the wine making also produce the tartaric acid or at least the cream of tartar?
My family is from Hungary and my grandfather was a glass man. When they immigrated to Cleveland he continued to cut crystal. If you live in a house in Cleveland that has a chandelier it is possible that he either cut all the crystal or cut a replacement piece. He was a true artist.
Regarding the plastic carboy: many plastics have organo-metallic additives or surface contaminates which are manufacturing additives. For example, mould release agents, and many other modifier agents. Often these are left on the surface of the plastic product in relatively large amounts, or can leach out slowly over time. We had a huge problem with tin (Sn) additives leaching out of plastics in one project I worked on.
Although NileRed videos are fun, but this is how I’d like a research presentation. To go through all the aspects, mistakes and triumphs, math science and engineering, tip’s tricks and techniques, and so on. Thanks again Ben, and awesome video as always 👍
I've found myself liking Nile Red's videos less and less over recent years. IMO he's clearly appealing to a more casual viewer, and the content feels a little "dumbed down" compared to his older stuff
@@JustinDriver-m1i Yup going for a bigger audience
Nilered is just a kid making memes and throwing tantrums.
@@quarteratom lol tantrums? When did he do that?
@@iTeerRex ua-cam.com/video/tGqVMbAQhBs/v-deo.htmlm6s
For example.
In the hospital lab they used a multi-stage deionizer and then all the water was distributed via tin pipes. I asked why not glass and was told the deionized water would leach all sorts of impurities out of the glass.
This depends on the glass aswell, normal sodium glass tends to leach more impurities than borosilikat glass
Why not pure Sapphire? I have a Graphics tablet where the entire surface is a huge sapphire panel. It's probably the only scratch resistant thing I have.
@@AmstradExin Most likely a shaping constraint, as all synthetic sapphire applications I am aware of can be made and cut from flat sheets (screens, camera lenses etc)
@@timkurz6086 Borosilicate glass is less likely to leach impurities, but plastic containers or even soda-lime glass are specifically preferrable for boron analysis because it does not leach boron.
@@fatiheneskuru4332 seems logical to me 😂 however i have to admit ive never done boron analysis to this day nor have i heard someone doing that to encounter such a problem!
26:30 : If you made standards for copper, nickel, and other metals, I think you could use a multivariate least squares approach to find the concentration of all trace metals in your sample simultaneously, which would both tell you if there's other stuff in there and give you more accurate estimates of lead that wouldn't be confounded by other metals.
This.
This assumes that the result is a linear mixture of the standards, which may not be the case. Maybe the literature has something to say, but in the absence of that, you'd have to make some samples which were known mixtures of metals to validate the method.
@@bob2859good point
@@bob2859 The data at 22:14 shows that the absorbance for lead is quite linear until you reach saturation. It should definitely be linear in the limit of low concentration.
The idea with the dithizone is to always have an excess of unreacted dithizone, so that the reactions are never starved for it and all of the metal reacts. When all of the metal reacts, the absorbance of the reacted dithizone is directly proportional to the concentration of the metal. So long as each different metal has a different absorbance spectrum when reacted with dithizone, yes, it's possible to measure the concentrations independently in the combined solution. Absorbance spectra add linearly at each wavelength and the contributing spectral curve shapes are known, so you only need a linear transformation to separate them and get the concentration of each metal.
as a analystical chemist i'm so happy u actually addressed the PPM PPB notation. i hate it especially when they use ppm as mg/l. its so inaccurate because of denisty and all
Even he was like .5% acetic acid. It's just natural to think that way.
It seems fine for comparisons, like 300ppb lead vs 200 ppb lead, but it’s definitely not good for specifications, because it’s vague. By volume? By mass? Certain units?
This doesn’t matter as much when there’s another reference point, but is extremely important for other purposes
I agree, when following recipes, nothing beats the mass per mass specification. So better use mg per kg of water, not per liter 😊
As someone who does water lead testing as part of my job - this is really great!
The dithizone is a great choice for UA-cam because it gives a color as a function of metal content!
