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Why can't you just flick a tick? Because it attaches to you with a mouth covered in hooks, while it fattens up on your blood. For days. But don't worry – there *is* a way to pull it out.

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DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

Spring is here. Unfortunately for hikers and picnickers out enjoying the weather, the new season is prime time for ticks, which can transmit bacteria that cause Lyme disease.

How they latch on – and stay on – is a feat of engineering that scientists have been piecing together. Once you know how a tick’s mouth works, you understand why it’s impossible to simply flick a tick.

The key to their success is a menacing mouth covered in hooks that they use to get under the surface of our skin and attach themselves for several days while they fatten up on our blood.

“Ticks have a lovely, evolved mouth part for doing exactly what they need to do, which is extended feeding,” said Kerry Padgett, supervising public health biologist at the California Department of Public Health in Richmond. “They're not like a mosquito that can just put their mouth parts in and out nicely, like a hypodermic needle.”

Instead, a tick digs in using two sets of hooks. Each set looks like a hand with three hooked fingers. The hooks dig in and wriggle into the skin. Then these “hands” bend in unison to perform approximately half-a-dozen breaststrokes that pull skin out of the way so the tick can push in a long stubby part called the hypostome.

“It’s almost like swimming into the skin,” said Dania Richter, a biologist at the Technische Universität Braunschweig in Germany, who has studied the mechanism closely. “By bending the hooks it’s engaging the skin. It’s pulling the skin when it retracts.”

The bottom of their long hypostome is also covered in rows of hooks that give it the look of a chainsaw. Those hooks act like mini-harpoons, anchoring the tick to us for the long haul.

“They’re teeth that are backwards facing, similar to one of those gates you would drive over but you're not allowed to back up or else you'd puncture your tires,” said Padgett.

--- How to remove a tick.
Kerry Padgett, at the California Department of Public Health, recommends grabbing the tick close to the skin using a pair of fine tweezers and simply pulling straight up.

“No twisting or jerking,” she said. “Use a smooth motion pulling up.”

Padgett warned against using other strategies.

“Don't use Vaseline or try to burn the tick or use a cotton swab soaked in soft soap or any of these other techniques that might take a little longer or might not work at all,” she said. “You really want to remove the tick as soon as possible.”

--- What happens if the mouth of a tick breaks off in your skin?
Don’t worry if the tick’s mouth parts stay behind when you pull.

“The mouth parts are not going to transmit disease to people,” said Padgett.

If the mouth stayed behind in your skin, it will eventually work its way out, sort of like a splinter does, she said. Clean the bite area with soap and water and apply antibiotic ointment.

---+ Read the entire article on KQED Science: https://www.kqed.org/science/1....920972/how-ticks-dig

---+ For more information:
Centers for Disease Control information on Lyme disease:
https://www.cdc.gov/lyme/

Mosquito & Vector Control District for San Mateo County, California:
https://www.smcmvcd.org/ticks


---+ More Great Deep Look episodes:

How Mosquitoes Use Six Needles to Suck Your Blood
https://www.youtube.com/watch?v=rD8SmacBUcU

So … Sometimes Fireflies Eat Other Fireflies
https://www.youtube.com/watch?v=oWdCMFvgFbo

---+ See some great videos and documentaries from the PBS Digital Studios!

Above the Noise: Are Energy Drinks Really that Bad?
https://www.youtube.com/watch?v=5l0cjsZS-eM

It’s Okay To Be Smart: Inside an ICE CAVE! - Nature's Most Beautiful Blue
https://www.youtube.com/watch?v=P7LKm9jtm8I


---+ Follow KQED Science:
KQED Science: http://www.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

---+ About KQED
KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is supported by the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation Fund and the members of KQED.
#deeplook #ticks #tickbite

Termites cause billions of dollars in damage annually – but they need help to do it. So they carry tiny organisms around with them in their gut. Together, termites and microorganisms can turn the wood in your house into a palace of poop.

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

Termites such as dampwood termites use their cardboard-like poop pellets to build up their nests, turning a human house into a termite toilet. “They build their own houses out of their own feces,” said entomologist Michael Scharf, of Purdue University, in Indiana.

And while they’re using their poop as a building material, termites are also feeding on the wood. They’re one of the few animals that can extract nutrients from wood. But it turns out that they need help to do this.

A termite’s gut is host to a couple dozen species of protists, organisms that are neither animals, nor plants, nor fungi. Scientists have found that several of them help termites break down wood.

When some protists are eliminated from the termite’s gut, the insect can’t get any nutrition out of the wood. This is a weakness that biologists hope to exploit as a way to get rid of termites using biology rather than chemicals.

Louisiana State University entomologist Chinmay Tikhe is working to genetically engineer a bacterium found in the Formosan termite’s gut so that the bacterium will destroy the gut protists. The idea would be to sneak these killer bacteria into the termite colony on some sort of bait the termites would eat and carry back with them.

“It’s like a Trojan Horse,” said Tikhe, referring to the strategy used by the Greeks to sneak their troops into the city of Troy using a wooden horse that was the city’s emblem.

The bacteria would then kill the protists that help the termite derive nutrition from wood. The termites would eventually starve.

--- How do termites eat wood?

Termites gnaw on the wood. Then they mix it with enzymes that start to break it down. But they need help turning the cellulose in wood into nutrients. They get help from hundreds, and sometimes thousands, of species of microbes that live inside their guts. One bacterium, for example, combines nitrogen from the air and calories from the wood to make protein for the termites. A termite’s gut is also host to a couple dozen species of protists. In the termite’s hindgut, protists ferment the wood into a substance called acetate, which gives the termite energy.

--- How do termites get into our houses?

Termites can crawl up into a house from the soil through specialized tubes made of dirt and saliva, or winged adults can fly in, or both. This depends on the species and caste member involved.

--- What do termites eat in our houses?

Once they’re established in our houses, termites attack and feed on sources of cellulose, a major component of wood, says entomologist Vernard Lewis, of the University of California, Berkeley. This could include anything from structural wood and paneling, to furniture and cotton clothing. Termites also will eat dead or living trees, depending on the species.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....016/10/18/these-term

---+ For more information:

University of California Integrated Pest Management Program’s web page on termites:

http://ipm.ucanr.edu/PMG/PESTNOTES/pn7415.html

---+ More Great Deep Look episodes:

How Mosquitoes Use Six Needles to Suck Your Blood:
https://www.youtube.com/watch?v=rD8SmacBUcU

For These Tiny Spiders, It’s Sing or Get Served:
https://www.youtube.com/watch?v=y7qMqAgCqME

Where are the Ants Carrying All Those Leaves?:
https://www.youtube.com/watch?v=-6oKJ5FGk24

---+ See some great videos and documentaries from PBS Digital Studios!

It’s Okay To Be Smart: The Donald Trump Caterpillar and Nature’s Masters of Disguise
https://www.youtube.com/watch?v=VTUCTT6I1TU

Gross Science: Why Do Dogs Eat Poop?
https://www.youtube.com/watch?v=Z3pB-xZGM1U

---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media. macro pest control
#deeplook

Earwigs are equipped with some pretty imposing pincers on their rear, and they're not afraid to use them. But when it comes to these appendages, size isn't everything.

You can learn more about CuriosityStream at https://curiositystream.com/deeplook.
SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

Many animals seem to show a preference for symmetry in a potential mate. It can be a clue that the mate has the genes necessary to develop properly and thrive in an environment full of stresses and dangers.

But in some critters buck the trend. Like the earwig, a diminutive insect found on every continent except Antarctica.

Andrew ZInk, an associate professor of biology at San Francisco State University, has been looking at how symmetry affects earwigs success when it comes to social interactions.

