Scientists can’t be everywhere all at once, as much as they’d like to. Many of the problems citizen science helps solve are concerned with spreading the net wider – or getting more helping hands on the task.

Biosecurity managers can’t make it to every regional town in their state. But if members of the public report suspicious species, such as through the popular iNaturalist app, they can take action.

Astronomers need more eyes to sift through vast databases of stellar explosions. Climate scientists can learn from our history, but deciphering the records takes time.

Below we introduce five citizen science projects where large numbers of people have contributed impactful results, or yielded new knowledge. Some of them even have new project stages you may be able to participate in.

Science lives far beyond the lab, and it’s not just done by scientists.

In this series, we spotlight the world of citizen science – its benefits, discoveries and how you can participate.

Atlas of Living Australia’s Biosecurity Alerts Service

Andrew Turley, Team Leader – Applications and Biosecurity – Atlas of Living Australia, CSIRO

Australia is one of the world’s most biodiverse continents, but we’re constantly at risk from introduced and invasive species. Even with current border controls, some pests, weeds, and diseases inevitably slip through.

The Atlas of Living Australia (ALA) is the nation’s largest open source biodiversity data source. In partnership with the Department of Agriculture, Fisheries and Forestry, a Biosecurity Alerts Service was set up to connect this trove of data – much of it collected through citizen science – with biosecurity managers across Australia.

The service delivers weekly email notifications to biosecurity managers about new reports of introduced and invasive species of concern in their area. In 2020, this led to the first report of globally invasive Asian shore crab (Hemigrapsus sanguineus). In 2024, an iNaturalist user recorded the first report of the invasive freshwater gold clam (Corbicula fluminea). Early detection allowed biosecurity managers to monitor and mitigate these species’ spread to other areas.

In 2025, an iNaturalist citizen scientist recorded Siam weed north of Brisbane. This record was more than 1,000km from the nearest known infestation, near Townsville. The resulting alert allowed Biosecurity Queensland to eradicate the new infestation. Likewise, reports of the tree cholla cactus, red imported fire ants, honey fungus and many other species have triggered local responses.

This work ultimately helps protect our environment and agricultural systems from the impacts of these introduced and invasive species.

The Biosecurity Alerts Service is ongoing, and every week we send alerts to biosecurity managers across the country. If you use one of the ALA-linked apps – such as iNaturalist, eBird or FrogID, among many others – and choose to share your data publicly, the data you collect will be automatically checked as part of the service.

If you’re lucky, you may even be contacted by a biosecurity officer for more information or to collect a sample to help confirm the species. To get involved, just be curious, visit the outdoors with a biodiversity app, and make sure to record anything that looks odd or out of place.

Climate History Australia

Linden Ashcroft, Senior Lecturer, Climate Science and Science Communication, University of Melbourne

There are millions of valuable weather observations scattered across the world that only exist on paper. It would take thousands of lifetimes for scientists to transcribe these precious records on their own.

But with the help of citizen scientists, we’ve been able to rescue these vital observations from being lost to time. The data they provide have improved the coverage and accuracy of global data models used to understand how our climate is changing.

Climate History Australia was modelled on similar projects from the United Kingdom and New Zealand. Scanned images of historical weather data from the National Archives were split into chunks, allowing people to help us rescue these observations in a manageable way at home.

Across two projects in 2020 and 2021, more than 1,700 citizen scientists transcribed at least 67,400 weather observations recorded in the 19th century. The journals contained meticulous weather data including descriptions of the clouds, type of rainfall, and other activities of the day. The project attracted amazing volunteers, including students, historians, and people who wanted to contribute to climate science.

Thanks to the recovered data, we have now filled gaps in weather observations in Adelaide and Perth, allowing us to build near-continuous records of the weather of these two cities back to 1830 and 1843 respectively. We now know more about extreme weather events in Australia, which is so important because changes in the extremes are what will affect us the most as the world warms.

The rescued data have also fed into global weather and climate datasets, improving our understanding of weather and climate change in the entire Southern Hemisphere. While there are no active Climate History Australia data rescue projects, similar activities are happening in Ireland, Africa and Italy.

