August 1 - 31, 2025: Issue 645

Sunday Cartoons

Sunday cartoons and animations returns this year. This Issue: Lost Sheep - Paper Stop Motion Short Film by Lukas Rooney

When a three-legged lamb realizes he is different from the other sheep in his flock, he ventures out into the unknown and becomes lost and alone. Determined to bring the lamb home, the kind-hearted shepherd sets out on a rescue mission. The lamb discovers that he may not be able to achieve great things on his own, but he is loved and valued by the shepherd simply for who he is. This heart-warming tale of love and acceptance will leave you feeling inspired and uplifted.

Credits

  • Written, Directed and Animated by Lukas Rooney
  • Music by Andrew Gerlicher
  • Additional Programming by Jesse Haugen

Special Thanks

  • Alyssa Rooney
  • Fritz and Maria Wienecke

 

Peninsula Junior Cricket Club

Website: www.peninsulacricketclub.com.au
Home Ground: Kitchener Park Mona Vale 

Gary Searles, Club Treasurer and Registrar, states;

Peninsula Cricket Club is a large junior cricket club covering from Palm Beach through to Narrabeen.

Our Cricket Blast season commences Oct 15 ( Avalon), Oct 17 (Warriewood) and Oct 18 (Warriewood). Cricket Blast is our entry level cricket program designed to teach the kids the basics of the game before tackling competitive Cricket from U10s.

Competitive Cricket, for U12s and up (we go through to U16s) commences September 13 2025.

The Girls U11s / U13s and Boys U10s and U11s start October 18.

Registrations are now open at: www.peninsulacricketclub.com.au/registration

We are the only Cricket Club in the Barrenjoey Peninsula catchment area - Palm Beach to Narrabeen – and we are Not for Profit. Our primary focus is the children's welfare as they develop their skills, passion and a lifelong love for the wonderful game of cricket.

We have Cricket skill programs, designed to get kids into Cricket - so think Kindy, Year 1 and 2 - available at 3 locations. The cricket skills program runs at Avalon (Wednesday), Warriewood (Friday evening), Warriewood (Saturday morning).

We have modified games, so no helmets, pads etc. These re-designed for children for prior to getting into competition Cricket, for Years 3 and 4. 

Then we also offer Competitive Cricket for U10s and Up for boys. We have 3 girls teams in the U11s, U13s and U15s – and are always wanting to build up more girls playing.

More details are on our Website: www.peninsulacricketclub.com.au

When did the Peninsula Junior Cricket Club begin? 

In 1987 – so the club is coming up on 40 years.

What is your home ground? 

Our main base is Kitchener Park, Mona Vale but our Grassroots program Cricket Blast is held at Warriewood Sports Field.

Who is this for?

We offer Grassroots Cricket (ages 5-9) this teaches the kids coming into the sport the basics of the game through a program of fun, interactive skill sessions and modified games (no pads, helmets, etc ) From U10s and up kids have the ability to register into Competitive / Traditional form of Cricket (with pads, helmets, gloves, harder ball). We provide cricket programs and competitions for Boys and Girls of all abilities between the ages of 5 and 17.

What if you haven’t played cricket before? Is here a coach or training program? 

As a volunteer based club, our coaches come from Parents who have a love for the game or have coached other sports. The club provides the coaches with training and coaches can use the Cricket Australia app to think of fun ways to make training interesting.

What equipment will a player need? 

For Cricket Blast nothing is needed, the club provides all gear - kids do get a Participant pack from Cricket Australia upon registering). 

Once they hit U10s Traditional Cricket the club provides a team kit to all teams which includes everything they need to play - so no outlay initially. We find kids who love the game will get Bats, Pads etc as Christmas and Birthday presents, but generally the club provides everything.

What is the best part about being part of a big team? 

Being part of a Community and meeting new people. Kids get an opportunity to interact with kids from other schools in the area. Cricket can teach kids a lot about resilience and teamwork.

When does the Season start and end? 

Cricket Blast: Oct 18 - runs for 8 weeks in Term 4, then we run another one for 6 weeks in February-March each year.

