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.

What did the T. rex use its little arms for? – Aurora, age 11, Pemberton Township, New Jersey

One of the most famous dinosaurs to ever roam across Earth, Tyrannosaurus rex, has filled people’s minds with wonder since the first skeleton was discovered in the early 1900s.

Scientists believe T. rex, or King of the Tyrant Lizards, as its name translates, was a fearsome predator. An adult T. rex was massive in size – approximately 40 feet (12 meters) long and 20 feet (6 meters) tall, weighing as much as an African elephant. Each of its enormous sharp teeth could be near a foot (0.3 meters) in length from the root to the tip.

I’m a paleontologist, and I use fossils to study how animals lived and evolved over long periods of time. One of the coolest things about being a paleontologist is that there are always new questions to ask and new things to learn – even about a super-well-known dino like T.rex, which went extinct just over 65 million years ago.

One T. rex mystery has to do with this giant predator’s relatively tiny arms. Why would it have arms so short that it couldn’t even reach its own mouth? How did it use them?

How ‘short’ is short?

First, let’s define what we mean by “short.”

The biggest T. rex could measure 45 feet (14 meters) from the snout to the tip of the tail, but their arms were only about 3 feet (1 meter) long. On average, a T. rex’s arms were just about 30% of the length of its legs.

In comparison, humans have, on average, arms around 66% of the length of their legs. If people had the same arm proportions as a T.rex, a 6-foot (1.8 meters) tall person would have arms only 10 or 12 inches (25 to 30 centimeters) long!

T. rex isn’t the only dinosaur with such short arms. The evolutionary trend toward shorter arms in theropods – the larger group of meat-eating, two-legged dinosaurs that T. rex belongs to – happened multiple times. Similar to how wings separately evolved in different animals – like birds and bats – traits can emerge many times in evolutionary history.

You can see the shortening of T. rex arms as a pattern in its family tree, as earlier relatives had proportionally longer arms.

How did they use their mini-arms?

Short arms don’t seem to have been a problem for these mighty dinosaurs. T. rex was a successful carnivorous species that existed for over a million years. They only went extinct when an asteroid hit the Earth, causing a global mass extinction.

Scientists have suggested a few ideas to possibly explain how T. rex used their arms. Maybe they were used as some kind of social display that could impress other T. rex – kind of like the bright feathers of a peacock that can attract potential mates.

But male and female T. rex skeletons don’t show the major differences that paleontologists would take as clues that they relied on social displays to attract mates. And while animal behavior can sometimes be preserved, such as in bite marks or fossilized footprints, it’s rare to have enough fossil data to draw clear conclusions.

Maybe T. rex used their arms as weapons to attack or hold down prey. But these options seem unlikely since T. rex’s huge jaws would have made contact with an enemy or prey before the short arms would have been able to reach it.

Some scientists have recently hypothesized that T. rex‘s short arms were an adaptation to competition with other carnivores. If multiple predators were feeding on a carcass, one could get hurt by accidental bites or even intentional warning bites for getting too close. Shorter arms would be less likely to get chomped. Similar things occur today with territorial carnivores, like Komodo dragons.

Maybe the arms didn’t have a purpose

Another possibility is that the arms served little or no purpose at all, so over time, they became vestigial. That’s the scientific term for body parts that don’t have clear purposes anymore, but are still passed down through evolution.

One example is a whale’s hindlimbs. Whales evolved from mammals that lived on land that had large legs to move around. The bones are still present in today’s whales, but have gotten much smaller over millions of years and have no function.

Some scientists have suggested a different idea: T. rex’s arms may have evolved to be smaller as another body part grew larger. The fossil record reveals that arms got shorter as theropod skulls got larger across many different dinosaur groups, including T. rex. Larger skulls likely would have made it easier to hunt and eat larger prey.

Researchers can use mathematical equations to accurately predict theropod arm length if they know the animal’s skull size and length of its upper leg bone, the femur. It turns out that larger skulls are strongly linked to shorter arms in theropods.

