Dinosaurs have captured people’s imagination ever since their bones and teeth were first scientifically described in 1822 by geologist and palaeontologist Gideon Mantell in England.

Dinosaur bones have taught us a great deal about these animals from the “age of dinosaurs”, the Mesozoic Era, which stretched from approximately 252 million years ago to 65 million years ago. However, there’s something especially appealing about a different kind of dinosaur fossil: their tracks, which show researchers what the animals were doing while they were alive.

Ichnology is the study of tracks and traces and, since 2008, the Cape South Coast Ichnology Project has documented more than 370 vertebrate tracksites on South Africa’s southern coast. These sites are from the Pleistocene Epoch, which stretched from approximately 2.6 million years ago to 11,700 years ago, much more recent than the Mesozoic.

We knew that this coastline contained Mesozoic sedimentary rocks, some of which include non-marine sediments that could potentially preserve dinosaur tracks. We are both familiar with dinosaur tracks from our research in Canada, so we decided to investigate the possibility of tracks in South Africa’s Western Cape.

We found some – and, once we knew what to look for, it was evident that the tracks were not rare. In a new paper published in the journal Ichnos, we describe our findings in detail, presenting evidence of tracks of sauropods (enormous plant-eating dinosaurs) and possibly ornithopods (another group of large herbivorous dinosaurs).

The tracks were found in a rugged, remote, breathtakingly spectacular coastal setting. They were made by dinosaurs in a variety of estuarine settings. Some were walking on sandy, inter-tidal channel bars. Others walked on the bottom of tidal channels, their feet sinking down into soft mud forming the bed of the channel. Other vague “squishy” structures were formed by dinosaurs wading, or even wallowing in the muddy fill of abandoned channels.

These tracks are around 140 million years old, from the very beginning of the Cretaceous period when the African and South American tectonic plates were starting to pull apart. Southern Africa has an extensive record of Mesozoic vertebrate fossils, but that record ends at around 180 million years ago in the Early Jurassic with the eruption of voluminous lava flows. To the best of our knowledge, all the southern African dinosaur tracks known until now are from the Triassic and Jurassic periods, so they pre-date these eruptions.

That means these tracks are not only the first from the Western Cape. They also appear to be the youngest – that is, the most recent – thus far reported from southern Africa.

Knowing where to look

After deciding to hunt for potential dinosaur tracks, we visited a few likely sites on the Cape south coast in 2022, choosing areas with non-marine deposits of the appropriate age, mostly in the eastern coastal portion of the Western Cape. We found a few promising spots on that visit and, in 2023, undertook a dedicated examination.

Large horizontal bedding surface exposures in this area are very rare. We knew that, if we were to find dinosaur tracks, they would be evident mostly in profile in vertical cliff exposures.

In the public imagination a dinosaur trackway extends across a level surface and toe impressions are visible. Some may also know that the infill of dinosaur tracks can occur on what are today the ceilings of overhangs or cave roofs. However, there are also distinctive features that allow tracks to be identified in profile. That’s because the animals’ footfalls deformed underlying layers in a distinctive manner.

The problem is that other mechanisms, such as earthquakes, are capable of generating broadly similar deformation structures.

The deposits we were examining had probably also been affected by seismic activity. The challenge was for us to differentiate between the two types of deformation.

The Early Cretaceous rocks that we examined had been studied and reported on decades ago, and the deformation structures had been attributed to origins such as earthquakes rather than living organisms. Since then, however, scientists have developed a better appreciation of what dinosaur tracks look like in profile.

After careful examination, our conclusion was straightforward: both dinosaur-generated and earthquake-generated types of deformation were present in the Cretaceous rocks.

Further evidence that we were looking at dinosaur tracks comes from the region’s bone fossil record. Cretaceous bone material has been reported from the region, mostly in the Kirkwood area in the Eastern Cape province. Two dinosaur bones have also been reported from the Knysna area in the Western Cape. One of these, a theropod tooth, was found – and correctly identified – by a 13-year-old boy.

Clearly, dinosaurs were present in the Western Cape area. That means our discovery of ichnological evidence of their presence is not entirely surprising, but it is still extremely exciting.

Keep exploring

Our team plans to keep exploring deposits of suitable age in the region for evidence of more dinosaur tracks. We also hope that our discovery will inspire a new generation of dinosaur trackers to continue the quest and keep exploring.