U12s and up starts Sept 13 including Girls U15s (U12s play Sat afternoon - everyone else is Saturday morning ) 

U10s / U11s / Girls U11s and U13s start Oct 18 (matches go for 2 hours on a Saturday morning)

Who are you playing against? 

There are 8 junior Clubs on the beaches;  Seaforth, Wakehurst, Beacon Hill, Harbord, Cromer, St Augustine's, Collaroy Plateau, and St. Pius. Competition Cricket for Junior Boys and Girls is played all over the peninsula from Seaforth to Avalon and everywhere in between. 

Does the Peninsula Junior Cricket Club have a 'motto'?  

Give Cricket a go!

If you are thinking of playing - give the sport a go, you don’t need to have natural ability - we just want kids playing in Sport and getting in the fresh air, for parents this is a great way to meet new people and be part of a fun club. We are always looking to improve as a club and welcome new volunteers to help run our club.

In what order did the planets in our solar system form?

An artistic rendition of our solar system, including the Sun and eight planets. vjanez/iStock via Getty Images
Christopher Palma, Penn State and Lucas Brefka, Penn State

Curious Kids is a series for children of all ages. If you have a question you’d like an expert to answer, send it to CuriousKidsUS@theconversation.com.


Are planets in the solar system that are closer to the Sun older than the ones further away? – Gavriel, age 10, Paducah, Kentucky


A cloud of collapsing gas created our Sun, the first thing to form in our solar system. This happened about 4½ billion years ago.

Then the planets began to emerge, as the billions of particles of gas and dust left over from the Sun’s formation became a flattened disk.

Known as a protoplanetary disk, it was enormous and surrounded the Sun for billions of miles. Within the disk, the gas and dust particles started to collide, solidify and stick together, like snowflakes clumping together to form snowballs.

As the particles clung together, the microscopic grains became pebble-size objects and then grew and grew. Some became rocks the size of baseballs, others the size of a house, and a few as big as a planet.

This process, called accretion, is how everything in the solar system – planets, moons, comets and asteroids – came into being.

A protoplanetary disk in space, featuring a bright star in the center, reflecting yellow light, and surrounded by swirls of orange dust.
Telescopes can see young solar systems being born. This image is a protoplanetary disk from a distant star in the Milky Way galaxy. NASA/ALMA/ESO/NAOJ/NRAO/A.Isella;/B.Saxton/NRAO/AUI/NSF

The ice line

By studying computer models and observing the creation of other star systems, astronomers like us have learned a lot about the early days of our solar system.

When the Sun was still forming and the protoplanetary disk was making planets, there was a distance from the Sun where it was cold enough for ice to gather. That place, the ice line – sometimes called the snow line – was in what’s now the asteroid belt, which is between Mars and Jupiter.

Today, of course, ice is found on almost every planet, even on Mercury. But back then, only the young protoplanets beyond the ice line were cold enough to have it. The ice, gas and dust, slamming into each other for millions of years, accumulated into enormous bodies that ultimately became giant planets – Jupiter, Saturn, Uranus and Neptune.

While all this was happening, the smaller planets inside the ice line were forming too. But with less raw material to work with, Mercury, Venus, Earth and Mars took much longer.

Today, it’s believed that Jupiter and Saturn, the largest planets, were the first to fully form, both within a few million years. Uranus and Neptune were next, within 10 million years. The inner planets, including Earth, took at least 100 million years, maybe more.

To put it another way, the four planets closest to the Sun are the youngest; the two planets farthest out, the next youngest; and the two in between, the oldest. The difference in age between the youngest and oldest planets is perhaps 90 million years.

That sounds like an enormous age difference, but in space, 90 million years isn’t really that long – less than 1% of the total time the universe has been around. One way to consider it: Think of Earth as a little sister with a big brother, Jupiter, who’s 2 or 3 years older.

The planet Jupiter, multi-colored, multi-banded and sporting the Great Red Spot.
Taken by the Hubble Space Telescope in 2019, this is a photo of Jupiter, the fifth planet out from the Sun. NASA/JPL-Caltech/SwRI/MSSS/Kevin M. Gill (CC-BY)

Location, location, location

Soon after formation the giant worlds began to migrate, moving inward toward the Sun or outward away from the Sun, before finally settling into their final orbits.

