I was going to say as a welder that hydrogen entitlement would be a massive issue. most if not all certified welding procedures worldwide specify low hydrogen electrodes when arc welding high pressure steel pipes. Hydrogen gets into the steel crystalline structure and basically turns it into a brittle sponge much of the natural gas infrastructure is just carbon steel so I could see it being suspectible to this issue.

I saw the title and thought - gee that's a bad idea. I watched the video expecting to have my assumptions challenged, but discovered that the problems I was aware of were only the tip of the iceberg. Thanks.

Paul Martin has very impressive communication skills.

I recently discovered your channel and really appreciate the soundness of the engineering, pragmatism and non-preachy presentation. A real breath of fresh air,

Finally someone with some sense talking about this topic! How refreshing! The other thing no one talks about is the different hazardous area classifications between traditional hydrocarbons and hydrogen. Most hydrocarbons are Group D chemicals (the least restrictive type of flammables) but hydrogen is a Group B chemical. That's not an insignificant challenge because hydrogen has a very low minimum ignition energy, so low that just venting it out of a pipe to atmosphere will catch it on fire due to the friction. It also burns with an invisible flame when purified so you can't even see it when it does catch on fire. Handling it is industrially is very plausible and already heavily done, but expecting the average person to handle hydrogen without incident is a tall order and not one that will end without some loss of life.

I am working on a offshore city and spent a couple years crunching the numbers for everything including energy , and if I learned anything , you have to put real numbers to the problems , and not have any preconceptions about the results. Another thing I learned was how really amazing results you can achieve by going beyond what is normally considered "economically viable" efficiency improvements.

I LOVE this guy Paul Martin! We are both chemical engineers, and we have both the exact same opinion! He is much better than me at communicating, but that's even greater! Thanks Rosie, for having given us the privilege of hearing what Paul has to say!

Several problems: First, hydrogen will leak from a network when it was leak proof with the larger natural gas molecule. Second, natural gas has a very wide explosive range. Even a tiny leak will form an explosive mixture in air. Third, it takes an extremly low energy spark to ignite hydrogen. I think the better solution is to store renewable energy sources as hydrogen at the source then transmitt the energy as electricity.

I agree with basically everything he said. "jetted" is referring to the fixed orifices that are used to regulate gas volume through a device. They are in every gas appliance and pressure regulators among other uses. They would all have to be changed, aside from the down rated performance of the appliances. This would be expensive but very complicated as you'd have to do it for every appliance in the grid that was converted. So I agree that mixing hydrogen in isn't going to work at well. From a safety standpoint, like he said, hydrogen is notoriously hard to contain. The majority of the last mile of NG pipeline networks including almost all piping inside homes are mechanically fitted. (IE threaded and crimped.) I suspect that leakage rates would dramatically increase, causing plenty of panic. (odorization should keep accidents down but won't completely prevent them.) Some jurisdictions have extremely restrictive regulations. (Ontario, where I live, is one of them.) I honestly don't see the regulatory authorities moving any faster then geological speeds. For the electric heating, that is more of a problem for existing neighbourhoods in cold weather areas that use NG. Since the infrastructure was built with natural gas supplies in mind, electrical infrastructure isn't built to handle the full heating load on top of the normal peak loads. We would have to upgrade entire sections of the electricity grid along with additional power sources. That's considering heat pump usage. On top of that, heat pumps are much more expensive to repair. It's not a limiting factor, but something to consider. While they use gases that can be harmful to the environment, losses are extremely low in some jurisdictions and isn't really a factor. Side note : comfort heating is an essential service in cold weather areas. It very well can be life and death depending on the situation. Even Texas is aware of this now. After all that, consider that methane is most often a byproduct of oil extraction. There are some dedicated fields extracting NG, but it's not as common in North America. Burning methane is far better then releasing it to the atmosphere. The greenhouse potential of methane is far greater then carbon dioxide. Capturing methane from leaking fields will help substantially. Having a convenient way of consuming that energy is most efficient. (Although I still see NG volumes significantly dropping in hr future. Especially in places where it is imported from deep natural gas fields.)

this guy is so intelligible!!! he sounds super smart with great ideas our politicians need to listen to him. thanks for sharing this interviiew!

