Do Droughts Make Floods Worse?

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We found out, during our midwest drought this summer (which is still continuing), that 3" of rain in 44 minutes will "outrun" the soil's ability to absorb it, regardless of how thirsty it is! It did top up the swimming pool ... and flooded the basement.

Not to forget, dry areas with fewer plants will make the soil less porous, because there are fewer plant roots. So while the dry top layer can absorb more water, it can't transfer the water down deeper as well as soil with regular moisture that has more plants with roots all over the place.
It's a well known fact plants are great for preventing soil erosion. And that's related to permeability and other similar things.

As a gardener my theory on the hydrophobic nature of dry soil what I've noticed is when soils dry out they tend to compact and become less poros. In addition there tends to be less roots breaking up the soil further increasing its density. As water soaks in the soil tends to open back up.

A factor missing from the demos that may account for some of the differences is soil compaction. Soils in long term drought conditions get packed more tightly which I would imagine slows infiltration. It is intuitive to think about when you consider how much softer the same patch of ground gets when it is wet, there is more open space for the particles to move around in. Recently dried soils will retain some of those gaps until they settle down packing more tightly leaving less room for sudden rainfall.

I think it's also important to highlight the difference between an areal flood and a flash flood - hydrophobic ground conditions in drought-impacted areas can lead to more flash floods as water slides across the ground surface instead of absorbing, while moist ground conditions can contribute to more areal floods.

I think one important thing to note in the viral cup demonstration is the fact that no bubbles were rising into the cup on the dry soil. The cups on the wet soil were letting in air from around the base which bubbled up into the cup and equalized the pressure above the water, whereas the cup on dry soil seemed to be forming a partial vacuum above the waterline inside the cup. This partial vacuum may have inhibited the water from seeping into the dry soil, slowing its absorption into the ground below.

That was a fun video. Watching the three cup infiltration demo at the beginning I wondered if some of the water in the glasses was not even making it into the soil because the cups were slightly suspended by the grass. I appreciate your garage demos to help visualize the effects.
I agree about the tremendous impact of soil types. I grew up in the Chicago area with a lot of clay soil. During droughts our yard turned into "concrete." Now we live in southern NH with very sandy soils that water percolates through quickly. We have a small stream on our property and it is fun to watch the flow change during rain storms.

I think the biggest effect in the original demo is the fact that the edges of the cups are resting on the grass blades, leaving lots of spaces for water to leak out between the cup and the ground. Well-watered grass would be a lot thicker and springier than flat, dry, dead grass. It was the first thought I had when I first saw the demo and immediately dismissed it as useless.

I really like that 'all models are wrong, but some are useful'
Any model will neglect some small effects, but they manage to show the larger picture.

One of the things I learned about in my 2nd year Environmental Hydrology class was the massive effect fire has on the interaction between water and the soil. Especially in Australia, wildfires and burnoff will combine with the high oil content in Eucalyptus trees to form a barrier to water infiltration on the surface of the soil, significantly exacerbating runoff and worsening flood events.

Drought state gardener here. The tube demo adds water pressure as a variable, which does not reflect IRL semi-arid conditions. A pressure gradient helps overcome the hydrophobic conditions of the surface soil.
My area is Holdaway silt loam soil, high summer temps, and 10% humidity. Our surface soil desecates quickly, making it hydrophobic most of the time. Summer rain is usually intense thunderstorms, so .5to 5 cm of water in under half an hour. In those conditions, you can dig into the soil after a storm and find runoff happening on soil that is barely wet 5mm down. Even puddles drain slowly as the infiltration rate of native soil can be 1mm per hour.
Slightly wet soil absorbs water much better because the wetted soil breaks the surface tension of the water, allowing it to flow in via capillary action.
Easy experiment to show this: pack potting soil in a clear tube with holes and float it on water. The soil may not wet, even after days of floating. Potting soil must be wetted and mixed before using it to start seeds or the hydrophobic nature of the potting soil means some cells of the germination containers will hide pockets of desecates, hydrophobic soil.

Writing from Australia here. Our land definitely gets super hydrophobic during the droughts. We had just as intense flooding during the dry years as well as the last few La Nina years.
Really seems to matter how much vegetation and organic material there is on top. Exposed soil gets baked in the sun.

That original video had "air tight" dry grass vs long grass blades making the containers not air tight air rushing in, that's the biggest difference of the original video, he did not consider the air intake from the bottom of the glass vs no air intake on the dry grass.