For instance, Neptune migrated outward, switching places with Uranus, and pushed a lot of the small, icy bodies into the Kuiper Belt, a place in the outer solar system that’s home to dwarf planets Pluto, Eris and Makemake and millions of comets.

Meanwhile, Jupiter moved inward, and its massive gravity forced some forming planets into the Sun, where they disintegrated. Along the way, Jupiter flung some smaller rocks out of the solar system altogether; the rest went to the asteroid belt.

But most critically, as Jupiter settled into its own orbit, it moved all of the forming objects and likely finalized the location of the remaining inner planets, including Earth.

All of Jupiter’s tugging helped put our planet in the so-called “Goldilocks zone,” a place just the right distance from the Sun, where Earth could have liquid water on its surface and the right temperature for life to evolve. If Jupiter hadn’t formed the way it did, it’s entirely possible life would not have ignited on Earth – and we would not be here today.


Hello, curious kids! Do you have a question you’d like an expert to answer? Ask an adult to send your question to CuriousKidsUS@theconversation.com. Please tell us your name, age and the city where you live.

And since curiosity has no age limit – adults, let us know what you’re wondering, too. We won’t be able to answer every question, but we will do our best.The Conversation

Christopher Palma, Teaching Professor of Astronomy & Astrophysics, Penn State and Lucas Brefka, Ph.D. Student in Astronomy & Astrophysics, Penn State

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Curious Kids: Why do dolphins jump out of the water?

Will Falcon/Shutterstock
Dr Katharina J. Peters, University of Wollongong

Why do dolphins jump out of the water?

Charlize, age 8, Melbourne

Have you ever seen images of dolphins jumping out of the waves and performing impressive acrobatics in the air? Or maybe you’ve seen it in real life?

When a dolphin jumps, it can launch its whole body out of the water. While it looks like fun, it must also be hard work!

So, why do dolphins jump out of the water? There are several possible reasons. Let’s jump in and explore them.

Three dolphins emerging from a wave.
A dolphin can launch its whole body out of the water. Paulphin Photography/Shutterstock

To stay in touch

Dolphins are social animals and live in groups. But it’s hard to see long distances underwater. So, they use the power of sound to stay in contact with each other.

Sound travels much farther underwater than through the air. When dolphins jump, the slap of the landing makes a loud noise, and would be heard some distance away.

Some species, such as spinner dolphins, use jumping to communicate their location to other group members, especially at night. This helps them keep track of each other.

As an aside, spinner dolphins are very skilled jumpers. As the name suggests, they spin up to seven times in the air before landing back in the water!

Spinner dolphins are the acrobats of the sea.

The need for speed

Have you ever tried to walk underwater? You will have felt how hard it is. That’s because water is more dense than air, which creates a “drag”, or resistance.

Dolphins have streamlined bodies to reduce drag, but they still feel it. So, if they want to travel quickly – for example, if they are trying to escape a predator or hunt fish – they sometimes jump.

While in the air, they travel faster than they would through water, and also save energy.

To gather food

Some dolphins weigh less than 50 kilograms, such as the Hector’s dolphin. Others weigh several tonnes, such as an orca.

Either way, when a dolphin crashes back into the water, you can be sure it makes quite a noisy splash.

Some dolphin species, such as dusky dolphins, use this noise to herd fish at the surface to make them easier to capture.

Shaking off hitchhikers

Fish called remoras can attach themselves to dolphins using a sucker on their head. This is good for the fish, because it can keep them safe and they have plenty to eat, such as small parasites and old bits of dolphin skin.

While the remoras don’t hurt the dolphin, they probably slow it down. So dolphins may try to get rid of the little hitchhikers by jumping to dislodge them.

A dolphin calf jumping to remove remoras.

Fighting and frolicking

Dolphins are highly intelligent animals. They have big brains and can learn tricks and solve puzzles. With intelligence also come other traits: playfulness and social behaviour.

Sometimes, that social behaviour can end in a “fight”. Dolphin experts say two dolphins jumping around together might be actually trying to hit each other!

Dolphins also love to frolic – not just with each other but with other marine mammals such as whales and sea lions, with turtles – or even just a piece of seaweed! So they might jump as some sort of “game”.