The other problem with Hydrogen and blending in gas supplies is cost. If done properly (using truly green hydrogen or blue with at least 90% effective CCS) the cost is prohibitive because of inherent inefficiencies. Hydrogen may have some limited applications but I believe it is being promoted by the fossil fuel industry to delay the decline in fossil fuel use and divert attention away from investment in other forms of energy storage that are cleaner, cheaper and more efficient. These include chemical and mechanical batteries, pumped hydro, compressed air, molten salt plants, etc. Electric vehicles for example have the potential to provide vast energy storage with Vehicle to Grid connectivity.

Great article. What was not mentioned was that we could use "green" hydrogen to make ammonia .Ammonia boils at -33OC at atmospheric pressure. World production of ammonia is 150 million tons per year. 18 to 20 million tons of liquid ammonia are transported by sea each year. Green ammonia could replace the present production of ammonia from fossil fuels with no major changes in infrastructure. Ammonia can be used as a fuel for marine and stationary prime movers. It is a far more logical fuel than hydrogen.

in New Zealand, decades ago, we piped Coal Gas into homes (it was hydrogen plus carbon monoxide) . When I was a teen they switched over to Natural Gas. In your youse, only yhe burner orifices were changed.

I was impressed by the comments starting at about 11:50 where Paul mentions over-provision of natural energy sources (such as wind and PV but also potentially tide and wave power) then storing the energy in the form it is initially presented by which he presumably means electricity using e.g. batteries. We could of course convert the energy into hydrogen or ammonia and store it locally to that conversion plant until it is needed to generate electricity when the wind doesn't blow and sun doesn't shine. This avoids the main problem with hydrogen - its transport.

Brilliant video Rosie! You're our dose of reality amongst all the hydrogen madness! That must have been such an interesting chat and I wholeheartedly agree with your concluding remarks.

The various grades of "Town Gas" types of gas from coal had hydrogen contents from 20 - 50%.

Hydrogen leakage could be enormously problem??! Since hydrogen is tiny and can be passed through even the smallest openings, this means that the leak already present in natural gas would be incomparably higher - and when you add 3/4 times higher pressure in infrastructure - the leak could create huge losses.

Perfect and practical analysis My opinion would be creating mini ammonia factory every where in each farm attached with solar panels And using it as fertilizer and fuel

Brilliant video. I'm looking at renovating a house and one option is to demolish and rebuild (higher quality walls & insulation), get rid of the gas boiler, and use a heat pump for heating/cooling (also a massive tax break for doing this as opposed to renovating). 12 months ago I was thinking that, given a large renewable overbuild, maybe SNG could replace fossil methane (renewable power and, instead of using batteries to store excess power, the UK has over 4 bcm, or 41.86 TWh storage capacity in the old gas pipes, which shouldn't go to waste). I was wondering about the idea of hydrogen in the gas pipes for the last few months, and now I think it's fossil fuel's last hurrah.

Very informative, Rosie! So far I'd only heard of mixing H2 into the natural gas grid as a way to find a use for electricity from wind, solar and hydro sources during periods of low domestic demand. At night for example, the renewable electricity would be used for electrolysis and the hydrogen produced fed into the gas grid. The 14% reduction in calorific value would not be welcome by operators of gas engines either. It's well documented that even without H2 blending natural gas quality can vary from minute to minute and even second to second, causing knocking and misfiring and potentially severe engine damage.

This is a real eye-opener for me. Quite a few companies are touting hydrogen as a real green alternative in the future, but it’s a tiny atom, hard to store, pipes keep leaking, it doesn’t give the same energy as natural gas, storing it under huge pressure can be lethal, just have a look at the bad experiences Norway has had with hydrogen. I’m hopeful many of the problems will be dealt with in the near future, our planet depends on this and every other measure to reduce the effects of global warming. This was a great video, very informative, very well produced and it certainly gave me lots to ponder over. Thank you Rosemary.

I think that Paul has a good point about focousing on the low hanging fruit like Ammonia production first. From there it seems to me that baseload powerstations could also start producing and storing hydrogen to sell to fertilizer manufacturers, blimp enthusiasts or others. They could produce hydrogen when there is too much wind, water or sun filling the grid supply. Storing the hydrogen deep underwater in balloons seems like a good option to me. It is ideal for seasonal energy storage

This channel is much better than those Have a Think about Undecided channels

There is also the issue of NOx emissions when burning hydrogen in an air mixture. Another pollutant for the atmosphere that never seems to be mentioned in the videos for hydrogen combustion engines such as those proposed by JCB.