The reason for the change in arms, however, isn’t as clear. Some scientists have argued that the smaller arms could have helped with balance as the head got larger, but others aren’t so sure. In evolution, there isn’t always a reason why a change occurs – sometimes, changes just happen. In this case, we don’t yet know if there was a benefit for the arms to get smaller as heads got larger.

So for now, we don’t really know how T. rex used its arms or why they evolved to be so small, proportionally. As scientists find new data, we will continue to test hypotheses to better understand why this tiny-arm trend occurred so many times in theropod evolution. That’s what makes science so exciting – a future fossil discovery could be the missing puzzle piece that helps us answer these questions.

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.

Sarah Sheffield, Assistant Professor of Earth Sciences, Binghamton University, State University of New York

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 volcanoes erupt? - Nicholas, age 3 years and 11 months, Northmead, NSW.

The rock inside the planet we live on can melt to form molten rock called magma. This magma is lighter than the rocks around it and so it rises upwards. Where the magma eventually reaches the surface we get an eruption and volcanoes form.

The top part of the Earth is made up of a number of hard pieces called tectonic plates. Magma and volcanoes often form where the plates are pulled apart or pushed together but we also find some volcanoes in the middle of tectonic plates.

Volcanoes have many different shapes and sizes, some look like steep mountains (stratovolcanoes), others look like bumps (shield volcanoes) and some are flat with a hole (a crater or caldera) in the centre that is often filled with water.

The shape of the volcano and how explosively it erupts depend largely on how “sticky” and how “fizzy” (how much gas) the magma is that is erupted.

For example, if you try to blow bubbles in cooking oil though a straw, the bubbles can escape quite easily because the cooking oil is runny.

If you try to blow bubbles in jam or peanut butter you would find it very difficult because the jam and peanut butter are very sticky, they wouldn’t move much at all if you tried to pour them out of the jar.

It is the same with volcanoes. When magma rises towards the surface gas bubbles start to form. Whether or not they can escape as the magma is rising affects how explosive the eruption will be.

Where the magma is runny like cooking oil and doesn’t have much bubbly gas mixed in it, such as places like Hawaii, then we see lots of slow-moving lava flows and shield volcanoes. Lava is what we call magma when it reaches the surface.

Here are some pictures of a recent Hawaiian eruption:

However, where the magma is very sticky, like jam or peanut butter, and if it contains a lot of bubbly gas then the gas can get stuck and eruptions can be very powerful and explosive, like the recent eruptions at Fuego volcano in Guatemala.

Damage caused by eruptions

In explosive eruptions the frothy, bubbly magma can be ripped apart into tiny bits called volcanic ash. This is not ash like you get after a barbecue or fire, it does not crumble away in your fingers. It is very sharp and is dangerous to breathe in.

Some explosive volcanoes can send ash high up into the sky and it can travel around the world over different countries. If aeroplanes travel through an ash cloud from a volcano it can cause a lot of damage to the engine.

Other explosive eruptions create fast-moving, hot clouds of volcanic ash, gas and rocks that travel down the sides of the volcanoes and destroy pretty much everything in their path.

The benefits of volcanoes

Despite the great damage they can cause, volcanoes also help us to live. Volcanic ash provides food for the soil around volcanoes which helps us grow plants to eat. The heat from some volcanoes is used to make energy to power lights, fridges, televisions and computers in people’s houses.

You can find some more information about different types of volcanoes here and here.

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

* Email your question to curiouskids@theconversation.edu.au
* Tell us on Twitter by tagging @ConversationEDU with the hashtag #curiouskids, or
* Tell us on Facebook

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.

Heather Handley, Associate Professor in Volcanology and Geochemistry, Macquarie 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.

Hi, I’m Daniel, 12, and I would like to know the history behind squawk codes on aircraft and how they work. Thanks! – Daniel, age 12, Perth.

Thank you, Daniel, for this question. As you have guessed there is a very interesting back story to “squawk codes”. These codes have been used in radio signalling systems for more than 75 years to identify and determine the location of aircraft in flight.

Code name: Parrot

Early radar systems used in the second world war were critical to allied success in the Battle of Britain in 1940, when Britain’s Royal Air Force (RAF) defended the United Kingdom against a huge air attack campaign by Nazi Germany’s air force, the Luftwaffe.