Your ability to explain complex things in a clear way is top tier.

packed clay heavy soil becomes somewhat hydrophobic while dry. In areas where the rain only lasts for short amounts of time the rate of runoff outpaces the initial absorption rate. That's why flash floods are a problem in places like southern Utah, our soil is rich in clay that has baked in the sun. The occasion where we get a long running slow rainfall is practically celebrated because it means the rain has a chance to start saturating soil before it turns to runoff.

This is an important consideration when determining the irrigation interval and volume for a clay soil. Dry clay doesn't want to take water, but once it gets wet it holds water well. Most watering advice says to water deeply and less frequently, but when dealing with clay it's important that the soil remain damp so the first few minutes of watering don't try to run off. It's a tricky balance. That or the soil needs more humus, small aggregate, and possibly a surfactant to aid water retention.

I was first introduced to the idea of infiltration when my father did percolation tests to determine how large a leech bed was needed for a septic tank system in the flood plane of the Ohio River. The humus layer was very thin, less than 2 inches in most places, atop a substrate of layered alluvial clay with almost no aggregate, pretty much dense yellow clay as far as a core could be drilled. Memory says they stopped drilling at 60 feet. The percolation test results were not good. The engineer my father had hired did the math and came back with a dire face, telling my father that he'd need to buy more land to fit in the right sized leech bed for even a modest septic tank system or build a small water treatment system that would need regular service. I can't say I was surprised by this, because all while the house was being built, I had seen even a modest rain shower left the soil around the construction a muddy, sodden mess until solar evaporation dried everything to a flint hard mass. Fast forward a year and my father was suing the land developer that had sold him the lot. So, thus was I educated to the reality of soil infiltration.

I don't know why, but Grady is one of those youtube personalities that I just find so calming after a hard day. Maybe it's the quiet voice, or the smile, or the chipper tone, or the enthusiasm for the subject matter. And of course, I always love watching the water flow through the clear plastic devices. Thanks Grady.

I live in Southern California, where it usually doesn't rain for six to eight months out of the year. Our soil dries out to the point that it is difficult to re-wet. At the first rain, we are all hoping that the first storm will bring a slow, gentle rain that re-wets the soil. Our clay soil acts more like a sponge, where a moist sponge will absorb water more quickly than a dry sponge. That's why you wet a dry sponge out and then wring it dry before using it. Fires or not, the first rain of the season is cause for worry. Take care.

The footage of a microburst being overtook by an haboob @ 3:54 is amazing. Both are common in southern Arizona. I lived in the Mojave Desert for a couple decades and can attest to the hydrophobia of caliche soils. Clark County, Nevada, where Las Vegas is located, has invested billions of dollars on hundreds of miles of flood mitigation channels, not always with success, as recent events have greatly illustrated. Thank you for another illuminating video, Grady!

I thought the reason the really dry soil was slower to absorb water was more to do with compaction than being hydrophobic. I figured when the soil dried out, that exposed many "pockets of air" (which may have previously been occupied by water), which then allows the soil to settle (light compaction). Then when a large amount of water is applied to the surface, it is harder for the water to penetrate the more tightly compacted soil.

I think the type of flood we are talking about matters. Very dry conditions can cause unexpected flash floods even with relatively little rainfall, especially if the terrain favors accumulation. And, loss of plant/root mass and soil cohesion due to a long drought can make mudslides more likely or severe, too.

"All models are wrong but some are useful". That's an intriguing quote.

During the 3 inverted cup demo, the thing that I noticed right away was that more watered grass seems to lift the cup a lot more than the dry dead grass, and that appears create a larger gap for the water to escape and crucially for air to flow into the cup. This would have a huge effect on the speed that the water can escape the cup. That demonstration really doesn't say anything about how quickly the soil is absorbing water since it could just be flowing away.

In arboriculture, we use surfactants to help water get into (and out of) clay soils

This was an interesting video. The way it was explained to me is that dry soil condenses making it more difficult for water to get into the soil but I guess that would still absorb more water than when the ground his waterlogged and the water has nowhere to go. Maybe it's because I group in an area with soil that contained a lot of clay so, during the drier months, trying to dig was like trying to break through rock.

