Why do trees need to transport water to such heights?

Trees need to transport water to their topmost branches for survival, aiding in processes such as photosynthesis and growth.

What is the traditional limit for sucking water using a tube?

Water can traditionally be sucked to a height of 10 meters using a tube before a vacuum prevents further upward movement.

How do trees manage to move water upward beyond this 10-meter limit?

Trees use a process involving negative pressures and evaporation through nanoscale pores in the xylem tubes, allowing them to transport water up to 100 meters.

Why doesn't water boil inside the trees despite negative pressures?

The xylem tubes in trees contain no air bubbles, allowing water to remain in a metastable liquid state even at high negative pressures.

What proportion of water taken up by trees is used for photosynthesis?

Less than 1% of the water absorbed by trees is used in photosynthetic processes.

What happens to the majority of water that trees absorb?

About 95% of the water absorbed by trees simply evaporates.

Why doesn’t the meniscus at the water surface inside the tree break under pressure?

The meniscus doesn’t break because the pores that facilitate water movement are extremely tiny, supported by water's high surface tension.

Who contributed scientifically to the explanation of this phenomenon?

Professor John Sperry from the University of Utah contributed to the understanding of this process.

What common misconception about liquid pressure does the video address?

The video clarifies that, unlike gases, liquids can have negative pressures, a concept involving tension among molecules.

How Trees Bend the Laws of Physics

00:07:22

https://www.youtube.com/watch?v=BickMFHAZR0

Zusammenfassung

TLDRThis video delves into the mechanics of how trees, some exceeding 100 meters in height, manage to transport water from their roots to their topmost branches, a process that appears to defy typical physical limits. The traditional understanding is that water can only be sucked up to a height of 10 meters before a vacuum forms, preventing further movement. However, trees overcome this through the creation of negative pressures by evaporation through incredibly small pores. This process creates immense pressures to draw water upwards, despite it being in a state where it should boil due to negative pressure – a phenomenon countered by the water being in a metastable state without air bubbles. Surprisingly, 95% of the water absorbed by trees is merely evaporated, with minimal usage in photosynthesis or cell growth. The insights here involve contributions from scientists and serve not only to elucidate this natural mystery but also to dispel misconceptions about liquid pressure.

Mitbringsel

🌳 Trees must transport water to great heights to survive.
🌡️ Traditional pressure limits don't apply in trees due to unique mechanisms.
🧪 Trees create negative pressures exceeding -15 atmospheres.
💧 Transpiration creates a suction effect, aiding water movement.
🔬 Xylem tubes must remain air-free for effective water transport.
🌀 Water remains in a metastable state instead of boiling.
🍃 Most absorbed water simply evaporates for carbon dioxide exchange.
📚 Scientific contributions help unravel complex natural processes.
💡 Misconceptions about liquid negative pressure are clarified.
🌿 Trees utilize biomechanical strategies to sustain unimaginable feats.

Zeitleiste

00:00:00 - 00:07:22
The video begins by posing the seemingly simple question of why trees can grow so tall. It explores how water must be transported from a tree's roots to its highest branches, which poses a challenge due to the 10-meter limit on how high water can be sucked through a straw. The video mentions theories such as transpiration creating suction but notes these don't fully explain the process since the lowest achievable pressure in leaves isn't a pure vacuum. It also debunks the idea that trees have a continuous straw-like structure, suggesting instead that xylem tubes are responsible and that they contain a continuous water column.

Mind Map

Häufig gestellte Fragen

Why do trees need to transport water to such heights?
Trees need to transport water to their topmost branches for survival, aiding in processes such as photosynthesis and growth.
What is the traditional limit for sucking water using a tube?
Water can traditionally be sucked to a height of 10 meters using a tube before a vacuum prevents further upward movement.
How do trees manage to move water upward beyond this 10-meter limit?
Trees use a process involving negative pressures and evaporation through nanoscale pores in the xylem tubes, allowing them to transport water up to 100 meters.
Why doesn't water boil inside the trees despite negative pressures?
The xylem tubes in trees contain no air bubbles, allowing water to remain in a metastable liquid state even at high negative pressures.
What proportion of water taken up by trees is used for photosynthesis?
Less than 1% of the water absorbed by trees is used in photosynthetic processes.
What happens to the majority of water that trees absorb?
About 95% of the water absorbed by trees simply evaporates.
Why doesn’t the meniscus at the water surface inside the tree break under pressure?
The meniscus doesn’t break because the pores that facilitate water movement are extremely tiny, supported by water's high surface tension.
Who contributed scientifically to the explanation of this phenomenon?
Professor John Sperry from the University of Utah contributed to the understanding of this process.
What common misconception about liquid pressure does the video address?
The video clarifies that, unlike gases, liquids can have negative pressures, a concept involving tension among molecules.