I am surprised, given your background in materials and mechanical engineering, that you didn't discuss hydrogen-induced cracking (HIC) in existing pipeline infrastructure. Is HIC a concern?

A perfect explanation of why there is no such thing as a pure engineering solution to climate change, from an engineer in the industry. Climate change is about Political Economy, first and foremost.

When I was a kid, we had coal gas which I think contained hydrogen. I was mystified about this magic wand we had that lit the stove by inserting the end into the gas burner. When we converted to natural gas this wand didn't work. When I learned more about chemistry I suspected this wand contained a tiny wire of platinum or palladium which acted as a catalyst and ignited the hydrogen component. If hydrogen was introduced into the gas main such a wand will work again. Alas this was 55 years ago and I don't have this wand any more. Perhaps this is available elsewhere in the world which might have hydrogen in the gas main, be it coal gas or otherwise.

Great coverage of the topic, and very well presented. I'm really enjoying your channel, keep it up.

Great video, but I would have liked to hear Paul's view on the viability of using ammonia to transport hydrogen, both directly and indirectly someday? Which seems to address most of the issues of piping hydrogen by itself or with NG. Not really need now, but long term when it is, it seems like the the best option. Other than that Paul pointed out 99% the issues (including embrittlement) that I was thinking about prior to watching the video. Echoing Paul's line of reasoning. For now we should actually be focused increasing the use of NG, to replace dirtier fossil fuels such as coal. It's far more efficient and cheaper way of reducing all types of pollution, for now. And NG peaker plants are the best short term option for allowing great use of renewables such as wind to power the grid. NG should be the last fossil fuel to be replaced Strangely. Paul seemed to be wrong about one thing, that there are no costs (ie regs) on NG leakage. There have be for a long time and the allowed leakage was just readjusted down back Obama levels. Now we just have start to add cost for cow methane production (not a joke).

Great value in these videous....excelent. Great for ''low energy state'', when dry theory is not hard to consume, but want value from your free time actions.

Super video....definitely raises a lot of issues on the hydrogen/methane blending in the transmission/distribution systems.

Another problem with hydrogen could be that it actually acts as a greenhouse gas. Methane leaking from natural gas pipelines can easily reduce the climate benefit of making less CO2 per kwh than coal or oil. Hydrogen ( H2 ) is not itself a greenhouse gas, but it's almost inevitable that such a tiny molecule will leak more than CH4. Eventually the fugitive hydrogen will oxidise to water vapour, which would make little difference at sea level, but if a lot of it rises up past the tropopause to the normally dry stratosphere, it could trap even more outgoing heat than methane would. The H2O molecule is highly polar, and its vibrational modes absorb different wavelengths than CH4. Increasing its concentration at higher altitudes is like putting a thicker blanket over the earth. Hydrogen would also react with hydroxyl radicals, possibly increasing the average lifetime of methane in the air, and with ozone, weakening our ultraviolet sun shield.

Fascinating topic. Well done video. Keep making them!

Excellent, concisely communicated video! We need more presenters like you guys.

Canada’s gov. Is being lobbied into subsidizing blue, er, brownish, hydrogen. Mostly by fossil fuel investors protecting their investments. I’ll keep this vid handy for the next time I hear about our ‘hydrogen future.’ I like your brief point about keeping energy in its most efficient or harnessed form, that I’ld like to hear more about. Thank you.

Your best ever, keep it up! I thought I knew a little about this topic but I learned a lot.

Just a stupid question. How does hydrogen and gas compare to each other when it comes to explosive expansion velocity? The amount of air displaced or the weight it can push when it is ignited.

This is a very eye-opening video, thank you so much for making and sharing it guys. I still find myself wondering about using some of the existing network for applications where energy flow through the pipes is not critical, e.g. hydrogen filling stations. Hydrogen, or a synthetic fuel derived from hydrogen, are bound to be used in some hard-to-decarbonise applications such as aviation, shipping and possibly haulage, and any filling station is going to need to compress the gas or liquify it far beyond the energy density of what goes through the pipes. The situation I'm imagining is a site with some on-site electricity generation (e.g. solar PV panels), an on-site electrolyser that generates some of the consumed hydrogen, electricity and hydrogen gas feeds from the grid, a compressor/liquifier, a storage tank and dispensers. Depending on the state of the grid and its supply/demand, the hydrogen going into the compressor can come from the on-site electrolysis (powered by on-site generation and/or the grid) or from the gas grid. I can even imagine some situations where it might even be economical to put a fuel cell on site and generate electricity - naturally, the round-trip efficiency is lousy, but if the grid is not very stable an is in a serious dunkelflaute and wholesale prices are super-high, it might be worth it. I'm probably talking nonsense, but it seems crazy to me to transport hydrogen in cylinders *at all* when we have a piping grid in the ground already.