Great video! I grew up out in west Texas, dry as a bone most of the time, and the worst flash floods were almost always the first few in the autumn after a hot dry summer. I remember older folks around me pointing out how certain areas in the city were getting very dry (reasonably enough, all of them places with no automatic watering for lawns and so forth), and predicting that Wadley Avenue would flood (again). That street was infamous for it, but it was SO consistent that folks could just about judge the severity of the weather by asking if Wadley had flooded. I couldn't tell you, all these decades later, whether those extra-dry areas were connected to Wadley Avenue, but it wouldn't shock me to find that they were. But thunderstorms out west are frequently very intense at the start - gentle rains that go on for a day just aren't all that common - and MOST of Midland's infrastructure was built to handle such flash flooding, because it's just that likely that a big cloudburst will dump half the year's allotment of rain on the city, all in the space of thirty minutes!
Also I'd like to say - I appreciated that bit of humor. Bringing down a rainstorm at will would INDEED be a "ethically gray area," haha!!

I really like that melody right after the intro; it always sets the stage for an interesting episode.

"Even if they could, it would be an ethical gray area" - gold writing

Hi Grady! I've been watching you since your very first few videos - you really caught my eye with the automation systems in your garden. This channel has grown into a level of educational value and professionalism beyond many college classes. You're at outstanding example of engineering and a credit to us all.

Here in Arizona some of the worst flooding seems to be at the beginning of our monsoon when the ground is the driest. I've always understood it was from the ground having a hard crust on top that prevents the ground from readily soaking up the rain. It'll be interesting to see if what we've been told holds true in the video!
Edit: So the answer is no, bit maybe yes! LoL I love that you did the experiment with the hydrophobic sand as that is a really good analogy of the Arizona desert topsoil. As a kid playing with the hose out back I always marveled at how much slower the ground absorbed the water when it was really, really dry during the summer.
This seems like it would be a good graduate student project. Collect soil types from around the country and try to figure out a reliable test to figure out which regions will be most affected by drought vs super drought. Especially with the fact that rain patterns are changing over many areas we humans have populated.

I always thought that dry clay (especially in the dust form) is hydrophobic. I felt that a number of times when I water the garden. Adding some good amount of mulch on top of the soil made the run off significantly less, though.

I have had experience with this I emptied a drum of wash water on cracking clay and 120l of water disappeared in seconds but have often seen water run straight off sand.Water repellent sands are common in Perth .

I love how civil engineering through this channel explains truly fascinating mechanisms and structures. Answering simple seeming questions with the complex truth of the real world.
My granddad was a civil engineer, and while I didn't know him very well, I love learning about the field he dedicated his life to.
Thanks for your content Brady, you make civil engineers and educators proud!

the video with the upside down cups is so silly, the ‘very wet soil’ has way longer grass which just lets the water run out the bottom of the cup whereas the dry soil is basically a flat surface so with the surface tension of the water it is ‘sealed’

Grady, I love your videos. In the West, where clay soils go dry they take time to re hydrate. An agricultural engineer I once knew always talked about losing hydraulic conductivity, and how important it was to keep soil watered.. When the clay soils are dry, there is no capillary action to help pull water down..

Here in the Netherlands this is a very known thing. Flashfloods happen nearly always after a draught, especialy in the area I live in where we have sandy soil. After a draught the ground is rock sollid and doesn't absorb any rain for quite some time. Enough time for large flashfloods to happen. For this it is important to keep the soil water level as high as possible and to create as much shade as possible to limit evaporation during a draught.

I just installed a drywell in my backyard to disperse water from my sump discharge, all this discussion of soil water absorption is especially relevant to me right now. Thanks for the clear explanations!

"If I'm curt with you, it's because time is a factor."

I'd love to see a part 2 here that includes the effects of clays. Seeing loose soils and sands doesn't seem like what is present after a drought, as lack of vegetation can mean that soils have eroded away. Like the shot you showed in the desert, I'd be expecting hard packed earth, not loose sediments easily infiltrated by water. I'd be curious to see if the topsoil is even of the same content after a sufficient drought.

I remember my 5th grade teacher telling me Arizona has this problem... He says the ground gets too dry so when it does rain, it doesn't get absorbed quick, it just pools and creates a flash flood...

Thanks!

Great video, I work with peat moss, the stuff absorbs LOTS of water, but when dry it's almost impossible to make it absorb water; water runs off it and/or peat floats on top. My real life experience with water absorbtion

I love your videos in general, but this one especially. The answers to so many things in this world are often not as simple as people want them to be. Exploring the complicated answers is so satisfying.

Interesting video. I’d also suspect that extremely dry soil that has become compacted would also soak up water slower. We’ve been in and out of drought conditions all summer and thankfully have avoided serious flooding after a few big storms moved through. The minor low land flash flooding that occurred isn’t uncommon and pretty much expected after that much rain moved through.