With your electronics chops, I'd have thought maybe you'd have designed and built a electrochemical potentiostat to perform anodic stripping voltammetry - which is also usually sensitive down to the 10 is microgram/L range. In that method dissolved lead(II) is reduced to lead metal at an electrode and then "stripped" from the electrode by applying an oxidizing potential to the electrode. Usually a mercury-lead amalgam is used to create the deposit, but bismuth also works and is non-toxic. Other metals such as copper and zinc strip off at different potentials and therefore the method can be used with other metals present and also to quantify those metals. The only downside is that you have to use the method of standard additions to each sample to make your determinations - so it is tedious (perhaps more tedious than the liquid-liquid extraction).
From what I understand, the real danger of lead glass is it's use as a decanter for alcohol, especially if you leave liquor sitting in it for years.
From Wikipedia: In a study performed at North Carolina State University, the amount of lead migration was measured for port wine stored in lead crystal decanters.[20] After two days, lead levels were 89 µg/L (micrograms per liter). After four months, lead levels were between 2,000 and 5,000 µg/L. White wine doubled its lead content within an hour of storage and tripled it within four hours. Some brandy stored in lead crystal for over five years had lead levels around 20,000 µg/L.[21]
thank you.
Excellent video! It would be interesting to run the glass through dishwasher let's say 50times, leave it for a month and then repeat the experiments - to see A) if the dishwasher leached all the mobile lead out of the surface or B) made it worse by making the glass bit more porous(etched by the alkaline dishwasher powder) so there is more surface for the lead to come out in the next drink
In the same spirit, hand wash it with the abrasive part of a kitchen sponge and hot water
Another great video. You don't let yourself get sidetracked, calmly choose a topic that appeals to you, and then kneel down fully into it. Above all, I like the versatility of the topics; well, it's all applied science.
Lead crystal fluoresces a ghostly blue under UVB. An LED UV flashlight is great for uranium glass but won't cause lead crystal to glow. Love your videos!
Have you tested this yourself? what wavelengths?
I regularly see the ice blue glow of certain pieces of glass with a UVA flashlight at 365nm but I don't know for sure if it's lead, or cerium, or something else.
ben, you are a true hero in my eyes and you push me to be the man i aspire to be. the fact that your projects have such depth and involve so much scientific rigor, methodology and forethought, while at the same time being done in your garage with homemade setups, really makes me wonder about the boundaries of DIY. i do not know how you find the time, money and motivation to do these very advanced projects, but it makes me hopeful that i will get to a point in life that i can do the same. please keep being curious and making these awesome videos, because, while this community is not as big as i would like it to be, i am sure you motivate many people like me. i wish you the best of luck!
I just discovered your channel, and this one video convinced me that you are a real gift to humanity. It inspired me to know that there are people like you in the world. Thank you for your generosity in doing this experiment, and sharing it for free with the rest of the world!
7:00 "so luckily I found a pretty good solution" very nice pun
I am a retired analytical chemist. Well done! The ultimate in metals work is an inductively coupled plasma mass spectrometer (ICP/MS). Detection limits drop from your levels by a factor of 1000 or more. Typically low limit metals work is done in a metal-free, clean room. There is no exposed metal. All labware is polyprop or PTFE (aka Teflon). Reagents are certified for metals work, or prepared in-house. One comment about your pipettes. Air displacement pipettes like you use are prone to error. Positive displacement pipettes are much better. Also, I bet if you put some high pH extractant in your lead crystal, the lead levels would go back up. Almost forgot. I knew the answer to the cloudy lead solution problem as soon as I saw it. Dissolved CO2 is a real problem in a lot of wet chemical methods.
"I bet if you put some high pH extractant in your lead crystal, the lead levels would go back up."
What do you think would happen to make the lead levels go back up?
The stuff you do is absolutely brilliant. Giving some figures to these kinds of toxic substances is extremely interesting.
An interesting question is how usage patterns affect things. If it's your "special crystal" that you pull it a few times per year, you have maximum recharge from migration, but minimum exposure events. If, instead, you use it every day, then you'll be extracting frequently but getting less exposure each time. If the migration is slow enough, then both might be similar in total exposure because the rate of migration matters the most.
Alternatively, if the migration is somewhat faster, then the layer of glass which is extracted from might "fill up" for the occasional user so the everyday user gets more exposure, but maybe not excessively more.
Finally, if the migration rate is pretty fast, then every extraction leads to roughly the same exposure level so the daily use might be getting a hundred times the exposure of the occasional user.
Ben's results suggest that, for his extraction method at least, his glassware isn't in the fast recharge regime. It suggests that it could be in the slow (migration limited) or medium (daily is worse than occasional, but maybe not immensely worse) regime.