Guy Plint, Professor Emeritus, Earth Sciences, Western University and Charles Helm, Research Associate, African Centre for Coastal Palaeoscience, Nelson Mandela University

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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 many types of insects are there in the world? – Sawyer, age 8, Fuquay-Varina, North Carolina

Exploring anywhere on Earth, look closely and you’ll find insects. Check your backyard and you may see ants, beetles, crickets, wasps, mosquitoes and more. There are more kinds of insects than there are mammals, birds and plants combined. This fact has fascinated scientists for centuries.

One of the things biologists like me do is classify all living things into categories. Insects belong to a phylum called Arthropoda – animals with hard exoskeletons and jointed feet.

All insects are arthropods, but not all arthropods are insects. For instance, spiders, lobsters and millipedes are arthropods, but they’re not insects.

Instead, insects are a subgroup within Arthropoda, a class called “Insecta,” that is characterized by six legs, two antennae and three body segments – head, abdomen and the thorax, which is the part of the body between the head and abdomen.

Most insects also have wings, although a few, like fleas, don’t. All have compound eyes, which means insects see very differently from the way people see. Instead of one lens per eye, they have many: a fly has 5,000 lenses; a dragonfly has 30,000. These types of eyes, though not great for clarity, are excellent at detecting movement.

What is a species?

All insects descend from a common ancestor that lived about about 480 million years ago. For context, that’s about 100 million years before any of our vertebrate ancestors – animals with a backbone – ever walked on land.

A species is the most basic unit that biologists use to classify living things. When people use words like “ant” or “fly” or “butterfly” they are referring not to species, but to categories that may contain hundreds, thousands or tens of thousands of species. For example, about 18,000 species of butterfly exist – think monarch, zebra swallowtail or cabbage white.

Basically, species are a group that can interbreed with each other, but not with other groups. One obvious example: bees can’t interbreed with ants.

But brown-belted bumblebees and red-belted bumblebees can’t interbreed either, so they are different species of bumblebee.

Each species has a unique scientific name – like Bombus griseocollis for the brown-belted bumblebee – so scientists can be sure which species they’re talking about.

Quadrillions of ants

Counting the exact number of insect species is probably impossible. Every year, some species go extinct, while some evolve anew. Even if we could magically freeze time and survey the entire Earth all at once, experts would disagree on the distinctiveness or identity of some species. So instead of counting, researchers use statistical analysis to make an estimate.

One scientist did just that. He published his answer in a 2018 research paper. His calculations showed there are approximately 5.5 million insect species, with the correct number almost certainly between 2.6 and 7.2 million.

Beetles alone account for almost one-third of the number, about 1.5 million species. By comparison, there are “only” an estimated 22,000 species of ants. This and other studies have also estimated about 3,500 species of mosquitoes, 120,000 species of flies and 30,000 species of grasshoppers and crickets.

The estimate of 5.5 million species of insects is interesting. What’s even more remarkable is that because scientists have found only about 1 million species, that means more than 4.5 million species are still waiting for someone to discover them. In other words, over 80% of the Earth’s insect biodiversity is still unknown.

Add up the total population and biomass of the insects, and the numbers are even more staggering. The 22,000 species of ants comprise about 20,000,000,000,000,000 individuals – that’s 20 quadrillion ants. And if a typical ant weighs about 0.0001 ounces (3 milligrams) – or one ten-thousandth of an ounce – that means all the ants on Earth together weigh more than 132 billion pounds (about 60 billion kilograms).

That’s the equivalent of about 7 million school buses, 600 aircraft carriers or about 20% of the weight of all humans on Earth combined.

Many insect species are going extinct

All of this has potentially huge implications for our own human species. Insects affect us in countless ways. People depend on them for crop pollination, industrial products and medicine. Other insects can harm us by transmitting disease or eating our crops.

Most insects have little to no direct impact on people, but they are integral parts of their ecosystems. This is why entomologists – bug scientists – say we should leave insects alone as much as possible. Most of them are harmless to people, and they are critical to the environment.

It is sobering to note that although millions of undiscovered insect species may be out there, many will go extinct before people have a chance to discover them. Largely due to human activity, a significant proportion of Earth’s biodiversity – including insects – may ultimately be forever lost.

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.