But these early radar systems had a major limitation. They could detect aircraft by radio signals being reflected by moving objects, but the reflected signal could not tell you whether an aircraft was friendly or hostile.

This led to the rapid development of secondary surveillance radars, which required an active and cooperative response from aircraft. In other words, the aircraft had to answer back. This would help to identify the “friendlies” in the skies.

The secondary radar system would send a transmission of radio frequency pulses directed at the aircraft. Friendly aircraft were fitted with equipment that would respond with an identification code. If no response was received, radar operators would presume the aircraft was an enemy plane.

This innovation meant that radar operators could now use the main radars (known as “primary radars”) in combination with the secondary radars to detect the presence of aircraft and to distinguish between friends and foes.

This system was known as Identification Friend or Foe (IFF) and the concept remains important to military forces even today.

The aircraft transponder, which received and transmitted signals, was initially code-named Parrot. Soon, airmen started using the nickname “squawk codes”.

While the name Parrot didn’t last, the term “squawk” continues to be used today to describe the activity of the transponder.

How it works

After the war, the concept was adapted for civil aircraft – the kinds of plane we fly on when we go on holiday.

The system identifies an aircraft through a four-digit octal number (each digit from 0 to 7), which provides for up to 4,096 possible codes. These codes can also be used to alert controllers of an aircraft emergency. Subsequently, another mode was added to inform radar controllers of an aircraft’s height, using data from the plane’s altimeter (the instrument that tells you how high a plane is flying).

For those of you who are technically minded, the frequencies used in secondary surveillance radar are 1030 Megahertz for the interrogation (the “hello, who are you?” signal) and 1090 Megahertz for the response (the answer you get back). The response is a sequence of pulses spaced 1.45 microseconds apart – that’s very fast!

Air traffic control towers

Imagine a pilot is flying a plane full of passengers on holiday to Sydney. As she or he flies towards the destination, the air traffic control tower at Sydney airport sends an interrogation signal. The aircraft automatically responds with a series of short pulses that let air traffic control know the identity of the plane and its altitude. Then air traffic control can compare the identity code to flight plans to identify the aircraft.

The time taken between the interrogation transmission and the received code lets us know the distance between the radar and the aircraft. Air traffic control computer systems use this information, the direction of the interrogation signal, and the altitude to determine exactly where the aircraft is.

Other navigation and airspace management systems have been developed over the years. The most recent is the Automatic Dependent Surveillance Broadcast (ADS-B) system, which incorporates Global Positioning System (GPS) data into the responses from aircraft.

Secondary surveillance radar was an important development in the safety of aviation and remains a key element of airspace management today.

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

* Email your question to curiouskids@theconversation.edu.au
* Tell us on Twitter

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.

Andrew Dowse, Director, Defence Research and Engagement, Edith Cowan 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!

Why can some cups go in the microwave and some not? What happens if you put the wrong cup or plate in the microwave? – Edie, age 8, Melbourne.

Good question, Edie!

The short answer is that it depends on the material the cups and plates are made of, and even what shape they are.

Microwave ovens heat up the food from the inside – using what scientists call “microwaves”.

What are microwaves?

Microwaves are a kind of electromagnetic radiation – just like sunlight, radio waves, and x-rays (like the ones they use to take photos of bones in hospitals).

When you put your food in a microwave oven, the microwaves make the water molecules in the food vibrate or jiggle around really fast. This is how the food heats up.

Why are metals dangerous?

Putting metal in the microwave oven is generally a bad idea. In metals, the electrons – the tiny, negatively charged parts of the atoms – are free to move around. This is why metals conduct electricity, meaning they can carry electricity from one point to another.

The microwaves push and pull the electrons around. With metallic objects that have sharp edges or tips – like aluminium foil or forks – the electrons can build up on the tips. This can lead to sparks and fire.

Other metallic objects may not spark but they can get very hot. That can also lead to a fire depending on what else is inside the microwave.

What materials are microwave safe?

Materials like plastic, glass or ceramics are usually safe to use in the microwave because they don’t contain water and the electrons aren’t free to move around. But we still need to be careful: some plastic containers are too thin and can melt or release plastic into the food.