As you can see, dolphins may jump for a range of reasons – sometimes just because it’s really fun!The Conversation

Dr Katharina J. Peters, Lecturer in Biological Sciences, University of Wollongong

This article is republished from The Conversation under a Creative Commons license. Read the original article.

How can the James Webb Space Telescope see so far?

This is a James Webb Space Telescope image of NGC 604, a star-forming region about 2.7 million light-years from Earth. NASA/ESA/CSA/STScI
Adi Foord, University of Maryland, Baltimore County

Curious Kids is a series for children of all ages. If you have a question you’d like an expert to answer, send it to CuriousKidsUS@theconversation.com.


How does the camera on the James Webb Space Telescope work and see so far out? – Kieran G., age 12, Minnesota


Imagine a camera so powerful it can see light from galaxies that formed more than 13 billion years ago. That’s exactly what NASA’s James Webb Space Telescope is built to do.

Since it launched in December 2021, Webb has been orbiting more than a million miles from Earth, capturing breathtaking images of deep space. But how does it actually work? And how can it see so far? The secret lies in its powerful cameras – especially ones that don’t see light the way our eyes do.

I’m an astrophysicist who studies galaxies and supermassive black holes, and the Webb telescope is an incredible tool for observing some of the earliest galaxies and black holes in the universe.

When Webb takes a picture of a distant galaxy, astronomers like me are actually seeing what that galaxy looked like billions of years ago. The light from that galaxy has been traveling across space for the billions of years it takes to reach the telescope’s mirror. It’s like having a time machine that takes snapshots of the early universe.

By using a giant mirror to collect ancient light, Webb has been discovering new secrets about the universe.

A telescope that sees heat

Unlike regular cameras or even the Hubble Space Telescope, which take images of visible light, Webb is designed to see a kind of light that’s invisible to your eyes: infrared light. Infrared light has longer wavelengths than visible light, which is why our eyes can’t detect it. But with the right instruments, Webb can capture infrared light to study some of the earliest and most distant objects in the universe.

A dog, shown normally, then through thermal imaging, with the eyes, mouth and ears brighter than the rest of the dog.
Infrared cameras, like night-vision goggles, allow you to ‘see’ the infrared waves emitting from warm objects such as humans and animals. The temperatures for the images are in degrees Fahrenheit. NASA/JPL-Caltech

Although the human eye cannot see it, people can detect infrared light as a form of heat using specialized technology, such as infrared cameras or thermal sensors. For example, night-vision goggles use infrared light to detect warm objects in the dark. Webb uses the same idea to study stars, galaxies and planets.

Why infrared? When visible light from faraway galaxies travels across the universe, it stretches out. This is because the universe is expanding. That stretching turns visible light into infrared light. So, the most distant galaxies in space don’t shine in visible light anymore – they glow in faint infrared. That’s the light Webb is built to detect.

A diagram of the electromagnetic spectrum, with radio, micro and infrared waves having a longer wavelength than visible light, while UV, X-ray and gamma rays have shorter wavelengths than visible light.
The rainbow of visible light that you can see is only a small slice of all the kinds of light. Some telescopes can detect light with a longer wavelength, such as infrared light, or light with a shorter wavelength, such as ultraviolet light. Others can detect X-rays or radio waves. Inductiveload, NASA/Wikimedia Commons, CC BY-SA

A golden mirror to gather the faintest glow

Before the light reaches the cameras, it first has to be collected by the Webb telescope’s enormous golden mirror. This mirror is over 21 feet (6.5 meters) wide and made of 18 smaller mirror pieces that fit together like a honeycomb. It’s coated in a thin layer of real gold – not just to look fancy, but because gold reflects infrared light extremely well.

The mirror gathers light from deep space and reflects it into the telescope’s instruments. The bigger the mirror, the more light it can collect – and the farther it can see. Webb’s mirror is the largest ever launched into space.

The JWST's mirror, which looks like a large, roughly hexagonal shiny surface made up of 18 smaller hexagons put together, sitting in a facility. The mirror is reflecting the NASA meatball logo.
Webb’s 21-foot primary mirror, made of 18 hexagonal mirrors, is coated with a plating of gold. NASA

Inside the cameras: NIRCam and MIRI

The most important “eyes” of the telescope are two science instruments that act like cameras: NIRCam and MIRI.