He’s studying maritime earwigs, a larger and more powerful cousin to the common European earwig you might find in your backyard. Both creatures bear fearsome looking pincers on their backsides. And they aren’t afraid to use them to defend themselves. Zink knows all about that.

--- Do earwigs climb into your ear?
The quick answer is no. Earwigs are not interested in climbing into your ear to lay their eggs or otherwise. They’re no more likely than any other bug to accidentally find its way into you ear. The name earwig come from the old english words for ear and insect. It may have been named after the shape of the common European earwig’s wings, which when extended resemble a human ear.

--- Do earwigs pinch people?
Earwigs will use their pincers to defend themselves, but the pinch is typically not strong enough to be considered dangerous.

--- Do earwigs fly?
Male common European earwigs have wings and can fly to disperse and find mates. Females do not have wings or fly. Neither male nor female maritime earwigs have wings or fly.

--- What do earwigs eat?
Most earwigs are scavengers and omnivores. In addition to scavenging and eating plants, the common European earwigs also hunts small prey like aphids. Maritime earwigs are carnivorous hunting smaller arthropods like sand hoppers.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....018/06/26/what-do-ea

---+ For more information:

Biologists probe asymmetric warfare between earwigs
https://news.sfsu.edu/biologis....ts-probe-asymmetric-

Asymmetric Forceps Increase Fighting Success among Males of Similar size in the Maritime Earwig
https://onlinelibrary.wiley.co....m/doi/abs/10.1111/j.

Sexual selection by the seashore: the roles of body size and weaponry in mate choice and competition in the maritime earwig (Anisolabis maritima)
http://viyengar.clasit.org/wp-....content/uploads/2017

---+ More Great Deep Look episodes:

Watch These Cunning Snails Stab and Swallow Fish Whole | Deep Look
https://www.youtube.com/watch?v=jYMjLgPFSso

This Is Why Water Striders Make Terrible Lifeguards | Deep Look
https://www.youtube.com/watch?v=E2unnSK7WTE&t=19s

Take Two Leeches and Call Me in the Morning | Deep Look
https://www.youtube.com/watch?v=O-0SFWPLaII


---+ See some great videos and documentaries from PBS Digital Studios!

What the World’s Cutest Animal Can Teach Us About Saving Ourselves | Hot Mess
https://www.youtube.com/watch?v=IF8ym4g2SCU

The Deadpool Salamander | It's Okay To Be Smart
https://www.youtube.com/watch?v=uGutfyDOmu0

Why Do We Eat Artificial Flavors? | Origin Of Everything
https://www.youtube.com/watch?v=iNaJ31EV13U

---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is supported by the Templeton Religion Trust and the Templeton World Charity Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation Fund and the members of KQED.
#deeplook #earwig #pincers

Bugs and beetles can’t hold their breath underwater like we do. But some aquatic insects can spend their whole adult lives underwater. How do they do it? Meet nature’s Scuba divers. They carry their air with them—in some cases, for a lifetime.

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

--- How do some insects breathe underwater?

Air-breathing aquatic bugs and beetles don’t hold their breath the way sea mammals do, nor do they have gills like fish.

So how do they do it? The answer lies in their small size. Insect scuba strategies hinge on a property of water that relative giants like us usually overlook: surface tension.

People first crossed the line between land and sea to become scuba divers more than 70 years ago, when Jacques Cousteau pioneered the Aqua-Lung in Nazi-occupied France.

But some species of aquatic insects have been doing it for millions of years.

“Water beetles have been breathing underwater since before the dinosaurs existed,” said Crystal Maier, an entomologist at The Field Museum in Chicago. “It has evolved at least 10 times across the insect tree of life.”

--- What is surface tension?

Surface tension is the property of any liquid that describes how its particles stick together. In the case of water, surface tension is especially strong, enough to form a kind of film where it meets the air, whether at the surface or in a bubble.

The film is so strong, in fact, that a paper clip, which should sink because of its density, will float.

Surface tension is a delicate force, vulnerable to changes temperature, turbulence or the introduction of contaminants, like soap. A sudden drop in surface tension can drown a whole insect community in an instant.

Though it might not seem to affect our world to the same degree, surface tension is active all around us. It allows raindrops to form, trees to bring water to their leaves and ice to float. So in a sense, we too live on a thin boundary, ruled by the same subtle properties of water.

--- How do beetles use surface tension to breathe underwater?

If you’re a bug the size of a paperclip, in other words, surface tension makes a difference. Harnessing it, some aquatic beetles carry the oxygen they need underwater in the form of a temporary bubble, sort of like a natural scuba tank. Others encase themselves in a layer of air and draw oxygen from it their whole lives.

“It’s a pretty successful group of insects. They’re on every continent, except Antarctica,” said Cheryl Barr, collection manger emeritus at the Essig Museum of Entomology at UC Berkeley.

--- Super videos from the PBS Digital Studios Network!

Seven Surface Tension Experiments | Physics Girl
https://www.youtube.com/watch?v=WsksF...

Nature's Most Amazing Animal Superpowers | It's Okay to Be Smart
https://www.youtube.com/watch?v=e69ya...

Why Don’t These Cicadas Have Butts? | Gross Science
https://www.youtube.com/watch?v=IDBkj...

Read the full article on KQED Science:

http://ww2.kqed.org/science/20....15/11/10/natures-scu

--- More great DEEP LOOK episodes:

Halloween Special: Watch Flesh-Eating Beetles Strip Bodies to the Bone
https://www.youtube.com/watch?v=Np0hJ...

What Happens When You Put a Hummingbird in a Wind Tunnel?
https://www.youtube.com/watch?v=JyqY6...

You're Not Hallucinating. That's Just Squid Skin.
https://www.youtube.com/watch?v=0wtLr...

--- More KQED SCIENCE:

Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience
KQED Science: http://ww2.kqed.org/science


Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.
#deeplook

Dragonflies might rule the skies, but their babies grow up underwater in a larva-eat-larva world. Luckily for them, they have a killer lip that snatches prey, Alien-style, at lightning speed.

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DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

If adult dragonflies are known to be precise hunters, capable of turning on a dime and using their almost-360-degree vision to nab mosquitoes and flies in midair, their dragon-looking babies are even more fearsome.

Dragonflies and damselflies lay their eggs in water. After they hatch, their larvae, also known as nymphs, spend months or years underwater growing wings on their backs.

Without those versatile four wings that adults use to chase down prey, nymphs rely on a mouthpart they shoot out. It’s like a long, hinged arm that they keep folded under their head and it’s eerily similar to the snapping tongue-like protuberance the alien shoots out at Ripley in the sci-fi movie Aliens.

A nymph’s eyesight is almost as precise as an adult dragonfly’s and when they spot something they want to eat, they extrude this mouthpart, called a labium, to engulf, grab, or impale their next meal and draw it back to their mouth. Only dragonfly and damselfly nymphs have this special mouthpart.

“It’s like a built-in spear gun,” said Kathy Biggs, the author of guides to the dragonflies of California and the greater Southwest.

With their labium, nymphs can catch mosquito larvae, worms and even small fish and tadpoles.

“It’s obviously an adaptation to be a predator underwater, where it’s not easy to trap things,” said Dennis Paulson, a dragonfly biologist retired from the University of Puget Sound.

Also known among biologists as a “killer lip,” the labium comes in two versions. There’s the spork-shaped labium that scoops up prey, and a flat one with a pair of pincers on the end that can grab or impale aquatic insects.

-- How many years have dragonflies been around?

Dragonflies have been around for 320 million years, said Ed Jarzembowski, who studies fossil dragonflies at the Nanjing Institute of Geology and Paleontology. That means they were here before the dinosaurs.

