through an invisible web of servers, computers, and devices.

It has changed our lives in countless ways

by allowing otherwise separated people to interact

and by providing access to vast amounts of information.

But humans aren't the only organisms on the planet

with an invisible interconnected network.

While plants might seem like isolated, solitary individuals,

they're capable of communicating with each other,

sometimes over considerable distances,

all thanks to their special relationship with fungi.

Nearly all plant species we know of have a mutually beneficial relationship

with soil fungi called mycorrhizae.

Mycorrhizae grow a network of small, branching tubes, called a mycelium,

that extends throughout the soil, including inside of or around plant roots.

And these allow the fungi to absorb nutrients from the soil,

like nitrogen and phosphorus, which plants struggle to extract.

So they basically barter: in exchange for those hard-to-get nutrients,

the plants trade the fungi carbon in the form of sugars.

And ultimately, together, both can thrive when they otherwise wouldn't.

This symbiotic relationship between plants and fungi

was discovered in the early 1900s, but it wasn't until 1997

that we understood just how deep this underground network goes.

Ecologist Suzanne Simard had a hunch

that plants weren't just sharing nutrients with fungi, but also with each other.

To test her hypothesis,

she and her colleagues infused trees in a forest

with a traceable, radioactive form of carbon,

and later took samples from neighboring trees.

And it turned out many nearby trees had the radioactive carbon, too,

proving that plants could send nutrients back and forth to one another.

Not only that,

they seemingly distributed the nutrients where they were needed most.

Plants need light energy to turn carbon dioxide and water

into sugar and oxygen

thanks to that magical process called photosynthesis.

So those in shade have less sugar to go around.

Simard found that these shaded, energy-deficient trees

ended up with more of the radioactive carbon

than their sunbathing counterparts.

So it's basically the plant-fungi equivalent of feeding the hungry.

Continued research into these underground networks,

called Common Mycelium Networks,

has revealed that plants are not only able to gain access to more nutrients,

they can also engage in sophisticated communication

by “talking” chemically through mycelia.

And, it turns out, they're saying quite a bit!

Generally, any seedling that's plugged into the Common Mycelium Network,

or CMN, has a higher likelihood of surviving.

And plants that are “online” are generally healthier, too.

Researchers think this has to do with having access

to an early warning system.

When a plant is attacked, it releases chemicals

that tell nearby plants something bad is coming their way.

This communication happens with airborne compounds,

but also through a CMN.

And other plants heed this warning.

For example, when tomato plants are connected by a CMN,

and one plant is attacked by a pest,

nearby plants will activate their defenses before the pest reaches them.

Scientists are only just starting to understand

how important these plant networks are.

They've discovered that entire forests can be interconnected,

but like with our internet,

connectivity throughout an ecosystem isn't evenly distributed.

Older, larger trees are more connected,

kind of like some servers in the human internet.

These highly connected trees are called hub or mother trees.

They have big root networks that host a greater diversity of mycorrhizal fungi,

and that allows them to interact with a lot of other plants.

They do play favorites, though…

Scientists have shown they can send 'care packages' of extra nutrients

to their kin to help them survive, which is how they got the mommy moniker.

And they also can help forests transition during times of change.

When they're injured or dying, they release a surge of carbon

into the network which nurtures the next generation of trees,

even if they're a different species.

Of course, no internet is complete without hackers.

Some plants can claim territory and influence community dynamics

by sending toxins into the CMN.

Black Walnuts will use these networks

to release toxins into the soil, for example.

Those that are immune to the toxins thrive, while others struggle or die off.

And harmful worms, parasitic plants, and fungi

can find their way to the plants they target by following chemical trails

emitted by the mycorrhizae underground.

It's amazing to think that this chemical information superhighway

was right below our noses for eons and yet we had no clue.

But now that we can finally plug in, it might just help us connect

with the planet's flora in much more constructive ways.

Knowledge of this interconnectivity is helping improve our relationship to plants,

including things like forest conservation and agriculture.

For example, preserving the highly connected mother trees from deforestation

ensures mycorrhizal fungal diversity,

and helps forest regrowth happen more quickly.

And farming in soil with a CMN means plants can warn each other

of invading pests, which may reduce the need for pesticides.

Like with the human internet, the internet of the earth increases security,

awareness, and knowledge for those connected to it—including us.

Thanks for watching this episode of SciShow!

If you liked learning about plant symbiotic relationships,

you might like our episode on how plants recruit bodyguards.