Power to methane is also an option. It is not very efficient but you can use power from production peaks (windy and sunny day) when power is virtually free.

Rosie, Many thanks for this interesting video on the problems of hydrogen. Mr. Martin believes that the way forward is to use and store energy in the form it is created. The problem for electricity is firstly that so far we have no commercial way of storing it, particularly over a period of a few days, and secondly the electrification of everything will be a mammoth task - a Cambridge professor of engineering has calculated that to electrify just the UK’s vehicle fleet will take the annual production of the World’s supply of Lithium, Cobalt, Copper etc..and the estimated cost to convert the UK home gas boilers to heat pumps and upgrade the National Grid is put at £300bn. I think a better idea is to use biogas - green methane/natural gas because (briefly) : 1) It can be produced with low technology everywhere in the World using anaerobic digesters working with food/human/animal waste - and with just grass of which we have plenty. A by-product is green fertiliser. It can also be produced using excess electricity from renewables (wind and solar) using hydrolysis to produce the hydrogen and using CO2 from the air via the Sabatier process. This process is helpfully exothermic and takes CO2 from the atmosphere, definitely a plus point. A by-product is oxygen, which is also useful. 2) The technology and infrastructure already exists to store, distribute and burn methane/natural gas to provide heating for homes (18m existing gas boilers in the UK) and cars/HGVs can be easily converted to run on methane/natural gas. Note that BEVs are currently unable to successfully power large vehicles such as HGVs. It is also safe to use. I would like to see please another video with Mr. Martin with his views on using methane. The hydrolysis and Sabatier processes may not be very efficient but does this matter if the electricity would be going to waste and the biogas can be easily stored/distributed/used?

Ohh this is very interesting. I want to add one thing: The existing boilers and burners used in the Netherlands have to use very low BTU (Wobbe index) gas, because the gas from our gas fields (particularly in Groningen and the North Sea which field are now nearly empty) is of very low caloric value and our network and machines have been built around this. So, if we import gas of higher caloric content, we have to mix in nitrogen to make the gas of lesser quality! I see a great opportunity of mixing in hydrogen instead of nitrogen in our use-case!

Great video. Agree completely in hydrogen blending issues like compressor station upgrades and embrittlement/leakage. Not sure how much lifecycle emissions are actually reduced for blue hydrogen because there are still upstream emissions for nat gas production upstream of SMR, even if there is CCS of CO2 from the reforming process

I'm wondering. Why put hydrogen into the pipeline? Is that using one fuel to generate another fuel with substancial loss? Why not put the wind/solar/other green electricity directly to the grid and use that for cooking?

Wow, Paul is great, like you.

Thanks for bringing up leakage. Wish you talked more about it and how the present system is not built ...the entire thing....for the small hydrogen atom compared to methane.

Excellent informative video Rosie. And Paul. Thank you. I believe some of Pauls conclusions are worth exploring with an open mind. But the difficulties presented for Hydrogen substituting into the NG network are considerable, and this is the key message that I found useful. Yes, I think embrittlement will be a very important piece as well. But also the ammonia aspect. there is much to unpack here. Distributed generation of hydrogen, and distributed storage of hydrogen, and many more. Storage at 700 bar is really not attractive, so ammonia, but yes, renovation of the Haber Bosch process - there seems to be some good developments in this area recently. My own interest is in seasonal storage. Solar PV is cheap now. But storage is still a big deal. So I'm exploring hydrogen production and storage for remote sites. We are talking about smaller amounts, so lower pressures, and perhaps ammonia will be involved. All the best to all the engineers here !

Brilliant, been wondering about the hydrogen excitement.... some very salient facts there. Thanks Rosie (and Paul).👍

Very informative, thanks for the vid.

How about using Hydrogen to (long-term) store excess Solar & Wind energy, a process that is easily reversible very inexpensively, safely and with relatively low conversion loss?

Thank you, Rosie and Paul for your thoughtful insights.