Wow, that's a nice idea that you can pretty much make these glasses safe by pre-extracting most of the lead at the surface layers, awesome!
This is great advice for anyone who uses a lead crystal decanter. Or it's an excuse to drink the contents straight away 😁
The issue is that he used an acidic extraction liquid. The problem is that moast soaps especially for dishwashers are basic. Basic solutios tend to attac glass much more. So every time you put this stuff in the dishwasher you remove a small amount of glass wich could free more lead. So using citric acid is not very realistic I think. Still like always it is a super cool video.
@@electricalychalanged4911 You wouldn't want to put lead crystal into the dishwasher anyway. Even a small amount of surface clouding will ruin the visual effect it is used for...
@@electricalychalanged4911 I thought that he said "acetic", like vinegar.
Would you or somebody confirm whether or not vinegar would work, and whether or not it would damage the glass?
@@eugenetswong Vinegar is a week acid pH 4,7. Glass or SiO2 does not react at this pH. But many if not most metal oxides do, forming mostly soluble salts. That goes for lead oxides too. in the concrete case the accessible lead oxide on the surface of the Glass would be dissolved by Vinegar (and most beverages es they tend to be acidic) over time. But after putting anything basic in there pH 8 or higher (like many soaps or cleaning agents, but also some herbal tees and vegetable juices) a very thin layer of glass can be removed which would expose more lead oxide. My argument is that removing the Lead by long exposition to week acids will not make the lead glass safe to use for food in most use cases I think. So can it work? Yes, if no basic stuff touches the glass afterward . Will it damamge the glass? Defiantely not.
There used to be significant amounts of lead additive in some types of PVC plastic, used to improve UV resistance and extrusion characteristics. I think it's mostly been eliminated, at least in the developed world. One problem with it was that if the product (such as vinyl window blinds) were exposed to sunlight the plastic would deteriorate in a thin layer which would turn to (lead-bearing) dust which could be ingested or inhaled, and the process continued with the freshly exposed plastic.
Last cordless drill I bought new came with a charger. The charger cord does have a lead warning. It is still being shipped in (ryobi). The vinyl insulated lunch totes are notorious and used mostly by children. Don't know if those are still around but I would think so. Appently the amount of lead used shot-up in the past 10 years due to re-regulation.
**Apparently 😃
Yeah, people talk about plastic (etc) as if it’s the plastic itself that’s the only problem, but often it’s the additives and there’s little control over what is being used as additives. Or maybe it’s something made of steel, that should be safe, but what if it’s steel with a significant amount of lead in it, and so on.
I'm speculating but I would love to know if polymerisation catalyst could have been the problem. I'm sure that there is some catalyst in final product, but I have no idea if it is in high enough amount and if it would even leach in solution.
@@napalmholocaust9093That was a California warning label because the solder might have contained lead. Long standing joke is "Everything in California causes cancer, especially California." Generally anything imported through California gets one of those tags slapped on them due to California law.
A joy to hear a video so well narrated.. A joy to hear a video so well narrated..
I used to work in R&D at a breathalyzer company. If you want to talk about confusing units, look at that industry. "%bac" can be defined in a lot of ways, just like your example of ppm. Also, we used the same method of diluting a stock solution when we were studying the linearity and sensitivity of our devices. As always, great video, Ben!
Interesting. Would love to have a discussion with you about calibration! I've recently ordered some alcohol sensors (the ubiquitous MQ-3) and I'm curious how to come up with some sort of actual measurement. How do the machines take into account people with different heights and weights? Or is that not considered at all, and it just looks at exactly how much alcohol is in the breath sample. It seems odd to me because different BAC levels show completely different levels of impairment and intoxication in different people -- but at the same time, how can you design a law for e.g. DUI without having some sort of non-subjective standard? It seems like a complex thing to do well.
@@AureliusR Impairment isn't taken into account by many (all?) legal systems, I would say because it's too difficult to measure. Instead alcohol breath or blood concentration limits are set. In New Zealand they are 250 micrograms of alcohol per litre of breath, or more than 50 milligrams of alcohol per 100 millilitres of blood which give a clear pass/fail result. Regarding calibrating an MQ3 presumably you'd want to generate a range of standard alcohol / air concentrations. More difficult than liquid solutions so have fun.