-- How big did dragonflies used to be?

Prehistoric dragonflies had a wingspan of 0.7 meters (almost 28 inches). That’s the wingspan of a small hawk today.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....017/09/12/a-baby-dra

---+ For more information:

This web site, run by Kathy and David Biggs, has photos and descriptions of California dragonflies and damselflies and information on building a pond to attract the insects to your backyard: http://bigsnest.members.sonic.net/Pond/dragons/

The book "A Dazzle of Dragonflies," by Forrest Mitchell and James Lasswell, has good information on dragonfly nymphs.

---+ More great Deep Look episodes:

Why Is The Very Hungry Caterpillar So Dang Hungry?
https://www.youtube.com/watch?v=el_lPd2oFV4

This Mushroom Starts Killing You Before You Even Realize It
https://www.youtube.com/watch?v=bl9aCH2QaQY&t=57s

Daddy Longlegs Risk Life ... and Especially Limb ... to Survive
https://www.youtube.com/watch?v=tjDmH8zhp6o

This Is Why Water Striders Make Terrible Lifeguards
https://www.youtube.com/watch?v=E2unnSK7WTE

---+ See some great videos and documentaries from PBS Digital Studios!

PBS Eons: The Biggest Thing That Ever Flew
https://www.youtube.com/watch?v=scAp-fncp64

PBS Infinite Series: A Breakthrough in Higher Dimensional Spheres
https://www.youtube.com/watch?v=ciM6wigZK0w

---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

---+ About KQED

KQED, an NPR and PBS affiliate based in San Francisco, serves the people of Northern California and beyond with a public-supported alternative to commercial media. Home to one of the most listened-to public radio stations in the nation, one of the highest-rated public television services and an award-winning education program, KQED is also a leader and innovator in interactive media and technology, taking people of all ages on journeys of exploration – exposing them to new people, places and ideas.

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.
#deeplook #dragonflies #dragonflynymph

Sea otters aren't just cute -- they're a vivid example of life on the edge. Unlike whales and other ocean mammals, sea otters have no blubber. Yet they're still able to keep warm in the frigid Pacific waters. The secret to their survival? A fur coat like no other.

SUBSCRIBE to Deep Look: http://goo.gl/8NwXqt

Find out more about the sea otter's fantastic fur: http://goo.gl/kdPvWV

Check out UC Santa Cruz's Marine Mammal Physiology Project: http://goo.gl/ntwUHp

Find out what Monterey Bay Aquarium is doing to save Southen sea otters: http://goo.gl/bbnxm0

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.

Happy #WorldOtterDay !
#deeplook

Octopuses and cuttlefish are masters of underwater camouflage, blending in seamlessly against a rock or coral. But squid have to hide in the open ocean, mimicking the subtle interplay of light, water, and waves. How do they do it? (And it is NOT OCTOPI)

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

--- How do squid change color?

For an animal with such a humble name, market squid have a spectacularly hypnotic appearance. Streaks and waves of color flicker and radiate across their skin. Other creatures may posses the ability to change color, but squid and their relatives are without equal when it comes to controlling their appearance and new research may illuminate how they do it.

To control the color of their skin, cephalopods use tiny organs in their skin called chromatophores. Each tiny chromatophore is basically a sac filled with pigment. Minute muscles tug on the sac, spreading it wide and exposing the colored pigment to any light hitting the skin. When the muscles relax, the colored areas shrink back into tiny spots.

--- Why do squid change color?

Octopuses, cuttlefish and squid belong to a class of animals referred to as cephalopods. These animals, widely regarded as the most intelligent of the invertebrates, use their color change abilities for both camouflage and communication. Their ability to hide is critical to their survival since, with the exception of the nautiluses, these squishy and often delicious animals live without the protection of protective external shells.

But squid often live in the open ocean. How do you blend in when there's nothing -- except water -- to blend into? They do it by changing the way light bounces off their their skin -- actually adjust how iridescent their skin is using light reflecting cells called iridophores. They can mimic the way sunlight filters down from the surface. Hide in plain sight.

Iridophores make structural color, which means they reflect certain wavelengths of light because of their shape. Most familiar instances of structural color in nature (peacock feathers, mother of pearl) are constant–they may shimmer when you change your viewing angle, but they don't shift from pink to blue.

--- Read the article for this video on KQED Science:
http://ww2.kqed.org/science/20....15/09/08/youre-not-h


--- More great DEEP LOOK episodes:

What Gives the Morpho Butterfly Its Magnificent Blue?
https://www.youtube.com/watch?v=29Ts7CsJDpg

Nature's Mood Rings: How Chameleons Really Change Color
https://www.youtube.com/watch?v=Kp9W-_W8rCM

Pygmy Seahorses: Masters of Camouflage
https://www.youtube.com/watch?v=Q3CtGoqz3ww

--- Related videos from the PBS Digital Studios Network!

Cuttlefish: Tentacles In Disguise - It’s Okay to Be Smart
https://www.youtube.com/watch?v=lcwfTOg5rnc

Why Neuroscientists Love Kinky Sea Slugs - Gross Science
https://www.youtube.com/watch?v=QGHiyWjjhHY

The Psychology of Colour, Emotion and Online Shopping - YouTube
https://www.youtube.com/watch?v=THTKv6dT8rU


--- More KQED SCIENCE:

Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience
KQED Science: http://ww2.kqed.org/science


Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.
#deeplook #squid #octopus

Brown pelicans hit the water at breakneck speed when they catch fish. Performing such dangerous plunges requires technique, equipment, and 30 million years of practice.

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

California’s brown pelicans are one of two pelican species (once considered the same) that plunge from the air to hunt. The rest, like the white pelican, bob for fish at the water’s surface.

The shape of its bill is essential to the birds' survival in these dives, reducing “hydrodynamic drag” — buckling forces, caused by the change from air to water — to almost zero. It’s something like the difference between slapping the water with your palm and chopping it, karate-style.

And while all birds have light, air-filled bones, pelican skeletons take it to an extreme. As they dive, they inflate special air sacs around their neck and belly, cushioning their impact and allowing them to float.

Even their celebrated pouches play a role. An old limerick quips, “A remarkable bird is a pelican / Its beak can hold more than its belly can…” That beak is more than just a fishing net. It’s also a parachute that pops open underwater, helping to slow the bird down.

Behind the pelican’s remarkable resilience (and beaks) lies 30 million years of evolutionary stasis, meaning they haven’t changed much over time.

--- What do pelicans eat?

Pelicans eat small fish like anchovies, sardines, and smelt.

--- How long to pelicans live?

Pelicans live 15-25 years in the wild.

--- How big are pelicans?

Brown pelicans are small for pelicans, but still big for birds, with a 6-8 foot wingspan. Their average weight is 3.5 kg.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....017/04/25/volunteer-

---+ For more information:
U.S. Fish and Wildlife brown pelican page
https://ecos.fws.gov/ecp0/prof....ile/speciesProfile?s

---+ More Great Deep Look episodes:

The Fantastic Fur of Sea Otters
https://www.youtube.com/watch?v=Zxqg_um1TXI

How Do Sharks and Rays Use Electricity to Find Hidden Prey?
https://www.youtube.com/watch?v=JDPFR6n8tAQ

---+ See some great videos and documentaries from the PBS Digital Studios!