District heating is a good third option. Trained technicians can burn hydrogen for electricity and heat in a controlled location, and distribute the waste heat to surrounding buildings. Combined heat and power systems are already popular in some regions.

Very informative video and KZbin Channel 👍 A possible way to solve much of the issues addressed in this video might be the conversion of Hydrogen and CO2 into Methane. This can be done as a form of biogas upgrading. The CO2 fraction that is formed in biogas systems can so be removed resulting in a higher calorific gas and more gas. Methane has a higher energy content per volume then Hydrogen and can be used through existing pipelines. Interesting research articles about this subject are: Production of high-calorific biogas from food waste by integrating two approaches: Autogenerative high-pressure and hydrogen injection. (Kim et al 2021) Recent progress towards in-situ biogas upgrading technologies. (Zhao et al 2021)

Glad to see you making a good distinction between weight and volume. When I am talking to people about hydrogen this is a big point of confusion, because it has more energy by WEIGHT than anything else, volume is another story. However, adding hydrogen to methane is like adding ethanol, not water, to gasoline. The real value of hydrogen is large scale utility storage where it doesn't matter how big the storage unit is (Lake Meade is really big!), and maybe aircraft where weight is everything.

An excellent video, very good explanation why hydrogen is not really an alternative in house heating. As my favorite energy writer, Mr. Vaclav Smil said that the biggest problem with see with hydrogen is that we cannot use it incrementally. We have to replace furnaces, compressors, even some cases pipes in order to implement this gas, cannot really use a lot of things from the already existing infrastructure. Further problems like generating green hydrogen is also arising as it is currently a highly inefficient process with over 80% losses, while current technologies are based primarily on constant supply of electricity and stable current, which intermittent renewable energy cannot provide. Honestly I do not understand the stock exchange hype about these technologies.

I have seen this a long time ago, but forgot to comment. Another mindblowing video (Y) Super interesting! So relevant and yet not covered by the normal media. Dont want to say mainstream. Dont like the connotation the word has and associations it revokes. What i mean is, that this stuff might be covered in topic specific papers, but not in the media most of us consume.

Totally agree with Paul Martin on everything he said but could add a few more facts about hydrogen. It has a flame speed 10 times higher then methane 3 m/s compared to 0.29 m/s and as a result a much higher flame temperature 2250 compared to 1954 which leads to high NOx emissions. Also the ignition energy is only 0.011 mJ compared to 0.28 mJ for methane and explosive limits in air of 5 - 75%. compared to 5-15% for methane. Hydrogen is also very ight compared to air so will rise which is why it can be used relatively safely in industrial sites where it can be used and stored outside or in very well ventilated spaces with gas detectors and safe shut down systems

What we are missing is that it is really easy to turn hydrogen into methane if you have a source of CO2. Eventually it will make sense to keep the old refinery running. Install a CO2 scrubber to get CO2 from the atmosphere and use it to make feedstocks for the chemical industry. We don't just use oil for burning. We use it to make everything from clothes to roads to buildings.

Thank you Rosie and Paul. You've really hit the nail on the head, with all this excellent information. Now let's somehow convince the australian government to implement a carbon tax, a seemingly impossible task.

Excellent summary of the crux of the natural gas/hydrogen debate!

What about shipping the hydrogen as ammonia, if you could make the ammonia cheaper ,

Thank you, i work as a storage and compression technician for a gas company in the US im very interested in the future of natural gas and what that means for my job.

What about HHO mixed with air on demand on site. Would it work if the whole system was corrosion proof?

Thanks. Nice video. The summary at the end was very helpful 👌.

Here in the UK it is very common to have a 30kw combination boiler. These kick out a lot of heat instantly for showering. However when in heating mode they tend to provide a lower amount of heat. Would it not be more efficient to add a 3kw immersion heater to these. This would provide a duel fuel solutions. With clever controls we could use 10% elec when on full demand and 100% at low. This solution could soak up to 60Gw (20million homes x 3kw) of excess elec in the UK. Am I missing something or are we only allowed to pick solutions with Shiny slogans?

Hydrogen is extremely explosive and the Hydrogen atom is so small that it can pass right through steel pipes ! So it should solve the over population problem!

