Why Buildings Need Foundations

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When we bought our house several years ago, we  fell in love with every part of it except one:  

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the foundation. At 75 years old, we knew  these old piers were just about finished  

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holding this old house up. This year we  finally bit the bullet to have them replaced.  

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Any homeowner who’s had foundation work  done can commiserate with us on the cost  

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and disruption of a project like this. But homes  aren’t the only structures with foundations.  

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It is both a gravitational necessity and a source  of job stability to structural and geotechnical  

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engineers that all construction - great and small  - sits upon the ground. And the ways in which we  

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accomplish such a seemingly unexceptional feat  are full of fascinating and unexpected details.  

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I’m Grady and this is Practical Engineering. In  today’s episode, we’re talking about foundations.

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This video is sponsored by CuriosityStream  and Nebula. More on them later.

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There’s really just one rule for structural and  geotechnical engineers designing foundations:  

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when you put something on the ground, it should  not move. That seems like a pretty straightforward  

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directive. You can put a lot of stuff on the  ground and have it stay there. For example,  

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several years ago I optimistically stacked  these pavers behind my shed with the false hope  

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that I would use them in a landscaping project  someday, but their most likely future is to sit  

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here in this shady purgatory for all of eternity.  Unfortunately, buildings and other structures are  

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a little different. Mainly, they are large enough  that one part could move relative to the other  

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parts, a phenomenon we call differential movement.  When you move one piece of anyTHING relative to  

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the rest of it, you introduce stress. And if that  stress is greater than the inherent strength of  

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the thing, that thing will pull itself apart.  It happens all the time, all around the world,  

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including right here in my own house. When  one of these piers settles or heaves more  

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than the others, all the stuff it supports  tries to move too. But doorframes, drywall,  

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and ceramic tile work much better and last much  longer when the surrounding structure stays put.

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There are many kinds of foundations used for  the various structures in our built environment,  

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but before we dive into how they work, I think it  will be helpful to first talk about what they’re  

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up against, or actually down against. Of course,  buildings are heavy, and one of the most important  

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jobs of a foundation is to evenly distribute  that weight into the subsurface as downward  

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pressure. Soil isn’t infinitely strong against  vertical loads. It can fail just like any other  

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component of a structural system. When the forces  are high enough to shear through soil particles,  

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we call it a bearing failure. The soil  directly below the load is forced downward,  

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pushing the rest of the soil to either side,  eventually bulging up around the edges.

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Even if the subsurface doesn’t full-on shear, it  can still settle. This happens when the particles  

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are compressed more closely together, and it  usually takes place over a longer period of time.  

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(I have a video all about settlement  that you can check out after this.)  

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So, job number 1 of a foundation is to distribute  the downward force of a structure over a large  

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enough area to reduce the bearing pressure and  avoid shear failures or excessive settlement.

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Structural loads don’t just come from gravity.  Wind can exert tremendous and rapidly-fluctuating  

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pressure on a large structure pushing it  horizontally and even creating uplift like the  

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wing of an airplane. Earthquakes also create loads  on structures, shifting and shaking them with very  

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little warning. Just like the normal weight of  a structure, these loads must also be resisted  

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by a foundation to prevent it from lifting or  sliding along the ground. That’s job number 2.

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Speaking of the ground, it’s not the most  hospitable place for many building materials.  

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It has bugs, like termites, that can eat away  at wooden members over time, reducing their  

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strength. It also has moisture that can lead to  mold and rot. My house was built in the 1940s  

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on top of cedar piers. This is a wood species  that is naturally resistant to bugs and fungi,  

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but not completely immune to them as you can see.  So, job number 3 of a foundation is to resist  

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the effects of long-term degradation and decay  that come from our tiny biological neighbors.

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Another problem with the ground is that  soil isn’t really as static as we think.  

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Freezing isn’t usually a problem for me in  central Texas, but many places in the world see  

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temperatures that rise and fall below the freezing  point of water tens or hundreds of times per year.  