Vintage Orange Tupperware I have from my grandmother supposedly also contains lots of build-in metal supplements to start the day, so I just use them around the shop, not in the kitchen.
This is the bar for scientific communication and process documentation imo. Thank you for the videos.
Very interesting video. I was just researching this week about lead content in brass which could be found in espresso machines and garden hose fittings.
All machined brass. They call it "free turning" 12 percent is pretty common.
@@napalmholocaust9093while I don't know exactly what alloy you're referring to, in my experience (as a machinist) the most common free machining brass is ASTM C360, which has an allowable lead content of 3-4%. There are also other "eco brass" alloys available that have near zero lead content, specifically for use in high volume production of plumbing parts and fittings that will come into contact with drinking water.
I agree. I try not to purposefully expose myself to excess lead knowing that I'm probably exposed to it anyway through daily activities. A good goal in life is to keep lead in your bones as low as possible. 😁
I use “grains per barleycorn” for maximal annoyance.
I prefer firkins per gloop, but to each his own.
I don't understand every detail of the chemistry but your combination of the subject with electronics, programming, and science [observation of the facts compared to a hypothesis] plus general intuition has always been education. My personal growth and career have been advanced by you and a few similar channels. Thank you so much for your time and the contributions you've made to the community.
Serious scientists all have the following tools: XRF Gun, Mass spectrometer, Electron microscope, Oscilloscope, Series of acids, pure forms of as many elements as possible, solder gun, wires, protective eyewear, gloves, lab coats, UV light, IR thermal camera, Series of high speed cameras for various wavelengths, vacuum pumps, vacuum chambers, CNC machines, glass making equipment, windowed high pressure metal pipes that fit together, table top electric kilns in programmable and regular forms, several computers, ultrasonic microphones, various freezers, solutions and solvents (include liquid nitrogen in there) and centrifuges.
Those all cost hundreds of thousands of dollars total. Most scientists aren't well off but are also interested in MRI machines, DNA decoders, super computers and just sort of not even think about owning but competing for time on orbitting telescopes. 😄
Point is to really know what's going on with most questions.
You don't often wonder, "does this have too much lead in it?" but if you did someone with the tools could answer that, like on this channel. 😊
A fun one today that's asked a lot but rarely meaningfully answered is, "is this computer secure?"
Good luck answering that without going over billions of lines of code and looking through hardware with electron microscopes. Some chips come with hardware vulnerabilities built in you can only see by decapsulating them. Software you must test with supercomputers for vulnerabilities not discovered yet. It takes a lab to answer such a simple question because there is a multi-billion dollar industry built to make them not secure.
Great channel.
I loved hearing your data analysis process, especially the idea about doing a best fit with the extremal spectra! I have a background in mathematics and physics, but my mom is an abalytical chemist, and hearing theae methods of analysis is always really cool!
I don’t know of any channel like yours, especially your presentation style, and I’m so grateful you share these experiments and adventures with us.
It would be interesting to do additional calibrations for common metal ions and then see if a multi-dimensional functional fit can get good accuracy for multiple metals at once.
If they're independent it should be pretty accurate right? But what about the unreacted values I this those are linearly dependant with every metal, or are they not? (Just learning linalg so this may be way off the mark lol)
@@xhivo97 I don't know, there were thoughts as to how these things might interact, but if we can find the ratios of bound values, then we can probably do a correlation to total unbound values. It would be work to calibrate, but if it isn't linear, we should be able to train a ML model.
I was thinking something similar, but different: instead of calibrating against ultrapure water, could the full spectrum functional fit method be used against tap water as a baseline, and just measure lead increases against that baseline?
@@aaronbotsis7218 The problem with tap water is that it tends to be inconsistent.
So you would have calibrate the baseline each time you take water fron the tap.
Thank you for teaching us about lead glass!
I assume your lead glassware was all new, I would be interested in testing glassware that is decades old as most of us probably have, but inversely hasn't been used in decades. Does the lead always over large enough timescales migrate to even distribution, or is 30 year old glassware with hundreds of uses but none in the last 10 years indistinguishable from non-leaded glassware.
Yes. My thoughts exactly.
Or do a test running the glass to through a dishwasher, or the suggested soak for a few days.