NIRCam stands for near-infrared camera. It’s the primary camera on Webb and takes stunning images of galaxies and stars. It also has a coronagraph – a device that blocks out starlight so it can photograph very faint objects near bright sources, such as planets orbiting bright stars.

NIRCam works by imaging near-infrared light, the type closest to what human eyes can almost see, and splitting it into different wavelengths. This helps scientists learn not just what something looks like but what it’s made of. Different materials in space absorb and emit infrared light at specific wavelengths, creating a kind of unique chemical fingerprint. By studying these fingerprints, scientists can uncover the properties of distant stars and galaxies.

MIRI, or the mid-infrared instrument, detects longer infrared wavelengths, which are especially useful for spotting cooler and dustier objects, such as stars that are still forming inside clouds of gas. MIRI can even help find clues about the types of molecules in the atmospheres of planets that might support life.

Both cameras are far more sensitive than the standard cameras used on Earth. NIRCam and MIRI can detect the tiniest amounts of heat from billions of light-years away. If you had Webb’s NIRCam as your eyes, you could see the heat from a bumblebee on the Moon. That’s how sensitive it is.

Two photos of space, with lots of stars and galaxies shown as little dots. The right image shows more, brighter dots than the left.
Webb’s first deep-field image: The MIRI image is on the left and the NIRCam image is on the right. NASA

Because Webb is trying to detect faint heat from faraway objects, it needs to keep itself as cold as possible. That’s why it carries a giant sun shield about the size of a tennis court. This five-layer sun shield blocks heat from the Sun, Earth and even the Moon, helping Webb stay incredibly cold: around -370 degrees F (-223 degrees C).

MIRI needs to be even colder. It has its own special refrigerator, called a cryocooler, to keep it chilled to nearly -447 degrees F (-266 degrees C). If Webb were even a little warm, its own heat would drown out the distant signals it’s trying to detect.

Turning space light into pictures

Once light reaches the Webb telescope’s cameras, it hits sensors called detectors. These detectors don’t capture regular photos like a phone camera. Instead, they convert the incoming infrared light into digital data. That data is then sent back to Earth, where scientists process it into full-color images.

The colors we see in Webb’s pictures aren’t what the camera “sees” directly. Because infrared light is invisible, scientists assign colors to different wavelengths to help us understand what’s in the image. These processed images help show the structure, age and composition of galaxies, stars and more.

By using a giant mirror to collect invisible infrared light and sending it to super-cold cameras, Webb lets us see galaxies that formed just after the universe began.


Hello, curious kids! Do you have a question you’d like an expert to answer? Ask an adult to send your question to CuriousKidsUS@theconversation.com. Please tell us your name, age and the city where you live.

And since curiosity has no age limit – adults, let us know what you’re wondering, too. We won’t be able to answer every question, but we will do our best.The Conversation

Adi Foord, Assistant Professor of Astronomy and Astrophysics, University of Maryland, Baltimore County

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Why is the object of golf to play as little golf as possible?

Brooke M. Henderson hits a bunker shot during a tournament in Grand Rapids, Mich., on June 12, 2025. Michael Miller/ISI Photos via Getty Images
Patrick Tutka, Purdue University

Curious Kids is a series for children of all ages. If you have a question you’d like an expert to answer, send it to CuriousKidsUS@theconversation.com.


Why is the object of golf to play the least amount of golf? – Bryleigh, age 12, Chandler, Arizona


In most sports, the team or player with the highest score wins, and fans celebrate super-high-scoring games. In golf, it’s the opposite – the lowest score is the champion. And since golf scores are the number of strokes each player needs to get around the course, the object is to do it with as few strokes as possible.

I study sport management, which includes training people to manage golf courses, help run associations that set the rules, and create scoring for golf. When I play golf, I find that it’s a great mental test. If I score poorly on one hole, how do I play the next hole? Will I let frustration cause me to play poorly and score high again, or can I recover?