Physics Girl: Why Outlets Spark When Unplugging
https://www.youtube.com/watch?v=g1Ld8D2bnJM

Gross Science: Everything You Didn’t Want to Know About Snot
https://www.youtube.com/watch?v=shEPwQPQG4I

---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
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Twitter: https://www.twitter.com/kqedscience

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is also supported by HopeLab, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Smart Family Foundation and the members of KQED.
#deeplook

Are You Smarter Than A Slime Mold? Let’s go ask Joe Hanson: https://youtu.be/K8HEDqoTPgk

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

---+ About Slime Molds

Flip over a rotting log and chances are you’ll see a goopy streak stuck to the wood. If you were to film this goop and play the video back in high speed, you’d see something that might remind you of the 1950s sci-fi classic “The Blob:” a jelly-like creature pulsating in a strange way, a little bit forward, a little bit back, spreading and searching for something to devour.

But this creature isn’t intent on world domination. It’s a slime mold, a very simple organism that is neither plant, nor animal, nor fungus. Unlike the cells of other living beings, which have only one nucleus that carries their genetic information, slime molds can organize into something like a cell with thousands of nuclei. Slime molds may move slowly, but they excite scientists by their ability to get a lot done with very little.

Researchers at the University of California San Diego and UC Davis have been focusing their attention on how slime molds get around, in the hope of inspiring a new generation of soft-bodied robots with medical applications.

Slime molds don’t have legs or any appendages. They eat bacteria and tiny fungi. And they move just by changing their shape.

“It’s intriguing to understand how they can move when they’re softer than the environment,” said UC San Diego engineer Juan Carlos Del Alamo. “The absence of limbs makes it a difficult problem.”

Slime mold’s locomotion is triggered by a chemical reaction. In the lab, Del Alamo and his colleagues cut off small pieces of a bright yellow slime mold called Physarum polycephalum and put them under a microscope. They watched each piece squeeze itself. This contraction is triggered by tiny calcium ions flowing inside it. The slime mold contracts its wall, then sloshes to move the calcium ions back so that they can trigger another contraction – at least that’s the researchers’ hypothesis.

---+ What are slime molds?

Let’s start with what they’re not. They can stand upright and produce spores. But they’re not fungi or plants. When they’re hungry, they spread across the forest chasing food such as tiny fungi or bacteria. But they’re not animals.

---+ Where are slime molds often found?

Slime molds are often found under rotting logs. You can also order the bright yellow slime mold in our video, Physarum polycephalum, from biological supplies companies. They’re fun to grow at home.

---+ What do slime molds eat?

In nature, slime molds eat tiny fungi and bacteria. When they’re grown in the lab, researchers feed them oats.

Read the entire article on KQED Science:
https://ww2.kqed.org/science/2....016/04/19/this-pulsa

---+ More great DEEP LOOK episodes:

Can A Thousand Tiny Swarming Robots Outsmart Nature?
https://www.youtube.com/watch?v=dDsmbwOrHJs

This Mushroom Starts Killing You Before You Even Realize It
https://www.youtube.com/watch?v=bl9aCH2QaQY

Banana Slugs: Secret of the Slime
https://www.youtube.com/watch?v=mHvCQSGanJg&nohtml5=False

---+ More videos and documentaries from the PBS Digital Studios!

Gross Science: Why Am I Obsessed With Gross Stuff?
https://www.youtube.com/watch?v=8dfVN5w3_Y4

BrainCraft: The Prisoner's Dilemma
https://www.youtube.com/watch?v=p1KU7i5hpM8


---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
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---+ About KQED

KQED, an NPR and PBS affiliate based in San Francisco, serves the people of Northern California and beyond with a public-supported alternative to commercial media. KQED is also a leader and innovator in interactive media and technology, taking people of all ages on journeys of exploration — exposing them to new people, places and ideas.

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is also supported by HopeLab, the David B. Gold Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Smart Family Foundation and the members of KQED.
#deeplook

This millipede uses deadly cyanide gas to keep predators at bay. But one beetle can tolerate the toxic defense and rides the millipede like a bucking bronco. Who will win this showdown in the forest?

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Please support us on Patreon! https://www.patreon.com/deeplook

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

---

Across Northern California, as the rainy season is ending and spring is taking hold, bees are buzzing, flowers are growing and hikers are hitting the trails.

But down at ground level, the pastoral scenery is concealing a surprising battle: relentless chemical warfare between bugs.

More than 200 species of millipedes emerge from their underground lairs every year during the winter and early spring months to forage for food and seek mates.

They have to fend off insects, mammals, reptiles and amphibians looking for a tasty meal. But they have a secret weapon – toxic chemicals they shoot from special glands. One Bay Area species, Xystocheir dissecta, carries deadly cyanide and benzaldehyde.

If they’re feeling threatened, these millipedes produce an invisible, odorless hydrogen cyanide gas that they spray at predators, and which is virtually toxic to all organisms. One byproduct is benzaldehyde, which gives off the scent of bitter almonds, as an additional signal that they’re secreting poison.

The millipedes don’t poison themselves, however. They’ve developed an immunity.

The cyanide can kill nearly any other animal trying to dine on the millipedes. Except one.

New research has found that one tough beetle is the only known predator in the world that can survive a direct blast of cyanide gas and keep going.

Brandt Weary, an entomologist, studied these hardy beetles last year for his senior thesis at the University of California Berkeley.

The beetles, known as Promecognathus crassus, love to eat millipedes, even though they are only one-fifth the millipedes’ size.

Weary wanted to know more about how the beetles withstood the millipedes’ tough chemical defense. He found that while many other beetles will avoid the cyanide-spraying millipedes, Promecognathus seeks them out.

--- How many legs do millipedes have?

Most millipedes have between 34-400 legs, and the record is 750!

--- Why do these millipedes “glow” or fluoresce?

One theory behind millipede fluorescence is that it's a warning sign. Moonlight has some UV light, so maybe an animal with better night vision can see the fluorescence even if we can't.

--- Which millipedes produce cyanide?

Only millipedes in the order Polydesmida produce cyanide. It's the largest order of millipedes with about 3500 species.

---+ Read the entire article on KQED Science:

https://www.kqed.org/science/1....939811/this-milliped

---+ For more information:

Kip Will at UC Berkeley: https://ourenvironment.berkele....y.edu/people/kipling
Science on the SPOT: Glowing Millipedes of Alcatraz: https://ww2.kqed.org/quest/201....3/03/19/science-on-t

---+ Shoutout!

?Congratulations ?to these fans for suggesting our *5 favorite common names* for Xystocheir dissecta, on our Community Tab: https://www.youtube.com/channe....l/UC-3SbfTPJsL8fJAPK

#5 Unom Auhasard: Walking rave stick
#4 F E: "Lumilipede"
#3 Mr.salty: " hell no"
#2 Mystery Bomb Noel: "blue galaxy"
#1 Tinkili: "Glowy Feets McGee"

---+ Thank you to our Top Patreon Supporters ($10+ per month)!

Bill Cass, Justin Bull, Daniel Weinstein, Chris B Emrick, Karen Reynolds, Jeremy Lambert, David Deshpande, Daisuke Goto, Bugeyed.fr, WhatzGames, Elizabeth Ann Ditz, Robert Warner, Shirley Washburn, Tatianna Bartlett, KW, Tanya Finch, Elizabeth Wolden, Sayantan Dasgupta, Monica Albe, Willy Nursalim, Jenn's Bowtique, Jane Orbuch, Laurel Przybylski, Johnnyonnyful, Levi Cai, Jason Buberel, Mark Joshua Bernardo, Michael Mieczkowski, Jeanine Womble, Aurora Mitchell, Edwin Rivas, Marjorie D Miller, Companion Cube, Chris Murphy, Joao Ascensao, Two Box Fish, PM Daeley, TierZoo, Robert Amling, Shelley Pearson Cranshaw, Mario Rahmani

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is also supported by the National Science Foundation, the Templeton Religion Trust, the Templeton World Charity Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation and the members of KQED.