@@ch94086 Or maybe scratch it with a spoon to simulate stirring a drink. If glass with lead content is softer it might be easier to scratch some of it off.
@@ch94086 Nice, soak the dishwasher in lead particles.
@@ch94086coming from a country that used to use crystal like it was going out of fashion, putting it into a dishwasher makes the glass cloudy.
Thank you do much for making the episode about lead crystal instead of about the machinery to check ppm. The moment is started I was thinking ‘hmm what IS lead crystal’ then you read our minds and focused on it
I'm really glad that I'm not the only one who hates PPM. I know technically it's well defined, but if you haven't read the spec, PPM can mean so many things. Is it PPM in molecule count? Is it PPM in volume? Is it PPM in weight? How would an average person know?
Even then, measuring things in Liters vs KGs is dangerous, too, because we're comparing volume with mass, disregarding any density arguments. Personally I'm very partial to always comparing mass to mass. Volume measurements only complicate things therer
I don't see this as being a problem with PPM itself as it is with just being unclear about what you're measuring. PPM is a perfectly fine unit for expressing ratios of numerical quantitiies (that have the same unit, obviously mg/L is not ppm in the first place), but a substance is not a numerical quantity. Using PPM for a concentration without specifying whether it's by volume/mass/mol is like asking for "50 water" without specifying a unit :P
Where ppm and ppb gets me is in metrology. Just state the uncertainty in the units measured, it's needlessly confusing. 10 ppm means less than +/- 10 μg
@@HBomb157 They mean completely different things, 10 ppm is a relative error, ±10 μg is an absolute error
@@MatthijsvanDuin both are usually specific for a full scale range so effectively the same. But you right. Still don't like it.
Right when I was thinking that there may be a chance that the lead content in the glass layer, which was in contact with the water, can slowly recover over time due to diffusion within the material, you started to comprehensively answer exactly that question in your video. That's why I like your content so much. This video was super interesting, TYVM!
Really interesting results. I wonder how much lead was being consumed when they used to add it to sweeten wine back in the day especially compared to the fairly low amount in lead crystal. Also wonder if you dug up some dirt near an old(pre 1972ish) busy highway intersection how much lead is still in the ground from the use of leaded fuel.
As always, another great video. I hope that one day people will be more attracted to science and less to junk videos.
I think you could also do a ratiometric approach: divide the absorbance value at one maximum by the other, and plot that against the concentration of lead. In theory as one peak increases the other decreases and the ratio changes, thereby making your measurements independent of things like uneven excitation intensities across samples (since you're looking at the relationship between intensities at 2 wavelengths). This is how some fluorescent biosensors are characterized
You could do that, but it's better to treat the concentrations of unreacted dithizone and dithizone reacted with lead as independent. That's because, as Ben mentioned, you don't know how much residual unreacted dithizone you'll have in the end. It depends on the starting concentration and on how much of it reacts. The concentration of reacted dithizone is what you ultimately care about, and you'd like to measure that without interference from the the concentration of unreacted dithizone. A ratio won't accomplish that. But it is enough to sample the absorbance spectrum at just two wavelengths. Since you know the shapes of the unreacted and reacted absorbance spectra and they add linearly at each wavelength to create the observed absorbance spectrum of the combined solution, it's just a linear transformation to separate them.
Wow, I was having some flashbacks when I developed the first home cholesterol tester in 1986. You did a superb job, thanks for this excellent video!
he does this in his free time? it's incredible, who does this?
Just being a layperson who is entertained by this stuff, I really liked the fairly normalized explanation of the "why". You dove down the rabbit hole of one thing and ended up on this niche topic. I also like your testing that almost ended up on "obvious", but now you have numbers to back it up. The end bit where you whip out the xray gun from years ago... priceless. It showed that one piece was either used or altered in the manufacturing process.
Thank you for your well explained videos.
I am always amazed at how much work you put in to make them.
This is just awesome. Knowing all this panic disorder which appears every time led is mentioned - "dont look at it, it can kill you!", I would say it is worth publishing. You have nice results!
But all these battles with reviews, registrations, editors, no affiliation, I assume, probably is too much.
Exdellent presentation. It would be interesting to do the entire experiment using the chemicals and water as purchased to see how sensitive the test could be without the extra (significant) work in purifying the reagents.
Do they use lead in vacuum tubes?