Skilled players are able to manage each shot, finding the best place to hit the ball so that they leverage the strengths of their game and work with conditions (weather, wind) at the hole they are playing. This allows them to limit the score they get on the hole.

In golf every shot is a stroke, and you play each hole only once. There are no do-overs or second chances, so each move is extremely important for scoring. That’s different from a game like basketball, where you may get a rebound or a second chance to make a particular shot.

Golf originated in Scotland and dates back to the 12th century. Mary, Queen of Scots, was one of the first female players.

Par for the course

Each hole on a golf course is assigned a par score, which is the number of shots the designer believes it will take to play that hole. Almost all golf courses are made up of par 3, par 4 and par 5 shots.

On a par 3, a person is expected to take three shots to put the ball in the hole. That usually begins with a tee shot from the starting point of the hole and then two shots around or on the green area where the hole is cut. Par 4s expect two shots, covering more ground, before they get to the green area; par 5s expect three shots.

Par is designed for each hole and then added up for the course. Most golf courses have 18 holes and a par between 70 and 72.

There also are par 3 courses, where every hole is a par 3, so they can be spaced more closely and players don’t have to hit long drives. And there are short courses with fewer than 18 holes and total pars as low as 27, usually set on smaller properties.

Golfers on the 2024 PGA Tour celebrate holes-in-one and other top shots.

Golfers want their score to be at par, or even lower, for each course. A decent golfer would probably shoot around 90 on an 18-hole, par 72 course. Coming in close to par lets people play together and compete against each other. Imagine that they were all trying to use as many shots as possible: They would never finish a hole, let alone a full round of the course.

Each score is given a name in comparison to par for a given hole. A score two strokes under par is called an eagle, and a score of one under par is called a birdie. When players go over par, it’s a bogey for one stroke over, a double bogey for two strokes over, and so on. There also are less-known terms, such as a snowman, which is shooting an 8 on a hole.

Every shot matters

Other sports that reward the lowest scores or the fewest attempts include darts and pool. For example, in 8-ball or 9-ball pool, the winner is the first person who sinks all of their colors and either the 8 or 9 ball into pockets with the fewest shots. Similarly, both swimming and track and field are won with low scores, although these are based on competitors’ times, not strokes or shots.

Golf requires great concentration and a good understanding of how your shot may move in the air. Players also need strategies for getting around objects in front of them on the course, such as trees, ponds and sand traps, which are also known as bunkers.

Good golfers are able to control relatively closely where their ball lands. But one of my favorite statistics is that the very best professional golfers land their ball within 10 feet of the hole just 1 in 4 times when they hit from 100 yards away.

A sense of humor helps. Baseball great Hank Aaron once said, “It took me 17 years to get 3,000 hits in baseball. It took one afternoon on the golf course.”


Hello, curious kids! Do you have a question you’d like an expert to answer? Ask an adult to send your question to CuriousKidsUS@theconversation.com. Please tell us your name, age and the city where you live.

And since curiosity has no age limit – adults, let us know what you’re wondering, too. We won’t be able to answer every question, but we will do our best.The Conversation

Patrick Tutka, Clinical Associate Professor of Health and Kinesiology, Purdue University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

How does your body make poop?

Sebastian Kaulitzki/Science Photo Library via Getty Images Brian Robert Boulay, University of Illinois Chicago

Curious Kids is a series for children of all ages. If you have a question you’d like an expert to answer, send it to CuriousKidsUS@theconversation.com.


How does your body make poop? Owen, 4, Wakefield, Massachusetts


Much of the food you eat is absorbed by your digestive system, which includes your stomach and your intestines.

But some of what you eat makes it all the way through those twists and turns and comes out the other end as poop. How does that happen?

Imagine you start your day by eating a bowl of crunchy cereal with milk. The process of digestion begins as you start to chew.

Your teeth grind up the cereal into smaller particles, making it easier to swallow and digest. Your saliva contains an enzyme, a kind of chemical, called amylase that starts breaking down the cereal on a molecular level.

I’m a doctor who regularly treats children and adults with digestive problems. Some of my patients have problems absorbing nutrients from their food and others poop too often or not often enough. When they describe their symptoms, I consider the process of how our bodies make poop and which steps can go wrong.