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We all know water expands when it freezes, and  it can do so with prodigious force. When this  

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happens to subsurface water below a structure, it  can behave like a jack to lift it up. Over time,  

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these cycles of freeze and thaw can slowly shift  or raise parts of a structure more than others,  

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creating issues. Similarly, some kinds  of soil expand when exposed to moisture.  

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I also have a video on this phenomenon, so you  have two videos to watch after this one. Expansive  

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clay soil can create the same type of damage  as cycles of freeze and thaw by subtly moving  

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a structure in small amounts with each cycle of  wet and dry. So job number 4 of a foundation is  

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to reach a deep enough layer that can’t freeze  or that doesn’t experience major fluctuations  

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in moisture content to avoid these problems that  come with water in the subgrade below a structure.

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Job number 5 isn’t necessarily applicable to  most buildings, but there are many types of  

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structures (like bridges and retaining walls)  that are regularly subject to flowing water.  

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Over time (or sometimes over the course of a  single flood), that water can create erosion,  

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undermining the structure. Many foundations  are specifically designed to combat erosion,  

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either with hard armoring or by simply  being installed so deep into the earth  

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that they can’t be undermined  by quickly flowing water.

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Job number 6 really applies to all of engineering:  foundations have to be cost effective. Could the  

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contractor who built my house in the 1940s  have driven twice as many piers, each one to  

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three times the depth? Of course it can be done,  but (with some minor maintenance and repairs),  

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this one lasted 75 years before needing to be  replaced. With the median length of homeownership  

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somewhere between 5 and 15 years, few people  would be willing to pay more for a house with  

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500 years of remaining life in the foundation  than they would for one with 30. I could have  

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paid this contractor to build me a foundation  that will last hundreds of years... but I didn’t.  

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Engineering is a job of balancing constraints, and  many of the decisions in foundation engineering  

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come down to the question of “How can we  achieve all of the first 5 jobs I mentioned  

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without overdoing it and wasting a bunch of  money in the process?” Let’s look at a few ways.

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Foundations are generally  divided into two classes:  

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deep and shallow. Most buildings with only  a few stories, including nearly all homes,  

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are built on shallow foundations. That means they  transfer the structure’s weight to the surface of  

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the earth (or just below it). Maybe the most basic  of these is how my house was originally built.  

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They cut down cedar trees, hammered those  logs into the ground as piles, layed wooden  

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beams across the top of those piers, and then  built the rest of the house atop the beams.  

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Pier and beam foundations are pretty common,  at least in my neck of the woods, and they have  

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an added benefit of creating a crawlspace below  the structure in which utilities like plumbing,  

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drains, and electric lines can be installed  and maintained. However, all these individual,  

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unconnected points of contact with the earth leave  quite a bit of room for differential movement.

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Another basic type of shallow foundation is  the strip footing, which generally consists  

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of a ribbon or strip of concrete upon which walls  can sit. In some cases the floor is isolated from  

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the walls and sits directly on concrete slab atop  the subgrade, but strip footings can also support  

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floor joists, making room for a crawlspace below.  For sites with strong soils, this is a great  

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option because it’s simple and cheap, but if the  subgrade soils are poor, strip footings can still  

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allow differential movement because all the walls  aren’t rigidly connected together. In that case,  

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it makes sense to use a raft foundation - a  completely solid concrete slab that extends  

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across the entire structure. Raft foundations  are typically concrete slabs placed directly on  

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the ground (usually with some thickened areas  to provide extra rigidity). They distribute  

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the loads across a larger area, reducing  the pressure on the subgrade, and they can  

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accommodate some movement of the ground without  transferring the movement into a structure,  

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essentially riding the waves of the earth like  a raft on the ocean (hence the name). However,  

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they don’t have a crawlspace which makes  plumbing repairs much more challenging.