Thank you for adding subtitles, I can’t hear that well because of a ear problem I have and it’s really helpful when someone add subtitles to a video 😊. Also the video was amazing❤.

I think you missed 1 type of soil conditions that often occurs with droughts and clay-like soils that are bare. That is the kind of baking or tile forming on the top soil. The really fine clay closes off the underlying clay from absorbing the moisture and thus essentially creating a barrier for infiltration. If there is a sudden downpour, the clay will not absorb any moisture and thus causing a flood.

The shot of the clouds dumping rain at 3:54 was friggin awesome.

I just love this channel. I’m a journeyman electrician by trade and run work in northwest Pennsylvania . my trade was nothing that motivated me till recently. Practical engineering is a something i look forward to when something new is posted . Appreciate the content Grady

Anyone who has made pour over coffee knows you have to add a small amount of water to allow the grounds to bloom (saturate) for a short period of time, before beginning the pour over process. Consider this as a model everyone can relate too.

Type of plant cover really changes the dynamics of soil and its abilities to absorb water. Gabe Brown is a farmer rancher in ND that tells story of an 11 inch rain event happening in a matter of 12 hours that was absorbed by his cover cropped land with no runoff and the field was drivable the next day. The roots and soil aggregates created by the fungus and microbial life have so much bearing on how a soil reacts to water. Nature's engineering would be a neat video Dr. Elaine Ingham and Gabe Brown have much to say about it if you decide to do a video. Their are others of course I just can't recall their names. Thanks!

In horticulture, where we mostly use nearly pure peat, dry soil can be a serious nuisance. You can water pots with dry peat for minutes and it will only penetrate a few millimeters. It looks soaking wet, but water just runs off at the surface almost completely.
The typical solution I've encountered in most places I worked at was to use tables that are build like big tubs, so you can flood the whole thing and leave the pots standing in the water for hours. The pots will eventually soak up water through holes in the bottom.
Though there are specialized chemical agents that can be mixed into the water to improve its ability to penetrate dry peat.
As I understand it, the effect is caused by air in the small empty spaces between the various soil particles. In many soils, these gaps are so small that the surface tension of water keeps it from squeezing through the narrow openings. If there is already moisture in the soil, then the surface water can link up with it and the water surface is broken, allowing it to get soaked up.

Really good discussion of how all of the variables (some of which are almost impossible to define) make outcomes appear to be "not logical". I spent over 40 years wrestling with this in my career as a mechanical engineer...and I didn't have to deal with rain absorption in soil! Here in California we deal with the layer of a fire-scorched earth crust every fall when the rains start. These processes are simply a part of our natural environment.

I think another factor for hydrophobic top layers is clay content. Having worked drainage construction in the Pacific Northwest, I saw this commonly.

I live on a property that floods - sometimes seriously, but every year I see this effect. My hill has loamy soil that absorbs well, the lower area is very clay heavy. During a drought, the clay becomes like concrete, and if it rains on top of that, the water goes nowhere (except the mole holes). Then in the rainy season it hits a saturation point where the water just doesn't absorb any more, and I get ponds all around my field that won't absorb into the ground for days. It's like a shammy cloth - dry doesn't absorb anything, saturated doesn't absorb anything, but damp absorbs a lot.

Hi Grady! Love the content as ever! I have a video suggestion 😊 the UK government has shut all school buildings that use Reinforced Autoclaved Aerated concrete, after a collapse of concrete previously deemed safe.
I'd love to have your take on the engineering side- what is RAAC, why was it thought safe, what changed and why is it now an issue?
Thanks!

10:55 I got two yew shrubs in my yard that have been there for about 15 years. I've noticed that the surface sand under the shrubs from the trunk to the dripline becomes hydrophobic if it hasn't rained in a while. When I spray water on it, it beads, and even when I soak it it stays dry. It definitely reminds me of that "Magic Sand" stuff that I used to play with as a kid.

This happened in British Columbia in 2021. After a summer of extreme heat and fire, those same areas so affected were stricken with massive flooding the following November due to warm, wet air (an atmospheric river), bringing in large amounts of heavy rain.

10:40 I have encountered hydrophobic soil in the Sierra Nevada mountains at Moraine Lake. Rain was pouring down, but the water ran across the surface of the dirt without wetting it; just sort of shiny and silver on the underside of the little rivulets of water. Absorption in that circumstance is zero.