Kilonova Seekers

Duncan Galloway, Associate Professor in Astrophysics, Monash University

Since 2023, the Kilonova Seekers citizen astronomy project has been sharing the excitement of transient astronomy, engaging citizen scientists in the discovery of some of the most exciting and energetic events in the universe.

Transient astronomy refers broadly to the study of cosmic objects that vary with time. Many types of normal stars, particularly those that have an orbiting companion, vary in brightness.

But of particular interest are short-lived explosive events that produce gamma-ray bursts, such as the supernova explosions of massive stars, or rare collisions between pairs of neutron stars.

Kilonova Seekers provides observations from the Gravitational-wave Optical Transient Observer (GOTO) telescope network to members of the public. GOTO collaboration members Lisa Kelsey from the University of Cambridge and Tom Killestein from the University of Warwick built an image comparison platform on the popular Zooniverse website.

To contribute, participants were invited to play “spot the difference” by comparing new images to old and looking for changes. This work helps astronomers to distinguish genuine new objects in the sky from imaging artefacts and other spurious signals.

The project has attracted thousands of volunteer observers and yielded more than 200 discoveries to date. A major discovery was published last year – an extremely bright star explosion, GOTO0650, captured as it took place. Once flagged, astronomers were able to look at it more closely with Earth-based and space observatories. The object was so bright, amateur astronomers could capture high-quality images, too.

Kilonova Seekers has just gone through a hardware and software upgrade and relaunched in February this year – so you too can have a hand in trying to discover new objects in space.

Mozzie Monitors

Craig Williams, Professor and Dean of Programs (STEM), Adelaide University

Mosquitoes are the world’s deadliest animal. It’s crucial for health departments and local governments to keep up mosquito surveillance to protect public health. But it takes a lot of resources to do so, leading to gaps in the system.

Launched by the University of South Australia in 2018, the Mozzie Monitors program comprised two main activities citizen scientists could help with. The first was setting low-tech mosquito traps at home and taking photos of the collections so experts could identify them remotely. The second was submitting mosquito images to the project page on the iNaturalist platform. It has been an amazing collaborative effort nationwide, with thousands of records submitted.

Originally, the program aimed to expand mosquito surveillance in Australia, detect exotic mosquitoes entering the country, and educate the public about mosquitoes and the diseases they carry.

It has since evolved to assisting remote communities in exotic mosquito surveillance, tracking mosquito-borne viruses, and running an education program in South Australian and Northern Territory schools. Hundreds of students aged 5–17 have participated in learning activities and even trapped some mosquitoes.

We designed and built Mozzie Monitors as we went along. It’s led to new mosquito trapping methods citizen scientists can use, has taught the participants a lot about mosquitoes, helped to establish a mosquito database with new species records, and even led to the discovery of mosquitoes not previously known to be in Australia.

The project continues to grow and evolve. In the Northern Territory, the small town of Tennant Creek has experienced repeated invasions of exotic dengue mosquitoes. Currently, readers in the Northern Territory anywhere between Katherine and Alice Springs, can become involved in Mozzie Monitors Tennant Creek. While Tennant Creek is the focus, we would dearly love to have participants across the region.

WomSAT: Wombat Survey and Analysis Tool

Julie Old, Associate Professor in Biology, Zoology and Animal Science, Western Sydney University

Hayley Stannard, Associate Professor in Animal Anatomy and Physiology, Charles Sturt University

Wombats are ecological engineers – they dig burrows to sleep in during the day and protect them from predators, but these burrows also provide shelter for other animals. Turning over the soil when they dig their burrows also helps plants grow, moving nutrients and water through the soil.

Due to their importance to ecosystems, there is a need to understand more about wombats and where they live, so that we can manage threats and aid their conservation. Sadly, wombats are at risk from several threats – these include collisions with vehicles, a devastating disease called sarcoptic mange, and habitat loss.

Started in 2015, WomSAT is a citizen science program that allows the public, researchers and wildlife carers to record evidence of wombats across Australia. It collects real-time data on wombat sightings – dead or alive, the location of their burrows, and whether they appear to be affected by mange. Wildlife carers also use WomSAT to track the treatment of sarcoptic mange.