#millipede #beetle #deeplook

Support Deep Look on Patreon!! https://www.patreon.com/deeplook

These pocket-sized predators are formidable hunters. But when it comes to hooking up, male mantises have good reason to fear commitment.

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

Mike Maxwell recently finished a ninth season studying the love life of the praying mantises that live around Bishop, a town in California’s Eastern Sierra.

Over that time, he’s seen some unsettlingly strange behaviors.

It’s pretty common knowledge that female mantises sometimes eat males during or after mating — a habit that biologists call “sexual cannibalism.”

But among the bordered mantises that Maxwell researches, it gets weirder than that.

As it turns out, when a male mantis loses his head, it doesn’t mean he loses the urge to procreate.

You read that right. Not only can some male bordered mantises continue mating even while being attacked by their female counterparts, some males are able to mount a female and initiate mating even after getting their heads completely bitten off.

“It’s a really weird, strange behavior,” said Maxwell, “So what’s going on? Why do they do it?”

-- What do praying mantises eat?

Praying mantises are mostly ambush predators that typically eat small animals like grasshoppers, crickets, bees, crickets and butterflies . They use camouflage to hide themselves and wait for their prey to come within striking distance. Then they use their raptorial forelimbs to grab their prey. Spikes on their forelimbs help them hold their prey while they eat.

-- Why do praying mantises eat each other?

Female praying mantises sometimes eat males that approach them to mate. They are only able to do this because mantises are predators and the female mantises are bigger and stronger than the males.

-- Do praying mantises bite?

Most mantises will not bite people but they will pinch people with their forelimbs to defend themselves. It feels a lot like getting bit, trust me.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....017/11/14/praying-ma

---+ For more information:

Dr. Michael Maxwell, National University
https://www.nu.edu/OurPrograms..../CollegeOfLettersAnd

---+ More Great Deep Look episodes:

It’s a Goopy Mess When Pines and Beetles Duke it Out | Deep Look
https://www.youtube.com/watch?v=wR5O48zsbnc

These Whispering, Walking Bats Are Onto Something | Deep Look
https://www.youtube.com/watch?v=l2py029bwhA&t=3s

There's Something Very Fishy About These Trees ... | Deep Look
https://www.youtube.com/watch?v=rZWiWh5acbE&t=1s


---+ See some great videos and documentaries from PBS Digital Studios!

How Your Rubber Ducky Explains Colonialism | Origin of Everything
https://www.youtube.com/watch?v=BWjzOcIIxgM

When Whales Walked | PBS Eons
https://www.youtube.com/watch?v=_OSRKtT_9vw

The Cheerios Effect | It’s OK To Be Smart
https://www.youtube.com/watch?v=mbKAwk-OG_w


---+ Follow KQED Science

KQED Science: http://www.kqed.org/science
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---+ About KQED


KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is also supported by HopeLab, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Smart Family Foundation and the members of KQED.
#deeplook #prayingmantis #mantises

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CORRECTION, 9/26/2018: This episode of Deep Look contains an error in the scientific name of the house centipede. It is Scutigera coleoptrata, not coleoptera. We regret the error. The viewers who caught the mistake will receive a free Deep Look T-shirt, and our gratitude. Thanks for keeping tabs on us!

Voracious, venomous and hella leggy, house centipedes are masterful predators with a knack for fancy footwork. But not all their legs are made for walking, they put some to work in other surprising ways.

SUBSCRIBE to Deep Look! http://goo.gl/8NwXqt

Recognizable for their striking (some might say, repulsive) starburst-like shape, house centipedes have far fewer than the 100 legs their name suggests. They’re born with a modest eight, a count that grows to 30 as they reach adulthood.

If 30 legs sound like more than one critter really needs – perhaps it is. Over the last 450 million years or so, when centipedes split off from other arthropods, evolution has turned some of those walking limbs into other useful and versatile tools.

When it hunts, for example, the house centipede uses its legs as a rope to restrain prey in a tactic called “lassoing.” The tip of each leg is so finely segmented and flexible that it can coil around its victim to prevent escape.

The centipede’s venom-injecting fangs, called forciples, are also modified legs. Though shorter and thicker than the walking limbs, they are multi-jointed , which makes them far more dexterous than the fangs of insects and spiders, which hinge in only one plane.

Because of this dexterity, the centipede’s forciples not only inject venom, but also hold prey in place while the centipede feeds. Then they take a turn as a grooming tool. The centipede passes its legs through the forciples to clean and lubricate their sensory hairs.

Scientists have long noticed that because of their length and the fact that the centipede holds them aloft when it walks, these back legs give the appearance of a second pair antennae. The house centipede looks like it has two heads.

In evolution, when an animal imitates itself, it’s called automimicry. Automimicry occurs in some fish, birds and butterflies, and usually serves to divert predators.

New research suggests that’s not the whole story with the house centipede. Electron microscopy conducted on the centipede’s legs has revealed as many sensory hairs, or sensilla, on them as on the antennae.

The presence of so many sensory hairs suggest the centipede’s long back legs are not merely dummies used in a defensive ploy, but serve a special function, possibly in mate selection. During courtship, both the male and female house centipede slowly raise and lower their antennae and back legs, followed by mutual tapping and probing.

--- Are house centipedes dangerous?

Though they do have venom, house centipedes don’t typically bite humans.

--- Where do house centipedes live?

House centipedes live anywhere where the humidity hovers around 90 percent. That means the moist places in the house: garages, bathrooms, basements. Sometimes their presence can indicate of a leaky roof or pipe.

--- Do house centipedes have 100 legs?

No. An adult house centipede has 30. Only one group of centipedes, called the soil centipedes, actually have a hundred legs or more.

---+ Read the entire article on KQED Science:

https://ww2.kqed.org/science/2....018/09/25/the-house-

---+ For more information:

Visit the centipede page of the Natural History Museum, London:
http://www.nhm.ac.uk/our-scien....ce/our-work/origins-

---+ More Great Deep Look episodes:

How Kittens Go From Clueless to Cute
https://www.youtube.com/watch?v=o1xRlkNwQy8

This Adorable Sea Slug is a Sneaky Little Thief
https://www.youtube.com/watch?v=KLVfWKxtfow

---+ See some great videos and documentaries from the PBS Digital Studios!

Origin of Everything: Why Do People Have Pets?
https://www.youtube.com/watch?v=k2nW7_2VUMc

Hot Mess: What if Carbon Emissions Stopped Tomorrow?
https://www.youtube.com/watch?v=A4kX9xKGeEw

---+ Follow KQED Science:

KQED Science: http://www.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is supported by the Templeton Religion Trust and the Templeton World Charity Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation Fund and the members of KQED.

Chameleons don't change color to match their environment; it’s just the opposite. How do they do it? By manipulating tiny crystals in their skin. Now, UC Berkeley researchers are on a quest to create synthetic chameleon skin inspired by these reptiles’ uncanny ability.

DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

--- How do Chameleons Change Color?

Chameleons are some of the most brilliantly colored animals on the planet. But how did they evolve the ability to change color?

Scientists used to believe that chameleons changed color by spreading out pigments in their skin, much like octopuses or squid do.

The top layer of chameleon skin – called the epidermis – contains yellow pigment cells called xanthophores, and red pigment cells called erythrophores. But the amount of pigment in the cells stays the same, even when the chameleon changes color.

Just beneath the chameleon’s skin is a layer of cells called iridophores. These cells contain microscopic salt crystals, which are arranged in a three-dimensional pattern like oranges stacked on a fruit stand.