Nicholas Green, Assistant Professor of Biology, Kennesaw State University

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

This is an article from Curious Kids, a series for children. The Conversation is asking kids to send in questions they’d like an expert to answer. All questions are welcome – serious, weird or wacky! You might also like the podcast Imagine This, a co-production between ABC KIDS listen and The Conversation, based on Curious Kids.

How do mountains get made? - Astrid, age 6, Marrickville

Hello Astrid. You may not believe this but when I was about your age my teacher (Mr Rouve) explained to the class how mountains get made.

He took a sheet of paper and put it flat on the table. Then, he put the tips of his right and left hands’ fingers on each side of the flat sheet and slowly moved his hands toward each other. Try to do it and you will see that the middle part of the paper will lift off the table to form a nice fold.

My teacher explained that mountains form in a similar way, when flat layers of rocks are pushed toward each other they move upward forming tall mountains.

My teacher was really excited by a discovery made by geologists at that time, when I was a kid. These geologists had figured out that the surface of the Earth was, like a giant jigsaw puzzle, made of pieces. Those pieces, called “tectonic plates”, move and bump into each other.

This bumping creates earthquakes, which slowly push the ground surface upward to make mountains. It happens so slowly that, in fact, you are getting taller faster than mountains do, except mountains keep growing and growing and growing for many millions of years until they are so heavy they can no longer grow taller, only wider.

In fact, Australia and New Zealand are sitting on two different “tectonic plates” that move towards each other at the speed of a few centimetres per year. Where they bump into each other, the ground gets lifted to form the stunning New Zealand Alps, the top of which stands close to 4,000 metres. Can you imagine about 4,000 people as tall as you, standing straight up on each other shoulders? That’s how tall these mountains are.

Mountains also form when the Earth’s crust is pushed upward from underneath. At the same time the New Zealand Alps started to form, a large hot bubble of rocks raising from deep in the Earth, like a giant air balloon, was pushing upward the surface of the eastern part of Africa forming a 4,000 metre high plateau. This plateau split to form what is known as the East African Rift, a valley twice as long as the New Zealands Alps.

There are many mountains at the surface of the Earth. Some we can see, some we can’t because they are under the sea. If you could take a submarine and dive under the sea, for instance in the ocean in between Australia and Antarctica, you could visit a long mountain where the Australian and Antarctica tectonic plates move away from each other.

Thank you again for your fantastic question.

Hello, curious kids! Have you got a question you’d like an expert to answer? Ask an adult to send your question to curiouskids@theconversation.edu.au

Please tell us your name, age and which city you live in. We won’t be able to answer every question but we will do our best.

Patrice Rey, Associate Professor, School of Geosciences, University of Sydney

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

Curious Kids is a series for children. If you have a question you’d like an expert to answer, send it to curiouskids@theconversation.edu.au You might also like the podcast Imagine This, a co-production between ABC KIDS listen and The Conversation, based on Curious Kids.

What makes a shooting star fall? – Katelyn, age 7, Adelaide.

Hi Katelyn,

Thanks for asking your fantastic question.

I’ll bet you’ve looked up at the night sky and seen lots of stars. They are beautiful aren’t they? Each star is a huge glowing ball of gas, just like the Sun. Stars look much smaller and fainter than our Sun because they are very far away.

Despite their name, shooting stars are not stars at all. They are tiny space adventurers who accidentally wander into our sky and get sucked toward us by the Earth’s gravity.

Let’s look at the journey of one of these adventurers. I’ll call her Gemma.

Once upon a time there was a tiny speck of dust — space dust — called Gemma. For many years she had spent her time wandering carefree through space and dancing around the planets and the stars.

One day, Gemma noticed a light in the distance. “What’s that?”, she wondered to herself. As she got closer, she saw a beautiful vision of a blue planet, hanging in space like a marble, covered with swirling colours of blue and white. “Wow! That’s the planet Earth,” she said to herself. “Just like I have read about in my books!” (In this story, specks of space dust read books just like you and me).

After spending so long floating through the darkness of space, Gemma felt a strange attraction towards this beautiful new distraction.

It wasn’t just the fascination of Earth. It felt like an invisible force was bringing her slowly closer and closer to this bright globe of light.

The pull of gravity

As Gemma flew closer, she realised that she was being pulled towards the Earth by the force of gravity. “I’ve read about this in my books,” she thought, remembering that gravity is the same force that keeps humans standing on the Earth instead of floating away. The bigger the planet, the stronger its gravity.