@@Eduardo_Espinoza No. Lead has a high vapor pressure so it must not be used. Mercury was used in special purpose tubes but no longer. Solid state devices have almost entirely replaced vacuum tubes.
@@glasslinger
might make good shot glasses in the end :)
Tnx your time !
Thank you for your time* )
I've been analyzing metals in water by ICPOES and ICPMS for 13 years and I've always wondered how metals were quantified in the days before ICP was practical. This video is fascinating for me. I love all the chemistry videos you do.
Would love to see someone do this on the old Visions glassware as well, especially since it's used at higher temperatures for cooking.
👍 Always excited when you post a video!
Can we acknowlege that this Guy is so skilled it's depressing. The things he puts together in his shed....even the smaller projects are totally op.
He's a hero character in the MMORPG called life.
Imagine that Valve let people like him (and others) go because they chose to focus on hosting games...
@@aserta bussiness wise that was the right thing to do
I am usually really loving every video you make, but this time I was a bit hesitant to watch it. I finally gave in just to see what it was about, and it was chock full of very interesting things that I didn’t know about lead.
In other words, another great and informative video and I should not be hesitant next time I am uncertain about any of the topics that you pick.
A very interesting video indeed. Thank you.
The flagon that was labeled "Fine crystal" and contained loads of lead, yet didn't leech any into the water was fascinating. I'll bet there are standards somewhere that limit potential leeching from "food-safe" containers, and some factory somewhere has developed a process to make them safe.
It could be as simple as a thin plastic coating on the inside of the container.
@@Regular6782 I’m honestly intrigued.
@@Regular6782 I've seen some producers put a thin layer of ordinary (non-leaded) glass on the inside.
@@somedumbguy0 wow. How do they do that? Is it part of the initial manufacturing process or is it done after its already moulded?
@@Regular6782 I don't know, but I would guess after molding. I think the good stuff is still cut after molding. There is a lot of fine manipulation that can be done with glass. Glass art is really cool.
Fascinating as always! One of the few channels that I have notifications turned on for; always click without even reading the title because I know it will be interesting regardless of subject!
Hm, it might be interesting to see more technical repeats (3 or 4) and calculate standard deviation. Also, it might be interesting to see if you would see an increase in leeched lead after using a dishwasher (they do heat up to some high temperatures after all). Maybe testing some cold solutions could be done? Or breaking off some parts of cristals, then keeping them in high temp for a much longer period of time? But in general it was a very fun video, and it is quite informative. I had no clue that lead was used in cristals.
I totally agree with ditching the parts per x amount notation, but why no go even further and use molarity instead of g/L? I mean, if you measure 1 mg/L of Pb and 1 mg/L of Cu, there is actually more than 3 times more Cu atoms than Pb atoms in that solution.
Damn you for always posting when I’m about to go to bed 😂
Not related to this video, but just in case you haven't heard about the papers for LK-99 you should definitely try that next Ben. It hasn't been replicated yet, but its supposedly a room temperature, ambient pressure superconductor (Tk > 120C) and the synthesis according to the paper is totally something you can do with the tools you already have. You already did YBCO and this just requires firing at 925C in 1 micron vacuum, and the precursors are pretty basic and available. It would be really cool if you were one of the first to reproduce it and it was documented on video in such a great way.
You should try to recreate LK - 99.. THE ONLY MAN FOR THE JOB..
this is amazing. its exactly the experiment i've wanted to run for a long time, especially with the software gathering wavelength vs amplitude data using a calibrated sensor. i see a lot of experiments that just eyeball or use a comparison card for measuring with dyes! we can do SO much better! this video is almost exactly how i would have done it, except for you took it even farther with figuring a linear transformation from one dye state to the other. i assumed it would not be linear! i thought the optics would be quite non linear, with the low amount of reacted dye being extremely sensitive relative to the high end. i will remember the method you used to generate that awesome linear curve using the entire frequency range instead of the single point. i have done similar experiments before, but my method was to essentially quantize the measurements and take a whole bunch of single point measurements at different points in the wave form (instead of just 515 nm) and then analyzing that. your method is way better!
excellent stuff. any idea how accurate your spectroscopy fitting technique is relative to modern techniques, mass spec and x-ray? have you found a technique that could've been used in the pre mass spec era that wasn't thought of because of the lack of available spectrometer, solvers and compute?