When light hits the crystals, some wavelengths are absorbed and some are reflected. The result, to our eyes, is the beautiful rainbow of colors on the chameleon’s skin. But what we’re actually seeing is light that is bouncing off of these tiny crystals. What we perceive as green, for example, is blue wavelengths of light being reflected off the crystals and through the layer of yellow xanthophore cells in the chameleon’s epidermis. The result is bright green skin that contains no green pigment!

The process of changing color is called metachrosis.

--- Why do Chameleons Change Color?

Chameleons don’t change color to match their environment. In fact, it’s just the opposite.

Their baseline is camouflage.

When chameleons are relaxed, they’re mostly green. They naturally blend into their home in the forest canopy. They even mimic leaves by dancing around a little.

But when they feel threatened, annoyed, or just want to show a little swagger, that’s when their color changes.

Scientists once thought that chameleons color-changing abilities allowed them to better camouflage themselves. Most species of chameleons live high in the forest canopy and their various shades of green provide natural camouflage. Even their movement provides camouflage – they dance around to mimic leaves blowing in the wind.

In fact, chameleons change color primarily to communicate with each other, as though they were living mood rings. Males will warn each other about their territory and females will change color to let males know whether they’re interested in breeding.

Chameleons also have a second layer of iridiophore cells just beneath the first. The crystals in that layer are larger and reflect light waves in the infrared wavelengths. This suggests that chameleons are also changing colors to regulate their temperature, according to Milinkovitch. Chameleons are cold-blooded and heat their bodies with the warmth of the sun.

Read the article for this video on KQED Science:
http://ww2.kqed.org/science/20....15/08/25/natures-moo


--- More great DEEP LOOK episodes:

Where Are the Ants Carrying All Those Leaves?
https://www.youtube.com/watch?v=-6oKJ5FGk24

What Happens When You Put a Hummingbird in a Wind Tunnel?
https://www.youtube.com/watch?v=JyqY64ovjfY

Pygmy Seahorses: Masters of Camouflage
https://www.youtube.com/watch?v=Q3CtGoqz3ww

--- Related video from the PBS Digital Studios Network!

Nature's Most Amazing Animal Superpowers - It’s Okay to be Smart
https://www.youtube.com/watch?v=e69yaWDkVGs


--- Other Great Science Videos About Chameleons

How Do Chameleons Change Color? - Veritasium
https://www.youtube.com/watch?v=SQggDnScsvI

True Facts About The Chameleon - zefrank1
https://www.youtube.com/watch?v=UR_byRbXxvs

--- More KQED SCIENCE:

Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience
KQED Science: http://ww2.kqed.org/science


Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.
#deeplook

Rain falls and within seconds dried-up moss that's been virtually dead for decades unfurls in an explosion of green. The microscopic creatures living in the moss come out to feed. Scientists say the genes in these “resurrection plants” might one day protect crops from drought.

DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

How does moss grow?

Mosses don’t have roots. Their porous cells absorb water like a sponge, whenever it’s available.

When there’s no rain, mosses dry out completely and stop photosynthesizing. That is, they stop using carbon dioxide and the light of the sun to grow. They’re virtually dead, reduced to a pile of chemicals, and can stay that way for years. Researchers have found dry, 100-year-old moss samples in a museum that came back to life when water was added.

Read an extended article on how scientists hope to use resurrection plants to create crops that can survive drought:

http://ww2.kqed.org/science/20....15/06/25/these-resur

--

More great Deep Look episodes:

Where Are the Ants Carrying All Those Leaves?
https://www.youtube.com/watch?v=-6oKJ5FGk24

What Happens When You Put a Hummingbird in a Wind Tunnel?
https://www.youtube.com/watch?v=JyqY64ovjfY

Pygmy Seahorses: Masters of Camouflage
https://www.youtube.com/watch?v=Q3CtGoqz3ww

See also another great video from the PBS Digital Studios!

It's Okay to Be Smart: Where Does the Smell of Rain Come From?

https://www.youtube.com/watch?v=lGcE5x8s0B8

KQED Science: http://ww2.kqed.org/science
Tumblr: http://kqedscience.tumblr.com
Twitter: https://www.twitter.com/kqedscience

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is supported by HopeLab, The David B. Gold Foundation; S. D. Bechtel, Jr. Foundation; The Dirk and Charlene Kabcenell Foundation; The Vadasz Family Foundation; Smart Family Foundation and the members of KQED.
#deeplook

Every fall, male tarantulas leave home for good with one thing on their minds: sex. But before these spiders can make the ultimate connection, they have to survive the perils of the open road...which include their potential mates.

Please join our community on Patreon! https://www.patreon.com/deeplook
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DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

--

Every September, a generation of newly mature male tarantulas leave their underground homes to wander the landscape south of La Junta, Colorado, to look for mates. The lucky males will find females, who remain near their dens the whole lives, and possibly mate. But this so-called “migration” is a one‐way trip.

Among the many risks for these itinerant tarantulas, besides running out of time and becoming roadkill, are the local tarantula hawks. The two‐inch long, blue‐and‐gold wasps pounce on the unsuspecting arachnid travelers, hit them with a paralyzing sting, then drag them off to their lairs. Once there, the female wasp lays an egg on the spider that eventually hatches into a larva. The larva burrows inside him to feast and grow before emerging from his body, Alien‐like, as an adult.

If a male does survive long enough to find a den, he courts the female by first “knocking” at the entrance by tapping the ground with his front mouth parts, called pedipalps. He must rely on vibration to communicate his intentions, since tarantulas are mostly blind. If the larger and more dangerous female comes out to investigate, they face off at the den entrance. She may reply with drumming of her own to indicate that she’s receptive ‐‐ or she might try to eat him.

But he’s come prepared. When male tarantulas reach maturity, right before they set out on their quest, they develop a special set of clasps on their front legs called “tibial hooks.” Tibial hooks serve a single purpose: to fasten underneath the female’s fangs during courtship, allowing him to keep danger at arm’s length, so to speak.

--- Are tarantulas dangerous?

Though they do have venom, tarantulas don’t typically bite humans. If they do, the bite hurts no more than a papercut.

--- How long do tarantulas live?

The adult males of this species usually only live ten years, but females can live much longer, 30-40 years.

---+ Read the entire article on KQED Science:

https://www.kqed.org/science/1....950117/tarantulas-ta

---+ For more information:

Visit the Colorado State University Bug Zoo site:
https://bspm.agsci.colostate.edu/the-bug-zoo/

---+ More Great Deep Look episodes about spiders:

Turret Spiders Launch Sneak Attacks From Tiny Towers
https://www.youtube.com/watch?v=9bEjYunwByw

Why the Male Black Widow is a Real Home Wrecker
https://www.youtube.com/watch?v=NpJNeGqExrc

---+ Shoutout!

?Congratulations ?to the following fans on our YouTube community tab for correctly identifying the body part that male tarantulas use for drumming up interest from females - the pedipalps!

Mitchel Castellon
TheWhiteScatterbug
Ian B
Dragim Yutto
Lydia Liu

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JanetFromAnotherPlanet
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lunafaaye
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monoirre
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Two Box Fish

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---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is also supported by the National Science Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Fuhs Family Foundation, Campaign 21 and the members of KQED.

#tarantula #deeplook #spiders

Peregrine falcons catch other birds mid-flight by diving at more than 200 mph. To do it, they need some high-precision gear: special eyesight, talons and aerodynamics that can't be beat.

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DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

---

While known for being the world’s fastest bird–peregrines have been clocked at diving more than 200 miles per hour–these majestic birds were at risk for going extinct 50 years ago. Widespread use of pesticides such as DDT decimated native populations of peregrine falcons.