I think one of the things potentially overlooked here is the way in which your models were carried out. Rain spits on the ground, it doesn't create a volume above the ground like in your example. Like you said in your video, some plant owners choose to submerge their plants rather than sprinkle them in order to water them properly.
You can even see this phenomenon on sponges. Sprinkling water on a bone dry sponge will not initially absorb water very well compared to a slightly damp one, but if you submerge it I doubt you would see much difference.
In your models you've submerged the ground with water rather than trying to simulate rainfall. Floods also don't usually occur because the dry ground got oversaturated and became submerged, usually they occur downstream because upstream they weren't absorbed properly. This make sense if the upstream ground is bone dry and was not able to absorb the water, so it simply flowed downstream causing the flood there instead.
If you want to correctly determine whether or not it increases flood risk would be to add that variable of allowing runoff, water that wasn't able to be absorbed before it flowed downstream.

Another great video!! Good job! A couple of additions to consider. Capillarity is one. Clayey soils can be hydrophobic initially after a severe drought for extended periods. This is due to their capillarity. It pulls the soil tightly together. As you mentioned hydrophobic soils are relatively common post wildfire. Duff builds up in soil - leaves, needles, organics in general. When it burns a waxy substance is released which penetrates a few inches into the soil. It's like putting a sheet of plastic over the soil.

A problem with the first demo (cups) is the airtightness. In nature, there is nothing like that - it's "open" to the ambient air pressure. So the one on the "dry" sand would permit the least amount of air to enter the cub at the rim whereas the grass leaves plenty of gaps.
Solution: put a small hole at the top to let air in (a few mm across will do) - or do the experiment as Grady did it (tube driven partway into the ground).
As to impermeability on the surface, you can see this in some soils after a hard rain - they form a sort of hard shield or shell that is much denser than the soil below. It eventually soaks up some water (possibly from underneath) and reverts to its former self.
As mentioned in the film, all sorts of "biofilms" will repel water.
Good video - as always!

Paused at 1:07 to say out loud "I'm Grady and as a civil engineer with an absolute love of geotechnical engineering, THIS IS TOTTALY MY JAM!" :D

This reminds me of some work going on in montana building artificial beaver dams to better retain water up near the snow bank and has reduced a lot of dry summer issues.

I love it whwn u show a "complicated" formula and its wayyy simpler than anything else i get given daily by some lecturer who hasnt spent a sing day doing anythubg outside of acedemia

Nice video Grady. My experiment is far from rigorous, and you did a great job of doing it far better and yet still visual. The effect of hydrophobic surface seems to occur in most natural soils, as you say once its overcome, infiltration starts. It's why the drought increases flash food risk, but has little impact on fluvial floods.

Not gonna lie...when you mentioned "I used to sit on," I was like..."wait, does he still work?" So I checked subscriber count. You don't push adds, so you're essentially on AdSense, but still...I didn't expect you to have ~3.5m subs. That's more than SO many bigger-scale channels! MAAD props. I still love it when I see real amateurs/indies making videos, even if this has become your full-time job. So many large-scale videos have massive "teams" and researchers and editors and licensers, and so on. But like ElectroBOOM, it's always refreshing when I see a creator who you can tell is just someone rolling their own videos, while maybe leveraging some "services," but mostly a full DIY approach!

Before watching this I’ll put a hypothesis in. I think dry ground would absorb water more slowly. I think this because as soil dries out it settles more under its own weight not having to make room for the water that usually inhabits it’s myriad of gaps. Then when water is reintroduced it has to force its way through the gaps, and the path of least resistance is to just pile up or run downhill

This is really cool, thank you for taking the time to make a covey explaining how you did that and what everything was. Keep it up, you def deserve more subscribers

I've always been told that the worst times to get heavy rain are when the ground is bone dry or water logged. I think the biggest factor is a large volume of rain in a short time

13:48 that exactly my experience with dry soil. You can turn your sprinkler for up to 4 hours and even see puddles but if you dig a bit you will notice that soil only wet for the first 2-4 cm and than it's completely dry. Things goes completely different if you have a lot of green grass. That not because how much water is in the soil it's about how many micro cracks it have due to rich vegetation. No vegetation no roots no cracks and so your soil became like concrete.

I always thought it was this: Soil contains more than just sand. And water does more than just seep through. Some material is like a sponge and swells when moist, some material clumps together when moist. Bigger particulates leave more room for water to flow, so if a draught causes the soil to compact, then it would be a logical conclusion that it slows the absorption of water. I also notice this with my plants. The soil level goes down and when properly watered it will sometimes rise above the normal level (and fall on the ground) due to the roots taking up more space than when I potted the plant.