Great video. Both informative and entertaining. I agree with the many challenges of democratizing hydrogen in both methane blends and pure HP cylinders. It makes sense in a secure industrial context for steels, fertilizers, etc that need hydrogen feed. NOT for private cars parked inside buildings. Also, hydrogen is not « a plug and play » substitute for methane - you can’t even start-up many existing gas turbines with more than a few % hydrogen. You may need a separate start up fuel since the combustors are not designed for these flame speeds.

very nice balancing fuel saving and also no more polution by the system,

In Germany we already doing that and it WORKS! You have my subs.

Very good. I worked at PETROBRAS for my whole profissional live and for me H2 was a natural way to replace CH4 using the already existing infraestruture of natural gas pipelines. I was wrong unfortunately. But there is others means to store H2 using metal oxides em disc like kassets. I learned a lot about the subject of the possible application of the natural gas grid to transport H2, so thanks a lot.

Rosie, these videos are great, thank you, and keep them coming!

Great discussion and insight from an industry expert. It appears we are quite a long way from energy transitioning in realistic means. I have been looking closely at historical climate data over the past 4 years and honestly think the "crisis" part of climate crisis is way overblown. I wish this specific topic was explored with the openness that the challenges of green energy were discussed.

I think there are also some other issues with blending hydrogen. One is when you have cryogenic peak-shaving plants in the network. The peak shaving plant would not be able to liquefy the hydrogen due to its much lower boiling point. Also in storage tanks I think the hydrogen, being lighter will slowly separate from the methane so if the gas is standing for some time in the tank the hydrogen will accumulate at the top and the methane at the bottom. I'm not 100% sure about this as I don;t know to what extent diffusion would keep the gases mixed. A third issue I see might exist is the embrittlement of the steel pipes and valves by the hydrogen though I'm not sure if this occurs also when the hydrogen is diluted in methane.

Awesome video, such a concise and easy to understand speaker in Paul. Nicely complemented by Rosie’s segways. Top job, well done

Not only is energy per volume abysmal with hydrogen, but the hydrogen molecule is so small that the leakage problem will increase. You might could add up to 20% hydrogen at some point, but if the distribution network leaks the smaller molecules it won't be there at the customers' meters. You can synthesize methane. Maybe work on making that more cost effective and green.

Before we had natural gas we had coal gas, which was 50% hydrogen. I don't remember hearing about a lot of problems with sending this through domestic pipes and use in households. By far the biggest issue was the toxicity from the 10% carbon monoxide. I'm wondering whether the issues with using more than 20% hydrogen is overhyped given that we used to use 50% through the same pipes in older houses.

Very important topic for the UK at the moment looking into the near future. Hydrogen is the only half-viable alternative to heat pumps. Making it work on the existing gas grid infrastructure would have huge economic benefit.

Well summarized the real problems in the present world. Thanks for the great video.

The not yet mentioned is hydrogen with nearby electrical connections. This is class 1, division 1, very expensive, careful build. this video does mention not bringing this into homes. Hydrogen cars and trucks filling their storage tanks also have the need for fail safe connections.

I've only just started following Rosie and she is growing on me quickly. I also liked the neutrality of thus video. Just the facts. Hydrogen has a lot of potential but I see everyone latching onto it (a lot like CO2 sequestration) without considering all the facts. Hydrogen is dangerous, particularly in a domestic setting. It has no smell, burns with an invisible flame, leaks at high rates through the tiniest hole imaginable and is insanely easy to ignite. I can't remember why but it also causes steel pipes to develop cracks. I'm not faulting the article but these are other things to consider. We have to weigh all the considerations before latching on to this one like we did sequestration. See where we got with that one!

great vid. Informative and well presented. Really enjoying the content on your channel, Rosie. Cheers!

Great summary. Very useful.

8:40 Correct me if I'm wrong but while hydrogen molecules are certainly tiny, they aren't amaller than a helium atom. That's because a Hydrogen molecule is two atoms of hydrogen each with its own electron shells, and sharing their electron with the other, compared to helium which is one atom with one electron shell and two electrons in that one electron shell.

Can gas turbines be adjusted to work with natural gas/hydrogen mixes?

Hydrogen is so incredibly leaky. Able to leak through things and through any joints that don't have a perfect vacuum seal. Natural gas infrastructure is already notoriously leaky. We frankly would hardly be able to hold hydrogen in our pipes in any building as far as I am aware. I feel like electric is the best way to heat things in the home and cook, because it is clean and safe. If we make hydrogen for power keep it at the place it is made and maybe just use it with hydrogen cells when electricity is needed.