By 1970, California’s peregrine population had dwindled to only two known nesting pairs statewide. The federal government banned DDT in 1972. And successful restoration efforts spearheaded by organizations like The Peregrine Fund helped revive their numbers. By 1999, they were removed from the federal Endangered Species List. Recent surveys estimate that there are now 300 to 350 nesting pairs in California and more than 2400 pairs nationwide.

---+ Read the entire article on KQED Science:

https://www.kqed.org/science/1....944037/peregrine-fal

--- What’s the origin of the Peregrine Falcon's name?
Peregrine is Latin for "Peregrinus," which means “traveler” or “pilgrim.”

--- How many eyelids do raptors, or birds or prey, like peregrine falcons have?

They have three! Two eyelids are used for closing their eyes, while the third is used for blinking. It’s also called the nictitating membrane and helps to protect their eyes and keep them moist and clean. It’s semi-transparent, so they can actually still see through it when it’s closed.

--- Did you know they have a special bone to protect their eyes?

It’s called a sclerotic ring and helps support and secure their eyeballs within their skulls.

---+ For more information:
Visit The Peregrine Fund
https://www.peregrinefund.org/

---+ More Great Deep Look episodes:

Things With Wings: https://youtu.be/a68fIQzaDBY

---+ Shoutout!

---+ ?Congratulations ?to the following fans for coming up with the best emoji or ASCII tributes to this fine feathered bird in our community tab challenge:

Sandcastle •
ɐɯɹɐʞ ɐıuɐɯ
lieutenant giwaffe
Sectumsempra, b****!
Sweetle pie.3.

Go look at all the entries here!

https://www.youtube.com/channe....l/UC-3SbfTPJsL8fJAPK

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Allen, Aurora Mitchell, Beckie, Ben Espey, Bill Cass, Breanna Tarnawsky, Carl, Chris B Emrick, Chris Murphy, Cindy McGill, Companion Cube, Cory, Daisuke Goto, Daisy Trevino , Daniel Voisine, Daniel Weinstein, David Deshpande, Dean Skoglund, Edwin Rivas, Elizabeth Ann Ditz, Geidi Rodriguez, Gerardo Alfaro, Ivan Alexander, Jane Orbuch, JanetFromAnotherPlanet, Jason Buberel, Jeanne Sommer, Joao Ascensao, johanna reis, Johnnyonnyful, Joshua Murallon Robertson, Justin Bull, Kallie Moore, Karen Reynolds, Katherine Schick, Kendall Rasmussen, Kenia Villegas, Kristell Esquivel, KW, Kyle Fisher, Laurel Przybylski, Leonhardt Wille, Levi Cai, Louis O'Neill, Michael Mieczkowski, Michele Wong, monoirre, Nathan Padilla, Nathan Wright, Nicolette Ray, NoahCXXIII, Pamela Parker, PM Daeley, Ricardo Martinez, riceeater, Richard Shalumov, Rick Wong, Robert Amling, Robert Warner, Sayantan Dasgupta, Shelley Pearson Cranshaw, Shirley Washburn, Sonia Tanlimco, SueEllen McCann, Supernovabetty, Tea Torvinen, TierZoo, Titania Juang, Two Box Fish, WhatzGames, Willy Nursalim


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---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is also supported by the National Science Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Fuhs Family Foundation, Campaign 21 and the members of KQED.

#peregrinefalcon #bird #deeplook

With their big heads and beady black eyes, Jerusalem crickets aren't winning any beauty contests. But that doesn't stop them from finding mates. They use their bulbous bellies to serenade each other with some furious drumming.

Support Deep Look on Patreon! https://www.patreon.com/deeplook
Come join us on our Deep Look Communty Tab: https://www.youtube.com/user/K....QEDDeepLook/communit

--

DEEP LOOK is an ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

Potato Bug. Child of the Earth. Old Bald-Headed Man. Skull Insects. Devil’s Baby. Spawn of Satan. There’s a fairly long list of imaginative nicknames that refer to Jerusalem crickets, those six-legged insects with eerily humanlike faces and prominent striped abdomens. And they can get quite large, too: Some measure over 3 inches long and weigh more than a mouse, so they can be quite unnerving if you see them crawling around in your backyard in summertime.

One individual who finds them compelling, and not creepy, has been studying Jerusalem crickets for over 40 years: David Weissman, a research associate in entomology affiliated with the California Academy of Sciences in San Francisco. He’s now considered the world’s foremost expert, since no one else has been as captivated or singlemindedly devoted to learning more about them.

While much of their general behavior is still not widely understood, Jerusalem crickets typically live solitary lives underground. They’ll emerge at night to scavenge for roots, tubers and smaller insects for their meals. And it’s also when they come out to serenade potential partners with a musical ritual: To attract a mate, adult crickets use their abdomens to drum the ground and generate low-frequency sound waves.

If a male begins drumming and a female senses the vibrations, she’ll respond with a longer drumming sequence so that he’ll have enough time to track her down. The drumming can vary between one beat every other second up to 40 beats per second.

---+ Read the entire article on KQED Science:
https://www.kqed.org/science/1....932923/jerusalem-cri

---+ For more information:

JERUSALEM! CRICKET? (Orthoptera: Stenopelmatidae: Stenopelmatus); Origins of a Common Name https://goo.gl/Y49GAK

---+ More Great Deep Look episodes:

The House Centipede is Fast, Furious, and Just So Extra | Deep Look
https://youtu.be/q2RtbP1d7Kg

Roly Polies Came From the Sea to Conquer the Earth | Deep Look
https://youtu.be/sj8pFX9SOXE

Turret Spiders Launch Sneak Attacks From Tiny Towers | Deep Look
https://youtu.be/9bEjYunwByw

---+ Shoutout!

?Congratulations ? to Piss Dog, Trent Geer, Mario Stankovski, Jelani Shillingford,
and Chaddydaddy who were the first to correctly 3 the species of Jerusalem Cricket relatives of the Stenopelmatoidea superfamily in our episode, over at the Deep Look Community Tab:

https://www.youtube.com/channe....l/UC-3SbfTPJsL8fJAPK

(hat tip to Antonio Garcia, who shared 3 full species names)


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---+ About KQED
KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is also supported by the National Science Foundation, the Templeton Religion Trust, the Templeton World Charity Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation and the members of KQED. #deeplook #jerusalemcrickets #wildlife

When it comes to spotting prey, sharks and rays have a secret sense beyond sight and smell. Tiny goo-filled organs called Ampullae of Lorenzini detect the invisible electric fields produced by all living creatures.

DEEP LOOK: a new ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

How do Sharks and Rays Sense Electric Fields?

Most animals don’t have the ability to detect electric fields. But sharks, rays, skates and sawfish — members of a group called Elasmobranchii — are masters of detecting electric signals. It’s one of their defining features. Elasmobranchs have specialized organs called Ampullae of Lorenzini. These tiny structures allow them to home in on weak bioelectric fields generated by nearby prey.

Elasmobranch’s electrosensory organs are named after a 17th century Italian physician, Stefano Lorenzini, who first identified them while dissecting an electric ray. Lorenzini noticed dozens of tiny pores around the animal’s mouth. Each of the pores led to jelly-filled canals that ended in pocket-like structures that he called ampullae, the Latin word for a type of round-bottomed flask.

Animals emit low frequency electric fields due to a process known as osmoregulation. This process allows the concentration of ions (charged atoms or molecules) to flow between the inside of our bodies and the outside. In order for our cells to stay intact, the flow of ions needs to be balanced.