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Untertitel

Automatisches Blättern:

00:00:01
Sometimes the simplest questions have the most amazing answers.
00:00:05
Like how can trees be so tall? It's a question that doesn't even seem
00:00:10
like it needs an answer.
00:00:11
Trees just are tall. Some of them are over 100 meters.
00:00:15
Why should there be a height limit?
00:00:17
I'll tell you why. Tress need to transport water from their roots up into their topmost
00:00:21
branches in order to survive. And that is no trivial task.
00:00:25
There is a limit to the height that water can be sucked up a tube - it's 10 meters.
00:00:30
If you suck on a long vertical straw, the water will go no higher than 10 meters. At
00:00:35
this point there will be a perfect vacuum at the top of the straw and the water will
00:00:38
start to boil spontaneously. For a tree to raise water 100 meters, it would have to create
00:00:43
a pressure difference of 10 atmospheres.
00:00:46
How would trees do that?
00:00:48
When I posed this conundrum, a lot of people said the answer is transpiration. And that's
00:00:53
when water evaporates from the leaf, pulling up the water molecules behind it. Now that's
00:00:57
clearly a mechanism a tree can use to create suction, but it doesn't help us overcome this
00:01:02
10 meter limit. The lowest the pressure can go is a pure vacuum,
00:01:05
which I imagine is not happening inside of tree leaves, right?
00:01:09
Right, Hank. So you might suspect that a tree does not contain continuous straw-like tubes
00:01:15
The tree effectively has valves in it. So you don't have a column of water
00:01:20
This big tube that you're saying needs to be full of water is actually made up of cells.
00:01:25
Although these are good speculations, they don't turn out to be correct.
00:01:29
Scientists who study trees find that the xylem tubes that transport water do contain a continuous
00:01:34
water column. So how else could the tree transport water from the roots to the leaves?
00:01:38
They don't suck, they don't use a vacuum.
00:01:40
OK, so how do they do it?
00:01:42
Squeezing like a cow udder all the way up. They have little tree muscles in there.
00:01:47
Yeah. Besides being a giant waste of energy, all
00:01:50
of the cells that make up the xylem tubes are all dead.
00:01:53
What about osmotic pressure? If there is more solute in the roots than in the surrounding
00:01:57
soil, water would be pushed up the tree. But some trees live in mangroves, where the water
00:02:02
is so salty that osmotic pressure actually acts in the other direction so the tree needs
00:02:06
additional pressure to suck water into the tree.
00:02:09
Then it must be capillary action. The thinner the tube, the higher the water can climb.
00:02:15
But the tubes in a tree are too wide - at 20-200 micrometers in diameter, water should
00:02:20
rise less than a meter.
00:02:22
So how do trees do it?
00:02:24
Well one of the assumptions we made is wrong: The lowest the pressure can go is a pure vacuum
00:02:29
pure vacuum pure vacuum
00:02:30
In a gas, this is true. When you eliminate all of the gas molecules, the pressure is
00:02:34
zero and you have a perfect vacuum.
00:02:37
But in a liquid, you can go lower than 0 pressure and actually get negative pressures. In a
00:02:43
solid, we would think of this as tension. This means that the molecules are pulling
00:02:47
on each other and their surroundings.
00:02:50
As the water evaporates from the pores of the cell wall, they create immense negative
00:02:55
pressures of -15 atmospheres in an average tree. Think about the air-water interface
00:03:01
at the pore. There is one atmosphere of pressure pushing in and negative 15 atmospheres of
00:03:06
suction on the other side. So why doesn't the meniscus break? Because the pores are
00:03:11
tiny, only 2-5 nanometres in diameter. At this scale, water's high surface tension ensures
00:03:18
the air-water boundary can withstand huge pressures without caving.
00:03:23
As you move down the tree, the pressure increases, up to atmospheric at the roots. So you can
00:03:28
have a large pressure difference between the top and bottom of the tree because the pressure
00:03:32