Every dollar currently being spent on developing a "Hydrogen ecconomy" is a dollar wasted. We should be concentrating on what we know actually works now. We have to move so quickly on this.We have to reduce our consumption, build more wind solar and tidal power, and we have to build more storage batteries, pumped hydro and others such as liquid air and flywheels even. If we put all of our efforts into these technologies we could end 95% of the CO2 emissions and quickly. We don't have time to waste on dead end stuff like hydrogen, no matter how exciting it may seem.

Congrats on an excellent interview. I'm all for reducing carbon emissions, but it must be done in a realistic way. Unfortunately, proposals like the Green New Deal are severely lacking when it comes to this kind of engineering realism.

Excellent explanation on why Hydrogen will never work for heating or transport for that matter. Zero point in using Hydrogen for heating when you create it with electricity, far more efficient just to use the electricity resistively, better but more expensive to use heat pump. Heat storage is the new kid on the block using excess renewables in a renewable over capacity world. Concentrate on insulation first to reduce natural gas heating, while building more renewables.

Thanks Rosie, nice video, i got a lot of questions answered

I have heard that hydrogen would just leak out of a natural gas pipeline. It was noted how much it leaked, but did not actually say it could not be used in the existing pipelines.

Hydrogen is best stored in ammonia or methanole, where it can be transported and stored easily at quite low pressure.

The critique of hydrogen centers around that it is tough and expensive to pipe hydrogen with the same energy content as for natural gas though a network designed for NG. However, we won't need to, reduced energy value is fine. In the UK for instance most heating both industrial and residential is currently done with gas, with the (costed) plan being to replace NG with hydrogen produced from wind turbines. But to hit GHG targets, everything from house insulation to heat pumps and loads of other tech will be needed. So the demand for a straight replacement of NG with hydrogen will not be there, and reduced volumes for which a strategically but limited upgrading and reinforcement, notably in storage, will be needed will cover the volumes needed just fine.

What about this? 1. Subsidize the bejeezus out of everything green hydrogen to make up for the inefficiencies. 2. Use distributed renewables (on buildings/property/land of all kinds) to generate a ton of excess energy. 3. Send the excess energy to a neighborhood green hydrogen electrolysis, compression, and storage facility where it can be accumulated for literally months if necessary (unlike a battery). 4. When power is required, use a fuel cell to convert the stored compressed hydrogen back to eletricity and send it to the grid for distribution. 5. When the neighborhood hydrogen facility is full, the utility can sell the excess to hydrogen fueling stations for vehicles (a proven technology) distributed locally via hydrogen fuel trucks. 6. Upgrade the electrical grid to a smart grid that can better integrate the neighborhood green hydrogen facilities into a robust network of on-demand stored energy. There's no shortage of energy if subsidized renewables are placed everywhere. Over time, it's easier to make too much renewable power than not enough. There's no need to keep compressed hydrogen in the home if it's kept at a local but sizable facility. There's no need to complain about cost with a fat subsidy like we did for decades with fossil fuels. We have all the tech already.

Gee, as a professional economist it is nice to see people getting the point that if you want less of something TAX THE BEJESUS OUT OF IT. That sets the incentives for all those incredibly smart engineers to not only change existing modes of productiuon but to invent all sorts of other modes that regulators with their quotas, bans etc can never hope to think of, let alone enforce. The great virtue of markets is that if set up properly they harness human greed to useful human ends - and getting the (post tax) prices right is the biggest step in setting them up properly.

Thanks for highlighting these points 👍

I believe Worcester Bosch 8000 models can be or are already Hydrogen ready whilst burning NG at the moment

Hello Rosie, I really like your videos, the subject was touched briefly, but why cant we burn nat gaz to produce electricity and collect the co2 emissions at the source. How big would be the commercial loss for that. It could work for any kind of fuel that we burn even coal (we would need to take care of ther emmissions as well)

Hindenburg....gas company intentionally mixes more Hydrogen into the gas supply and BOOM goes the CITY!

It's not a silver bullet but a 7% reduction in natural gas CO2 emissions, combined with less natural gas use in general, would be a great improvement.

Ammonia has 3H and 1N atoms and is already transported widely all over the world, Methanol has 4H, 1C and 1O. and can easily be transported just like ordinary gasoline and distributed at ordinary tankstations.

Nice video! Thanks! I also appreciate you moving away from the camera a bit. The screen felt a little crowded otherwise