Your stomach is full of enzymes and acid

Everything you eat contains three types of molecules that provide your body with the energy you need to live: carbohydrates, fats and proteins.

Amylase, an enzyme in saliva, begins breaking down the starches, a kind of carbohydrate, while the cereal is still in your mouth.

After you swallow, the milky cereal travels down your esophagus, a tube that carries swallowed food from your mouth to your stomach. That’s where digestion really gets going.

Your stomach contains hydrochloric acid, which breaks the food down into much smaller pieces. Over several hours, that acid and additional enzymes continue to pulverize the carbohydrates and protein from your bowl of cereal.

Diagram of the human gastrointestinal tract
What you ingest travels a long way before what’s left makes an exit. Veronika Zakharova/Science Photo Library via Getty Images

Your long and winding small intestine

Two or three hours later, your breakfast will leave your stomach and enter the small intestine, which is a long and coiled tube that is contained in your abdomen behind your belly button. By that point, the digestive process will have turned those big chunks of cereal into tiny particles that are small enough for your body to absorb.

By coursing through your bloodstream, these teeny particles will deliver energy and the building blocks for growth to the cells all over your body.

The small intestine is perfectly suited to perform the job of absorbing nutrients partly because it’s gigantic. Regardless of your height, it can be over 20 feet (6 meters) long, and its surface is covered with villi, tiny protrusions with a texture that resembles a shag carpet.

Those millions of villi create a huge amount of surface area, which is ideal for absorbing the nutrients in what you’ve eaten once it has been digested. The small intestine also contains many types of bacteria, which assist in breaking down the food particles.

The small intestine also produces more enzymes to help break down the carbohydrates in breads and pasta into simple sugars that are easily absorbed. As food enters into the small intestine, other organs also contribute their digestive juices to the mix.

The liver and gallbladder mix a greenish liquid called bile into the food.

Bile helps break down fats contained in food. Pancreatic enzymes help break down the carbohydrates, fats, proteins and the other nutrients in the food you eat.

Pink picture of the intestines.
Your small intestine and large intestine both have important jobs. Dmytro Lukyanets/iStock via Getty Images Plus

Your slow and short colon

The journey through your small intestine takes between two and six hours to complete. By this point, your bowl of cereal is unrecognizable. It has turned into chyme, a greenish liquid. Chyme gets its color from the bile made in the liver.

As the chyme reaches the end of the small intestine, it enters into your large intestine, also known as the colon. The large intestine gets its name due to being wider than the small intestine, even though it is much shorter.

The colon is about 5 feet (1.5 meters) long. Unlike the villi-lined small intestine, it doesn’t absorb any nutrients. Instead it does another important job: It absorbs water from the slimy green chyme your digestive system made from your breakfast. The small intestine also absorbs water into the bloodstream, where it is delivered to your kidneys to make urine.

So the intestines also play a small part in making your pee, as well as your poop.

This process is much slower than those earlier steps. It can take a whole day, and up to three days, to complete. By the time the chyme reaches the end of the colon, it has solidified and probably turned from green to brown.

The brown color of poop comes from the bile that is added by the liver to your bowl of cereal as it makes its way through the small intestine. The bile is changed by bacteria from green to brown. Without bile your poop would be a pale silver or clay color.

Lots of bacteria

What’s in your poop?

When it leaves your body, poop contains some leftover water, as well as undigested food such as plant fiber, as well as some dead intestinal cells. And, it may surprise you to learn, almost half of it, measured by weight, consists of bacteria.

Your intestines contain trillions of these bacteria, which help you digest what you eat. Unlike some other kinds of bacteria, they do not make you sick. The ones that come out as part of your poop give it that stinky smell.

Each part of your digestive system, from your mouth to your colon, plays an important role in extracting from what you eat the energy and water that your body needs. They all work together to help you absorb most of that energy and water, while eliminating what you do not need.


Hello, curious kids! Do you have a question you’d like an expert to answer? Ask an adult to send your question to CuriousKidsUS@theconversation.com. Please tell us your name, age and the city where you live.