This is why I love my smart timer for my sprinklers, it only waters based on the estimated soil moisture and it factors in rainfall, when it does water, it goes in multiple short waterings to maximize infiltration and minimize runoff. MUCH less water wasted to keep my lawn alive.

A very important variable that's missing here is how compressed the soil is. For soil that sees a lot of traffic (by foot, automobiles, farming equipment, etc.), long droughts allow the soil and any dead vegetation on top to compress far more than it would if it were wet.

completely agree. It is necessary to preserve not only water, but also all natural resources. Protect and multiply.

Wrong experiment at 0:39 min, all surfaces should have been shaved properly to create equal pressure.

I love learning about civil engineering because of your channel. Yay for more.

Question: In your experiments with the hydrophobic sand, did you ever try just leaving an inch of water on top of the sand to see if it could penetrate through the hydrophobic layer? It seemed to me that the added pressure of many inches of water helped it penetrate the hydrophobic layer. But in arid regions, you might only get one or two rainfalls a year and they may only have 2 inches of rain. I know this isn't related to flooding per se, but it does affect plant growth and the desertification process.
In some areas (I'm thinking of Somalia in particular), it rains quickly and briefly, but the soil is hard, (probably hydrophobic) so it doesn't penetrate deeply and runs off into dry riverbeds and out into the ocean, and the soil doesn't retain the moisture well even though the soil hasn't seen rainfall in 9 months.
I'm trying to think of practical, low-cost, low labor, ways to address this issue.
I hope you or someone with some idea of water engineering is able to reply to this comment.
Thanks,
Brant Erickson

Im in Education as a building material inspector in geology and I work for a company that, amongst other, monitors the building process of Landfills. And we determine the specific k value for probes of the coverage or the ground base of the land fill to see wether they have the correct value. Other as in this Video we don't want the water to soak in as easy as possiple, we want to slow it down as much as we could. To see it in other areas of usage is really cool.
Greetings from Germany

Ive been loving the disaster analysis and the engineering in plain sight series, but this is a wonderful return to just asking nerdy questions. I feel like a follow up video could be an excuse to return to the stream/river research institute.

I remember that drought. The temperature where I live got up to 49 degrees Celsius and fires started popping up everywhere. It was raining ash here like a snowstorm and the clouds of smoke were blocking out the sun and turning the sky black as night. Then the skies opened up afterward and the lower mainland near Vancouver was hit with a devastating flood that killed people. Not a good day for them.

Only a minute in as a type this, but this is incredibly true in potting soils. Most big brands will add a "wetting agent" into the ingredients to avoid this, but it stresses out a lot of growers who mix their own potting soils or buy ones without the added components. It has also killed A LOT of plants.
Using Walmart as an example. If i see plants that are wilted and sold at a lower value and it is one i want, I'll check the roots. If the pot is dry but the roots are healthy, a good soak will fix it. Otherwise, root rot is also very likely. People do love to overwater and the waterers probably think that's what they are doing.
What happens is that the potting soil becomes very hydrophobic as it dries out. People water the soil and see water coming out of the bottom. They think the plant has been well watered. But nope. The water went around the potting soil, which also contracts, down the sides of the pot, and out the bottom. Can only be fixed with a good soak by placing the pot in a bucket.
So mant of us have too much peat moss in our soil mixes. Need other components to keep it porous.

We had a gravel pitch for sports at the first school I went too. Turned out to have a lot of limestone and quarts in the gravel mix, with gneiss making up the other roughly 60%. Over a 30-year period, as rain dissolved the limestone partially and the constant games played on the gravel during PE and recess, the bottom 37cm out of 40 had turned into a lime-and-crystal rich clay-y substance. It was extremely slow to dry due to it's density, but said density also made it have a very low saturation threshold. The mineral mix also meant that, once the top 1-2cm had dried, it was like a lackered coat, taking up to 3h for the caked lime to dissolve enough to even let water begin to seep through. Lead to some pretty cool ponds forming, and as the gravel pitch was raised about 150cm above the rest of the school in a divet between two hillocks, me and the other lads would use sticks, stones and anything else we could leverage, to dig small drainage canals for the water down to a stormdrain.

Bassendean soils here in Australia often get hydrophobic. My backyard soil, which is characteristic of the Jandakot region, remains bone dry besides a thin surface layer, but despite that dryness it also drains quickly.
I know this due to recently trying to pre-soak soil to put in a couple of endemic shrubby plants from a lot that was being renovated (the owner let us dig them out) and after ten minutes of thoroughly wetting the whole area a shovel turned up bone dry soil less than an inch beneath the surface. At that point we just went and got some native potting mix and dug a great big hole to fill it in with.