As she neared the planet, Gemma could now see the outline of the oceans and the clouds and the sun glinting off the sparkling water.

Suddenly, she noticed the blackness of space was turning into a beautiful blue sky. She had entered the atmosphere of Earth! She had read that the atmosphere was a thick blanket of air, more than 100 kilometres thick that wraps around the surface of our planet and allows all the animals and people to breathe.

As she encountered the air, Gemma felt the chill of deep space subside. She started to feel as warm as a summer’s day. As she jostled and bounced through the air like an aeroplane, she started to glow with an energy and light that she had not felt before. “This must be friction, making me warm — just like the friction when I rub my hands together!” she thought to herself. A lot of friction can make things glow, and Gemma started to glow brighter and brighter.

As her speed increased, Gemma felt like she was on a roller coaster. “Wheeeeeeee!!” she called out with excitement, as she rocketed towards the blue planet, shining like a beautiful, bright star.

All the children on Earth looked up and were very excited to see Gemma, the shooting star from outer space, racing down to join them on Earth. She was just as excited to see them, and to have new friends on this beautiful planet Earth.

Next time you see a shooting star, say hello to Gemma!

Hello, curious kids! Have you got a question you’d like an expert to answer? Ask an adult to send your question to curiouskids@theconversation.edu.au

Please tell us your name, age and which city you live in. We won’t be able to answer every question but we will do our best.

Lisa Harvey-Smith, Professor and Australian Government’s Women in STEM Ambassador, UNSW Sydney

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

This is an article from Curious Kids, a series for children. The Conversation is asking kids to send in questions they’d like an expert to answer. All questions are welcome – serious, weird or wacky! You might also like the podcast Imagine This, a co-production between ABC KIDS listen and The Conversation, based on Curious Kids.

Why do you blink when there is a sudden loud noise close by? – Angus, age 8, Hobart.

When a noise surprises us, our eyes blink without us even realising. It happens unconsciously, without us telling our brain to do it.

This is called a blink reflex. It has an even longer name, actually. We call it “the acoustic startle-reflex eye blink”. The blink happens especially fast - in about a hundredth of a second – so you don’t have time to think about it.

Humans have developed this reflex over many years because it has helped us keep our eyes safe and that has helped us survive.

Eyes are very sensitive, easily damaged and obviously very useful, so they deserve protecting. The loud noise might be a warning that there is something falling nearby, or flying towards you. Our brain tells our eyes to quickly shut, to help protect them from any damage.

The blink reflex also happens when a strange or unfamiliar object touches the outer part of our eye, called the cornea. That one is called the corneal blink reflex.

Our eyes and ears pass messages to special nerves, called the sensory nerves, to cells in the bottom part of our brain, in the brain stem. The part of our brain that receives the message is called the pons.

A message is then sent back to a nerve in our face which controls our eyelid, telling it to close. Because the message only passes through the bottom part of our brain, in the brain stem, we don’t realise the message has been sent. It happens automatically, or unconsciously.

Try closing your eyes for a second now, and then open them again. To do that, a message passed a different part of our brain called the cerebral cortex.

Sudden bright light also causes our eyes to close. This reflex is a little bit different, because it sends a message to the cerebral cortex, so we know when it happens. It also makes it a little bit slower. Bright lights can damage special cells in the back of the eye, which are important to see. We need to avoid very bright light, so you shouldn’t look at the sun.

Startle responses also happen in other parts of the body, like when there is a loud noise, when we suddenly see something, or when we feel a touch or a push we didn’t expect. The responses make some muscles in our jaw, neck, and legs tighten, and releases a hormone, called adrenaline. The startle response makes us more alert, sharpens our senses and gets us ready to run from a threat, or protect ourselves from it. The adrenaline makes the heart beat faster, which we can sometimes feel.

For example, this can happen when something suddenly comes toward your eyes, like a ball flying through the air. You will automatically turn away and cover your eyes, to protect them.

Both humans and animals experience these reflex responses. They happen automatically to help protect us.

Hello, curious kids! Have you got a question you’d like an expert to answer? Ask an adult to send your question to us. You can:

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Please tell us your name, age and which city you live in. You can send an audio recording of your question too, if you want. Send as many questions as you like! We won’t be able to answer every question but we will do our best.

John Furness, Academic, The University of Melbourne

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