About 20 years ago a kindly grandmother in a gun store in Florida explained that the transmittance through one brand of riflescope was hindered very slightly by the lead in the glass; it must have been there to improve the index of refraction now that you mention. Thank you for the science!
Nice video, I've got a question: Why didn't you *test and verify your method against a lab* with an atomic absorption spectroscopy? This would also help determine if you really need the cyanide to mask other ions (in tap water samples) or if your method is good enough for accurate results.
I had wondered about this, and never got around to researching it. Thanks very much Ben
i would be interested to see the lead quantity after reverse osmosis, like you mentioned that it works well, but a numerical lead concentrate would be great before and after. its more relevant to the regular viewer
мицеллы коллоидных растворов весьма крупны, поэтому обратный осмос действительно должен быть эффективен против солей свинца.
I recall I was a kid and my parents kept asking to the greengrocers if their fruit
and greenies were grown along some road. The conscience of lead pollution from vehicle exhausts was spread among people but nobody seemed to be able to confront the issue of lead.
The ancient Roman writer Plinio referred to lead pipe workers to assume a pallor on the face as consequence of their kind of work.
Thanks for the video...
If you also measure the spectrum of the other metals, your linear combination method will give you all the concentrations. Also, using the backslash operator, which does a pseudo inverse, is faster and easier.
You're making the very big assumption that all the metal ions react with dithizone independently. There's no guarantee that a solution of multiple metal ions will produce a color that is a linear combination of the individual spectra for the metals.
@@tissuepaper9962 That is indeed the hypothesis. He was already working with it. I'm curious to see how far it holds.
Very cool video! Btw we still use the Dithizone method (visually as a limit test) to test for lead in pharmaceutical raw materials (USP and FCC describe it).
But for finished drug products, natural drugs and food we switched to ICP-MS. Since it is easier, selective for tons of heavy metals and more sensitive. Though you can go pretty low adapting the Dithizone method as you described.
Nice project.
A way to improve the plot would be to use a proper color scale, like viridis. That way color in the image maps to concentration of the sample, instead of nothing useful. It makes it much easier to follow the plot. Other colormaps work as well, but I like viridis, because it looks nice and preserves contrast even for color blind people (and black-white printers, lol)
It looks like he used Google Sheets to graph his results. This is the first time that I have heard of the viridis colour scale. Could it be implemented with GSheets?
The illustration of the grain of salt with the jugs of water was very informative!
It’s awesome to see numbers on this! I have lead-crystal whiskey decanters but due to the worry of lead leeching into the spirits I would never use them as long term storage. (Usually just put the spirits in them for a few hours as they are being consumed by myself/guests.) Also, on evenings I plan to use them I let them soak in the sink in water with some vinegar in it earlier in the day. It’s cool to see that the random tip I read online years ago has some validity to it.
Also, I know you postulated on it at the end but do you think ethanol would exacerbate leeching in any appreciable way?
so fascinating! Another contribution to our collective knowledge! Thanks, Ben!
Bruh make LK-99 already we need you
Wow you break things down so intuitively
I've wondered about this for a while. I was gifted a very nice lead crystal bottle,meant for use in a personal bar. Something you'd see somebody keep whisky in,in an old movie or something...but I was very hesitant to actually store any alcohol in it,for fear of leaching lead out of the glass. I kept it as a nice decoration,and decided I'd avoid using it for anything consumable. I'm quite curious now,and am wondering how alcohol might affect the outcome.
It'd probably be fine either way, but the general advice is to use it to serve alcohol rather than store alcohol.
Won't the acidity of the extraction solution be quite important? And chemical composition. e.g. What happens if you store your port in a lead crystal decanter?
Really cool application of analytical chemistry, i was doing similiar stuff all the time at uni, however dithizone we only used for qualitative analysis of heavy metals. One thing i want to comment on: You measured absorbance for the certain wavelengths of the lead dithizone comlex. There is a law called lambert-beer-law that correlates absorbance to concentration. With a calibration curve you dont need to use that law mathematically to determine the concentration, in fact doing it the way you did is way more accurate due to cancelling out alot of errors, however you have to keep in mind, that the lambert-beer-law is a logarithmic correlation and therefore this kind of curve you get is very typical for these high absorbances you measured. In general you want to dilute your samples of your calibatrion curve and your actual test samples in a way that the absorbance stays in the linear fraction of the lambert-beer-law. Typically that is between 0,2-1,4 absorbance, if you exceed that you are measuring in the non-linear fraction of the curve and you cant really use a linear regression, which would be ideal. As far as i can tell, that is an additional issue for your absorbance drop in the higher range of your curve along side the saturation of dithizone with lead ions. All in all you did a great job with that in my eyes really bad methode with dithizone. As you mentioned the dithizone still having absorbance in the wave length you wanna use for the complex is not ideal. But im really glad you tried to cancel such errors out as good as possible!