The bottom line is: it’s hard to tell exactly how something will behave inside a microwave without testing, so the rule of thumb is to only use containers that have been tested and are known to be microwave-safe.

What about the metal grate on the inside of the microwave door?

You’re right! There is a metal grate on the inside of the metal door, with tiny holes in it. I’ll explain why it’s there and why that metal grate doesn’t cause sparks or fire.

Electromagnetic radiation – like sunlight, x-rays and microwaves – all differ in their “wavelengths”. Like waves on the ocean, this is the distance between the peaks of the waves.

Sunlight and microwaves only differ by how far apart are the peaks of the wave. For light, this distance between peaks, that we call the “wavelength”, is very tiny – a thousand times smaller than the width of a hair.

In a typical microwave oven, the wavelength is much larger – about 12cm. This is why they have small holes (of about 1mm) on a metal plate in the door.

The wavelength of light is smaller than the holes and it can get out (so we can see inside), but the wavelength of the microwaves is too big for the hole and they bounce off the metal plate. The microwaves cannot escape.

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:

* Email your question to curiouskids@theconversation.edu.au
* Tell us on Twitter by tagging @ConversationEDU with the hashtag #curiouskids, or
* Tell us on Facebook

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.

Eric Cavalcanti, Senior Lecturer, Griffith 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!

What causes windy weather? – Jake, aged 8, Melbourne.

Thank you for your great question, Jake.

Wind is just moving air, and air is a collection of different gases. It’s mostly one type of gas, called nitrogen, but also lots of others, including oxygen – which we need to live.

When air is under pressure, it starts to move – and that causes wind. I’ll explain what I mean by “under pressure”.

Imagine you are blowing up a balloon. As you blow more air into the balloon, the pressure builds inside. If the pressure gets too great, the balloon could pop because the air has nowhere to move.

Just like the balloon, we don’t like to be under pressure, either. Think of when your brother or sister or slightly annoying cousin gives you a great big bear hug. You feel pressure because you’re getting squeezed. Sometimes that can be nice, but when the squeezing gets too much the best way to get comfortable again is to break free and run. It’s the same with air: when it’s under pressure, it tries to escape.

When the air inside a balloon is under pressure and you take your fingers off the neck part of it, the air rushes out – often with a bit of an embarrassing farty noise. Well, that air rushing out is wind. (And, let’s be honest, it’s why another name for a fart is “breaking wind”.)

In the atmosphere, the same thing happens. When pressure builds up in one place, the air rushes to another place where there is less pressure.

But what is causing this pressure in the atmosphere?

Well, as the sun heats up the surface of the Earth, some areas get warmer and others stay cooler. On the whole globe, for instance, the North and South Poles are really cold. This is because sunbeams pass over the top, so not much sunlight actually hits the ground. Compare this to the equator, where temperatures are really warm, because the sunbeams are hitting it from directly above.

As you may know, warm air rises - just like when you see hot steam coming out the top of your kettle or a cooking pot at home.

My old teacher used to say: “You don’t get something for nothing, Andrew!” What he meant was that if air goes up in one place, it must come down in another place. That other place will be where the air is not rising, and that’s normally where the cool areas are.

As this happens and the air comes down, it hits the ground and starts to build up. When that air piles up too much, that pile of air will collapse and spread out, just like air rushing out of a balloon.

That air will rush towards the area that doesn’t have a big mound of air built up, and that will usually be a warm place where the air is rising.

You can feel this happening at the beach in summer, where the sun heats up the sand more than the water. As heat builds up the air rises over the land and starts to fall over the ocean. Soon there is more air over the ocean than the land, and a breeze starts as that air pile collapses.

So, put simply: wind is just air moving from one place where there is high pressure to another place where there is low pressure (a smaller pile of air).

Often, that’s from where it is cooler to where it is hotter. And, thankfully, it rarely makes that farty sound.

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

* Email your question to curiouskids@theconversation.edu.au
* Tell us on Twitter

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.

Andrew B. Watkins, Manager of Long-range Forecast Services, Australian Bureau of Meteorology

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