Great video!
I will observe that the original viral video is from a clay soil area in the UK. Usually the ground is at least a bit damp, but a long summer drought can bake it into a hard packed, almost brick like surface that water does not like soaking into.
A sudden summer thunderstorm can run off that pretty well, and cause localised flooding in excess of that expected from the precipitation.
Certainly the flooding from that is likely to be less extensive than a big winter low on top of saturated ground.

I was sad you didn't mention clay. I happened to start a new garden plot this year in a spot with very high clay soil and a stubborn quantity of rocks (~1" diameter). I started tilling it by hand and decided at the half way point to simply take half of the plot down about 6" to replace with top soil & mulch. So I've got half a plot with clay/rock and half a plot with nice top soil.
Watering daily, each half is very different. The clay side sets almost to concrete when dry (90F + 20% humidity doesn't take long to dry; especially when water absorption is so slow to start)--puddles form after watering for just a few seconds. Watering continuously creates streams that simply flow to the lowest part of the garden. The other side of the garden, rich with purchased topsoil, can be watered for 30 seconds continuously with puddles only just barely forming by the end. I haven't the patience to wait to see if it will eventually form a river the way the other side will.
A side effect of this is that the clay/rock soil doesn't support as many plants--only specific ones survive and tend to grow very slowly. Ironically, leaving the lawn in place would have prevented this drainage problem--the grass roots kept the top clay layers loosened up and shaded.

I haven't touched HEC-RAS or HEC-HMS in a few years but when I saw the CN table I knew that had to be coming. For as long as that software has been around it still does a very good job of estimating runoff and its nice and simple to use.

We experienced this at a campground in Germany where no rain had fallen in a long time. The ground was dry and dusty and the grass wasn't green and healthy. Suddenly a shower of torrential rain hit and the water stayed on the surface and rose to above our ankles in the deepest areas. Luckily our tent was pitched on high ground. After a while, maybe 20-30 minutes the water was all absorbed and we had no further problems. I suppose that this is similar to clothes in a washing machine and the presoak program, it takes a while to get the absorption started and wet the textiles properly.

I work at a garden store. When I water plants I always do a light soak if the pot/hanging basket is super dry and light. I can definitely speak to how the soil can be hydrophobic. If you just soak it the lighter parts of the soil and fertilizer will float and flow out of the pot/basket.

I know that's not the focus of this video, but the shot at 2:47 is absolutely gorgeous!

This video was fantastic and perfectly timed. I’m going to give a bit of context below as to why because this video contextualised some important concepts for a project I’m now involved in.
I’m studying to be an industrial engineer and recently, one of our modules gave us a multidisciplinary project. We were assigned groups randomly and my group is now comprised of 2 mechanical engineers, 2 computer engineers, 1 chemical engineer and myself. Our group received a civil engineering project 😂. It so happens to be on flooding. Moreover, flood management when on a very stringent budget. Understanding soil composition and how it can either help or worsen flooding is definitely going to be a part of our project proposal.
I hope you wouldn’t mind if I use your video as a reference in our project. Mostly as a starting point to a deeper understanding on this topic but definitely as a starting point. We received the project brief 2 days ago so it’s still very early in its development. So I’m well aware that more will need to be done.
I’ve been following your channel for about 3 years now and I’ve always enjoyed your videos. They give a short synopsis of a far bigger picture and touch on a lot of important factors to consider.
I’m definitely going to go watch some more of your videos to get a fuller understanding.

My city (Arlington, TX) offered a free service to analyze residential sprinkler systems to conserve water last spring. The guy came out to my house and made two general recommendations. 1) I was using mixed types of sprinkler heads in the same zone. Different types deliver water at different rates so a zone was watering inconsistently. 2) He told me I needed to water TWICE per cycle about an hour apart for the reasons you mention, especially during a drought.
The first cycle gets the soil moist. The second cycle insures water gets into the ground much deeper without running off.