Try to make the LK-99 super conductor.
You mean the LK-99 'not room temperature superconductor'
I just love these videos. Well narrated. Great b roll. Love the methodology and you talking about the "gotchas" you encounter like dissolved CO2.
I've always wondered about this but for BPA or other contaminants in plastic. Is it be depleted over time? If you throw your sports team souvenir cup in a bucket of water for a week is it safe to use? It seems like it would be.
It would be interesting to cut one of your crystal vessels in two, leave one half in 5% acetic acid for a year and the other half in a cupboard, then retest to revisit the question of surface soluble lead regeneration.
I fucking love this guy more than any comment reader would want to see. My mans legit be giving me real information for free and showing me exactly what its worth in his own voice and reason.
One scenario that makes thinking about concentrations in terms of µL/L a bad idea is when you are dealing with non-linear densities of liquids. For example, when you try to make dilutions of D+ glucose in pure water (basically sugar water), adding 1 mL of pure water to 1mL of your sugary water will NOT result in 2mL. The key term you want to Google for is: "volume change upon mixing"
does this mean they'll explode an enclosed container if mixed? does this mean you can separate them by compression?
That's only really a concern if you're attempting to work backwards from the mixed solution. If you're trying to figure out how much of X to mix in Y, it doesn't matter if the volume changes upon mixing.
Trained analytical chemist here--you're an inspiration, Ben! Awaiting the day when you step it up with volumetric pipettes and flasks =D
Here in India paint still contains lead. Although 90ppm limit was introduced in 2017 it is self certified by companies so still there is no regulation. So there is no way of buying good paint except for importing.
Asked an architect and he said limewash is the only non toxic wall decoration
I love your videos! I rarely understand, most of your videos are way over my head but I pick up little things here and there. Not only that but it's just so cool that your doing all this at home.
Love the ChatGPT story!
Excellent video! A wide variety of skills and knowledge used here. I don’t have a use for lead concentration but the techniques used to work through the problem are valuable to see and for me to learn!
I would absolutely love to see Ben conduct a lk99 replication study, I think I would trust his result more than many other unknow academic researcher , if anything because he already succeed in making superconductor in a home shop ..
He wouldn't bother, because it's almost certainly a non-result that was manipulated to get more lab funding. Hence why no single other lab has been able to reproduce the results.
@@AureliusR yes on hindsight I wouldn't want him to waste his time..
Amazing content. Please keep uploading! I've followed your stuff for years and won't stop soon. thank you!
Who remembers leaded petrol?
Absolutely AMAZING Project! I was thinking about this a while back (some holiday drinks in the fancy glasses). Somewhat comforting to know the risk is pretty low, and neat trick on the pre-leaching!
I’m inspired to (once i have the capability) do more of that leaching testing. See of you could get *all* the Lead out, maybe do some TEM and/or AFM work with lead glass slides maybe to physically *see* the atoms move. Also testing material properties (especially “singing water glass” tone) changes with leaching would be neat.
All in all though really cool project, and I can’t thank you enough for also Open Sourcing all the Data/Code!, absolute LEGEND!
Great video! A tip for using a separatory funnel : you can keep the lid on and degas it upside down, away from anyone, with the valve.
Ben I just saw you at opensauce live and I just want to say you are a personal inspiration. You are the pinical of great, enjoyable, technical science content on YT.
I love your channel. You have great content. Never really thought about consuming lead from glassware I'm too poor to afford, but I really enjoy and respect the level of detail and in-depth information you pack into your videos.
I used to wash glassware with HF, which removes a little of the glass surface and that reduces contamination from the last run, but it might reveal a fresh surface of lead crystal.
Great video. This reminds me of my undergraduate research, where I needed to devise a way to measure small amounts of osmium in the presence of larger amounts of uranium.