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One issue with all shallow foundations is that  you still need to install them below the frost  

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line - that is the maximum depth to which water  in the soil might freeze during the harshest part  

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of the winter - in order to avoid frost heaving.  In some parts of the contiguous United States,  

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the frost line can be upwards of 8  feet or nearly two-and-a-half meters.  

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If you’re going to dig that deep  to install a foundation anyway,  

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you might as well just add an extra  floor to your structure below the ground.  

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That’s usually called a basement, and it  can be considered a building’s foundation  

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(although the walls are usually constructed on  a raft or strip footings as described above).

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As a structure’s size increases, so do the  loads it imposes on the ground, and eventually  

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it becomes infeasible to rely only on soils  near the surface of the earth. Tall buildings,  

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elevated roadways, bridges, and coastal structures  often rely on deep foundations for support. This  

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is especially true when the soils at the surface  are not as firm as the layers farther below the  

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ground. Deep foundations almost always rely on  piles, which are vertical structural elements that  

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are driven or drilled into the earth, often down  to a stronger layer of soil or bedrock, and there  

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are way more types than I could ever cover in a  single video. Piles not only transfer loads at the  

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bottom (called end bearing), but they can also be  supported along their length through a phenomenon  

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called skin friction. This makes it possible  for a foundation to resist much more significant  

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loads - whether downward, upward or horizontal  - within a given footprint of a structure.

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One of the benefits of driven piles is  that you install them in somewhat the  

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same way that they’ll be loaded in their final  configuration. There’s some efficiency there  

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because you can just stop pushing the pile  into the ground once it’s able to resist  

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the design loads. There’s a problem with  this though. Let me show you what I mean.  

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This hydraulic press has more than enough  power to push this steel rod into the ground.  

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And at first, it does just that. But eventually,  it reaches a point where the weight of the press  

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is less than the bearing capacity of the pile, and  it just lifts itself up. Easy… (you might think).  

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Just add more weight. But consider that these  piles might be designed to support the weight  

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of an entire structure. It’s not feasible  to bring in or build some massive weight  

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just to react against to drive a pile into  the ground. Instead, we usually use hammers,  

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which can deliver significantly more force to  drive a pile with only a relatively small weight.

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The problem with hammered piles is that the  dynamic loading they undergo during installation  

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is different from the static loading  they see once in service. In other words,  

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buildings don’t usually hammer on their  foundations. For example, if a pile can  

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withstand the force of a 5-ton weight dropped  from 16 feet or 5 meters without moving, what’s  

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the equivalent static load it can withstand? That  turns out to be a pretty complicated question,  

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and even though there are published equivalencies  between static and dynamic loads, their accuracy  

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can vary widely depending on soil conditions.  That’s especially true for long piles where  

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the pressure wave generated by a hammer might not  even travel fast enough to load the entire member  

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at the same moment in time. Static tests are more  reliable, but also much more expensive because you  

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either have to bring in a ton (or thousands of  tons) of weight to put on top, or you have to  

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build additional piles with a beam across them  to give the test rig something to react against.

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One interesting solution to this problem  is called statnamic testing of piles.  

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In this method, a mass is accelerated  upward using explosives, creating an  

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equal and opposite force on the pile to be  tested. It’s kind of like a reverse hammer,  

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except unlike a hammer where the force on  the pile lasts only for a few milliseconds,  

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the duration of loading in a statnamic test  is often upwards of 100 or 200 milliseconds.  

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That makes it much more similar to a static  force on the pile without having to bring in  

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tons and tons of weight or build expensive  reaction piers just to conduct a test.

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I’m only scratching the surface (or subsurface)  of a topic that fills hundreds of engineering  

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textbooks and the careers of thousands of  contractors and engineers. If all the earth  

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was solid rock, life would be a lot simpler, but  maybe a lot less interesting too. If there are  

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topics in foundations that you’d like to learn  more about, add a comment or send me an email,  

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and I’ll try to address it in a future video,  but I hope this one gives you some appreciation  

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of those innocuous bits of structural and  geotechnical engineering below our feet.

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