at the top is so negative.
00:03:34
But hang on, if the pressure near the top is negative 15 atmospheres, shouldn't the
00:03:38
water be boiling?
00:03:40
Yes. Yes it should.
00:03:42
But changing phase from liquid to gas requires activation energy. And that can come in the
00:03:48
form of a nucleation site like a tiny air bubble. That's why it's so important that
00:03:52
the xylem tubes contain no air bubbles, and they can do this because unlike a straw, they
00:03:57
have been water-filled from the start. This way, water remains in the metastable liquid
00:04:01
state when it really should be boiling.
00:04:04
It's just like supercooled water remains liquid when it really should be ice. So you could
00:04:08
say that the water in a tree is supersucked because it remains liquid at such negative
00:04:13
pressures.
00:04:14
And why are trees moving all this water up the tree? I want you to make a guess, say
00:04:19
it out loud. For photosynthesis?
00:04:21
Actually, no. Less than 1% of the water is used in photosynthetic reactions. Any other
00:04:27
ideas? Ok what about growth? Well 5% of the water
00:04:30
is used to make new cells. Well, so then what happens to the other 95%
00:04:34
of the water? It just evaporates.
00:04:38
For each molecule of carbon dioxide a tree takes in, it loses hundreds of water molecules
00:04:43
of water.
00:04:43
Woah.
00:04:44
Can you believe how amazing this is? Trees create huge negative pressures of 10's of
00:04:49
atmospheres, by evaporating water through nanoscale pores, sucking water up 100m, in
00:04:54
a state where it should be boiling but can't because of the perfect xylem tubes contain
00:04:58
no air bubbles, just so that most of it can evaporate in the process of absorbing a couple
00:05:03
molecules of carbon dioxide.
00:05:06
I will never look at a tree the same way again.
00:05:19
I'd like to say a huge thank you to Hank, Henry and Professor Poliakoff for making on
00:05:24
camera hypotheses. This is an essential part of the scientific process even if your hypothesis
00:05:29
turns out to be wrong. As Einstein said, "a person who has never
00:05:32
made a mistake has never tried anything new." I've always wondered what it would be like
00:05:36
to be on this side of a Veritasium video.
00:05:41
Now I'd be surprised if you weren't already subscribed to these guys, but if you're not,
00:05:44
go click on these annotations and check out their channels. You may just learn something.
00:05:48
I'd also like to thank Professor John Sperry from the University of Utah. He walked me
00:05:52
through all of this in an hour-long Skype conversation so I'm going to put a link to
00:05:56
his website in the description. We're looking at pressures here below atmospheric,
00:05:59
is that right? That's right. Below atmospheric. This is liquid
00:06:03
pressure not gas pressure. So it's a common misconception that oh, you can't have you
00:06:09
know negative pressures because there's no molecules left. You know, the definition of
00:06:14
pure vacuum is zero molecules. That's for a gas, ok. So just to be clear...
00:06:20
I think this was one of my big problems in understanding this.
00:06:23
This video would have been impossible without CGP Grey. When I told him in London about
00:06:27
this idea in London... And I felt like 'pssshhh mind just blown with
00:06:32
this whole thing' He said it was going to be really hard to
00:06:34
explain and when he says it's hard to explain you know things are going to be tough. So
00:06:38
thank you for all your input to this script.
00:06:41
And thank you for watching. Making this video has been a real odyssey for me so thank you
00:06:45
for joining me on this journey. I really appreciate all of your comments and if you haven't subscribed
00:06:50
to the channel already you can click the annotation or click the link above and join me on my
00:06:54
next scientific adventure.
00:06:56
I made a video promising to make a video about the answer to this. I proposed the problem
00:07:04
like a couple months ago, and I was like "subscribe to the channel and I'll give you the answer
00:07:07
next week." Hahaha Oh, the lies.
00:07:14
Drive it at the right frequency. Oh
00:07:17
Yes!! Success is frightening.