It also seems as though the hydraulic properties of dry soil cause issues along many fronts. Every soil type is different, but clay's hydraulic properties cause it to shrink and create compacted, dense clumps in a matrix rather than a single, homogeneous soil type over time. Over time, water is displaced as it runs through to the water table and evaporates, but the voids left are purely air. Over time, this settlement displaced air as the hydraulic sponge effect is lost and air is easily displaced and compacted with respect to water, causing extremely hard, compacted soil. Just feel the effect of force resonance on hard, compacted soil. Jumping on it feels like an anvil, where there is no room for crushing and you feel the immediate, exact force of your fall repelled back at you. Spongy soil can almost fully absorb your jump with little pain to your joints due to room for compaction creating a crush zone. The problem with the flash food effect on such soil is essentially a snowball effect. Water that cannot percolate instantly will run and continue to do so until it can. This leads to erosion of the soil/substrate instantly at the soil level, and the very media that created a matrix by which to contain the initial downpour is not stripped and actually contributes to the down-plane momentum of the flow. The root columns and mycelia matrix (and organisms burrowing) create a path to which percolation and saturation can occur in the absence of good soil conditions, but the absence of the same saturated soil conditions that allow adequate percolation are what deters the growth of all the aforementioned. Hydrophobia can occur at different levels of the surface several inches down to the sub-surface soil matrix, and every single surface (depending on pore size) gets coated in this, creating a massive systemic problem in the local environment in flood conditions. Even if healthy roots and mycelia are present and can help, if they're not enough, the surface flow will simply rip them out and their benefit is lost anyway. It is EXTREMELY difficult to replicate nature's phenomena completely in a lab environment, so it's clear that any factor left out could have a significant effect on results. I feel that the original experiment you're critiquing is ignoring a lot of reality, and ironically, his "simpler" experiment addressed the reality of the matter far more accurately than yours. Cheers.

Thanks for the video. I always assumed that when it rained after a drought, that the rain would just saturate the top inch or two of soil and before that moisture could work it's way to deeper, the rest of the rain would just run off. Glad i learned that's not necessarily the case.

0:25 first thing i noticed is that if we're testing soil why would we keep grass there while using small plastic cups, grass could easily like a wedge generate holes between the light cup and soil ruining the experiment, either cut out the grass or use heavier container that would squish the grass to make sure there is no holes between container and soil.
7:16 This is infinitely better and more convincing for the argument even tho not perfect.

I recently learned this from growing potted plants when the top of the soil is dry the water sits for a few then its slowly absorbed and/or runs down the sides of the pot but if I lightly sprayed them then came back a few minutes later to water them all the water is quickly absorbed by the soil and there's no run off

“I won’t make you go through the calculations, because we can make the computer do them.” Said no engineering professor ever 😅
Love the video, my recent internship worked a lot with soil conditions and estimating infiltration rates! 5:50

Regarding hydrophobic houseplant soil, it isn't just the surface layer that becomes water repellant, but rather the whole soil. You can try to water it from the top all you want, but it will just roll across the surface and drain down the sides of the pot. Even if the top layer becomes wetted, you can scrape under that and see comletely dry soil 1-2 cm down. That's why the best way to revive such soil is to soak the whole pot in water, sometimes for several hours for a larger pot. I imagine the same would apply to dry, hydrophobic ground - it could take hours for a rainstorm to penetrate deeply into the ground, and all the while the water that isn't infiltrating the soil would be running off and contributing to a possible flood. It's possible that some soils wouldn't become properly saturated by the rain alone, but only by volumes of water flooding across them and causing enough pressure to outmatch the hydrophobic repulsion.
Also, not to be too nitpicky here, but to really rehydrade hydrophobic material is different from breaking the surface tension barrier and allowing water to flow past the hydrophobic material. For example, it's clear in your video that water flows past the hydrophobic beads but does not wet them. Organic soil components such as dead plant material often become hydrophobic as well, despite their usual ability to retain water. If those materials still do not retain water even if water is available in the interstices between particles, the soil can retain less water overall.
So I think your hydrophobic model would have been more accurate if 1) you filled the entire container with hydrophobic material rather than just a thin layer on top of very absorbent sand; 2) you had some kind of outlet for water to flow off of the material and create runoff, rather than it building up in a high-pressure column which likely overcame the hydrophobicity faster; and 3) you used a material that more accurately models the changing properties of sometimes-hydrophobic soil. One recommendation I have is coconut coir, which is a common potting soil component. It absorbs water well when already moist, but when it dries out too much it becomes extremely hydrophobic and difficult to rehydrate efficiently.
Like you said, these factors are extremely complex! Really interesting video but I do feel like there is a lot more that can be explored on this topic.

I'd be very interested in seeing those same experiments with a fixed volume of water and performed on both flat areas and run off channels or artificial rivers (with and without levees) to understand the effect of terrain and engineering on run off volume