But balanced doesn’t necessarily mean equal. The concentration of ions within a shrimp’s body is much lower than that of the sea water it swims in. Their voltage, or potential difference generated between the two concentrations across “leaky” surfaces, can then be detected by the ampullae.


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---

Read the article for this video on KQED Science:
http://ww2.kqed.org/science/2015/08/11/sharks-and-rays-sense-electricity-fish-cant-hide/
#deeplook

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Yep, brown marmorated stink bugs are stinky, but that’s not the worst thing about them. They're imported agricultural pests eating their way across North America. But a native enemy from Asia – the tiny samurai wasp – has a particularly nasty method of stopping stink bugs in their tracks.

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DEEP LOOK is an ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Explore big scientific mysteries by going incredibly small.

---

It looks rather harmless at first glance. With a speckled exterior and a shield-like shape, the brown marmorated stink bug doesn’t appear to be any different from any other six-legged insect that might pop up in your garden. But this particular bug, which arrived in the U.S. from Asia in the mid-1990s and smells like old socks when it is squashed, is a real nuisance. Not only can it invade homes by the thousands in the wintertime, it’s one formidable agricultural pest, eating millions of dollars of peaches, apples and other crops since 2010.

Scientists are now investigating a new tactic in the war on the stink bugs: the possibility of relying on one of the bug’s natural enemies, the samurai wasp.

Also native to Asia, this parasitic wasp keeps the stink bug population in check there. How?

---+ Read the entire article on KQED Science:
https://www.kqed.org/science/1....937639/samurai-wasps

---+ For more information:

Brown Marmorated Stink Bug Research at Oregon State University
http://bit.ly/2GB8RFs

---+ More Great Deep Look episodes:

These Hairworms Eat a Cricket Alive and Control Its Mind
https://youtu.be/YB6O7jS_VBM

Jerusalem Crickets Only Date Drummers
https://youtu.be/mHbwC-AIyTE

Turret Spiders Launch Sneak Attacks From Tiny Towers
https://youtu.be/9bEjYunwByw

---+ Shoutout!

?Congratulations ?to bujur10514, Ace _YT13, Iridescent Moonbeam, Salina Tran, and Noke Noke over at the Deep Look Community Tab, for correctly identifying the term 'Thigmotaxis:'

https://www.youtube.com/channe....l/UC-3SbfTPJsL8fJAPK


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Bill Cass, Justin Bull, Daniel Weinstein, David Deshpande, Daisuke Goto, Karen Reynolds, Yidan Sun, Elizabeth Ann Ditz, KW, Shirley Washburn, Tanya Finch, johanna reis, Shelley Pearson Cranshaw, Johnnyonnyful, Levi Cai, Jeanine Womble, Michael Mieczkowski, SueEllen McCann, TierZoo, James Tarraga, Willy Nursalim, Aurora Mitchell, Marjorie D Miller, Joao Ascensao, PM Daeley, Two Box Fish, Tatianna Bartlett, Monica Albe, Jason Buberel

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---+ About KQED
KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios. Deep Look is a project of KQED Science, which is also supported by the National Science Foundation, the Templeton Religion Trust, the Templeton World Charity Foundation, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Fuhs Family Foundation and the members of KQED. #deeplook #stinkbugs #wildlife

Humans aren’t the only creatures that get frustrated. Squirrels do too. One researcher wants to know, could there be an evolutionary benefit to losing your cool?

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DEEP LOOK is a ultra-HD (4K) short video series created by KQED San Francisco and presented by PBS Digital Studios. See the unseen at the very edge of our visible world. Get a new perspective on our place in the universe and meet extraordinary new friends. Explore big scientific mysteries by going incredibly small.

* NEW VIDEOS EVERY OTHER TUESDAY! *

YouTube viewers are well-acquainted with the squirrel genre: Thousands of videos that show squirrels going to great lengths to extract seeds from bird feeders (https://www.youtube.com/watch?v=FgDa_cpgHWs), or the old favorite, squirrels stuffing their cheeks (https://www.youtube.com/watch?v=_15UrPHkVQo).

Maybe squirrels are so popular because we see some of ourselves in them. This is part of what fueled Mikel Delgado’s interest in the fox squirrels she saw at the University of California, Berkeley. An animal behaviorist and doctoral student there, she likes to quote from Charles Darwin’s book “The Descent of Man, and Selection in Relation to Sex,” in which the English naturalist proposed that the differences between humans and other animals aren’t that clear-cut.

“It was controversial because people thought animals were machines and didn’t feel pain,” she said.

Inspired by Darwin, Delgado was intrigued by squirrels’ emotional worlds. The way to tell what they’re feeling, researchers have found, is to watch their tails. When threatened by a predator like a dog, a fox squirrel whips its tail in an s-shaped pattern that researchers call “flagging.”

Delgado wondered what else she could learn from watching squirrels flag their tails. For instance, do they get frustrated, the way that people do? So she devised an experiment to explore this question.

She taught some of the fox squirrels on campus to lift the lid of a plastic box to find a walnut inside. When the squirrel ate the nut, she dropped another one in. This way, she trained the squirrels to expect a walnut when they looked inside. This training was important because frustration is usually defined as not getting what you expect.

Then she replaced the walnut with corn – which squirrels don’t like as much – or left the box empty. These squirrels flagged their tails. For a third group, she locked the box. They flagged their tails the most. They got aggressive, a hallmark of frustration. And they bit, toppled and dragged the box, trying to open it.

That makes Delgado think that perhaps frustration has an evolutionary purpose, that it isn’t just for blowing off steam, but is instead a way to gather up energy to “brute-force” a solution.

--+ Is frustration an emotion?

“It’s a little bit controversial,” said Delgado. “It depends on who you talk to.”

Researchers don’t consider frustration one of the basic, or universal, emotions. In the 1960s, psychologist Paul Ekman identified six universal emotions: joy, anger, sadness, surprise, fear and disgust:

https://www.youtube.com/watch?v=-PFqzYoKkCc

Frustration is related to anger, but researchers don’t consider frustration a basic emotion. “There’s a question as to what exactly it is,” said Delgado. “Sometimes you see it described very specifically as a task: For example, when you expect a soda and you don’t get it from the vending machine. And sometimes you see it described as the response to the task.”

---+ Read the entire article on KQED Science:
https://ww2.kqed.org/science/2....016/09/20/watch-thes

---+ For more information:

The lab of Lucia Jacobs, where Mikel Delgado does her research: http://jacobs.berkeley.edu/

---+ More Great Deep Look episodes:

Can a New “Vaccine” Stem the Frog Apocalypse?
https://www.youtube.com/watch?v=-IXVcyCZVBg

These Crazy Cute Turtles Want Their Lake Back
https://www.youtube.com/watch?v=YTYFdpNpkMY

---+ See some great videos and documentaries from PBS Digital Studios!

BrainCraft: The Power of Sadness in Inside Out
https://www.youtube.com/watch?v=ST97BGCi3-w

PBS Idea Channel: 3 Fallacies For Election Season!
https://www.youtube.com/watch?v=REp4zCum3XY

---+ About KQED

KQED, an NPR and PBS affiliate in San Francisco, CA, serves Northern California and beyond with a public-supported alternative to commercial TV, Radio and web media.

Funding for Deep Look is provided in part by PBS Digital Studios and the John S. and James L. Knight Foundation. Deep Look is a project of KQED Science, which is also supported by HopeLab, the S. D. Bechtel, Jr. Foundation, the Dirk and Charlene Kabcenell Foundation, the Vadasz Family Foundation, the Gordon and Betty Moore Foundation, the Smart Family Foundation and the members of KQED.
#deeplook #squirrel #squirrelbehavior