And since curiosity has no age limit – adults, let us know what you’re wondering, too. We won’t be able to answer every question, but we will do our best.The Conversation

Brian Robert Boulay, Associate Professor of Medicine, University of Illinois Chicago

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Grumpy Monkey Compilation

Published by Toadstools and Fairy Dust - more stories at the link

'The Magician's Hat' read by Alison Brie

More stories at: Storyline online

Archive of millions of Historical Children’s Books All Digitised: Free to download or Read Online

Enter the 1: Baldwin Library of Historical Children’s Literature here, where you can browse several categories, search for subjects, authors, titles, etc, see full-screen, zoomable images of book covers, download XML versions, and read all of the 2: over 6,000 books in the collection with comfortable reader views. 

Find 3: more classics in the collection, 800 Free eBooks for iPad, Kindle & Other Devices.


WilderQuest online fun

The NSW National Parks and Wildlife Service is pleased to present the WilderQuest program for teachers, students and children.

The WilderQuest program includes a website and apps with game and video content, Ranger led tours and activities in national parks across NSW. It provides opportunities for families to experience nature, science and Aboriginal culture in classrooms, online, at events and in national parks. The Teacher portal and free primary school resources have been produced with support from our Environmental Trust partners.

Profile: Ingleside Riders Group

Ingleside Riders Group Inc. (IRG) is a not for profit incorporated association and is run solely by volunteers. It was formed in 2003 and provides a facility known as “Ingleside Equestrian Park” which is approximately 9 acres of land between Wattle St and McLean St, Ingleside. 
IRG has a licence agreement with the Minister of Education to use this land. This facility is very valuable as it is the only designated area solely for equestrian use in the Pittwater District.  IRG promotes equal rights and the respect of one another and our list of rules that all members must sign reflect this.
Profile: Pittwater Baseball Club

Their Mission: Share a community spirit through the joy of our children engaging in baseball.

National Geographic for Australian Kids

Find amazing facts about animals, science, history and geography, along with fun competitions, games and more. Visit National Geographic Kids today!

This week the National Geographic for Kids has launched a new free digital resource platform called NatGeo@Home to entertain and educate children affected by school closures.

The three main categories of content on the NatGeo@Home site aim to educate, inspire and entertain. For parents and teachers, there are also separate resources and lesson plans covering everything from getting to grips with Google Earth to learning to label the geological features of the ocean.

For the main Australian National Geographic for Kids, visit: www.natgeokids.com/au

For the National Geographic at Home site, visit:

LEGO AT THE LIBRARY

Mona Vale Library runs a Lego club on the first Sunday of each month from 2pm to 4pm. The club is open to children aged between seven and twelve years of age, with younger children welcome with parental supervision. If you are interested in attending a Lego at the Library session contact the library on 9970 1622 or book in person at the library, 1 Park Street, Mona Vale.

Children's Storytime at Mona Vale LibraryMona Vale Library offers storytime for pre-school children every week during school terms. Children and their carers come and participate in a fun sing-a-long with our story teller as well as listen to several stories in each session, followed by some craft.  

Storytime is held in the Pelican Room of the library in front of the service desk. Storytime is free and no bookings are required. 

Storytime Sessions: Tuesdays  10.00am - 11.00am - Wednesdays  10.00am - 11.00am  - Thursdays  10.00am - 11.00am

Profile: Avalon Soccer Club
Avalon Soccer Club is an amateur club situated at the northern end of Sydney’s Northern Beaches. As a club we pride ourselves on our friendly, family club environment. The club is comprised of over a thousand players aged from 5  who enjoy playing the beautiful game at a variety of levels and is entirely run by a group of dedicated volunteers. 
Avalon Bilgola Amateur Swimming Club Profile

We swim at Bilgola rock pool on Saturday mornings (8:45am till 11:30am). Our season runs between October and March

Profile Bayview Yacht Racing Association (BYRA)

Website: www.byra.org.au

BYRA has a passion for sharing the great waters of Pittwater and a love of sailing with everyone aged 8 to 80 or over!

 Mona Vale Mountain Cub Scouts



Find out more about all the fun you can have at Mona Vale Mountain Cub Scouts Profile
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our Profile pages aren’t just about those who can tell you about Pittwater before you were born, they’re also about great clubs and activities that you too can get involved in!