To date, the impacts have been significant: WomSAT has been pivotal to determining roadkill hotspots and tracking sarcoptic mange, and even the factors that affect mange occurrence. In collaboration with the Wombat Protection Society of Australia, the project also created online training courses for the public who have an interest in wombats and wish to learn more, and for wildlife carers on how to safely treat sarcoptic mange in the field.

WomSAT is an ongoing project. Anyone can become a “wombat warrior” by logging sightings of wombats on WomSAT to help identify roadkill hotspots and track the occurrence of sarcoptic mange. You can also follow #WombatWednesday on social media.

Signe Dean, Science + Technology Editor, The Conversation

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

Curious Kids is a series for children. Send your question 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.

Why has nobody found any life outside of Earth? – Anna G, age 12, Strathfield, Sydney.

Anna, thank you for your amazing question.

Astronomers like us are hunting for “Earth-like” planets, but they’re not easy to find. And the conditions needed for life to exist have to be just right.

It’s likely that if such a planet exists, it will be outside our Solar System, and it’s very hard to study planets so far away.

But before we go on, it helps to remember how big the Universe is.

Our place in the Universe

Earth is inside our Solar System, along with the other planets (like Mars, Mercury, and Jupiter) orbiting a star we call the Sun.

But our Solar System is just one of many inside the huge Milky Way galaxy. And the Milky Way is just one of many, many galaxies in the Universe. Plus, we have no way of knowing exactly how big the Universe is beyond what we can directly see.

So while there may be life on other planets, it could be in another solar system in a different part of the Milky Way galaxy. Or in another galaxy far, far away.

We don’t have the technology yet to study such far away planets. But we are still trying to collect what clues we can using the technology we’ve got.

What makes a planet liveable? Follow the water

Much of the search for life has focused on trying to find liquid water, because it is essential for all life forms here on Earth.

Cells are mostly made up of water. Many of the chemical reactions that occur in our metabolism can only occur in the presence of water because it is an incredibly good solvent (meaning it will happily dissolve most things you put in it).

And water is very common. In fact, the components that make up water (hydrogen and oxygen) are the first and third most abundant elements in the Milky Way galaxy.

Oxygen loves grabbing onto other elements to make different chemicals. This means that we find water almost everywhere we look, from the surface of planets in our Solar System, to the depths of interstellar space.

But for life as we know it to exist, you would need a planet where water exists in a liquid state. Otherwise your cells would freeze or boil away.

Earth is in a perfect position from our Sun to support water in a liquid state. Astronomers call this ideal location from a star the “habitable” or “Goldilocks zone”.

Scientists last year discovered that there is permanent liquid water on Mars, which made a lot of people very excited. Water is also inside craters on Mercury, and there are vast water oceans on some of Jupiter’s and Saturn’s moons.

But we still haven’t found life on Mars, or any other planet in our Solar System.

What about outside our Solar System?

Planets outside our Solar System are called exoplanets. They orbit their own stars (as you know, our Sun is really just a big star).

For example, there is an exoplanet called Kepler-22b, which is in the habitable zone of another star called Kepler-22. Kepler 22b is bigger than Earth.

Fainter stars have habitable zones that are closer to them and brighter stars have their habitable zones further away.

Finding a world within a star’s habitable zone where liquid water can exist would be a great start to finding life. Unfortunately, we have not perfected the technology for it yet.

But finding a planet with the right conditions for life isn’t enough; we need to be able to detect signatures of life itself (scientists call these “biosignatures”). For example, we can look at a planet’s atmosphere and see what gases are in it. If we found a planet with lots of oxygen, we can infer there may be life there.

At the moment, it is not possible to detect biosignatures on Earth-like planets around others stars.

Maybe, Anna, you might be one of the scientists who develops the technology that makes all this possible, and will discover the first inhabited world beyond Earth.

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.

Josh Calcino, PhD Candidate, The University of Queensland and Jake Clark, PhD Candidate, University of Southern Queensland

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

Have you ever stayed in the bath or swimming pool for ages and noticed that your fingers and toes went all wrinkly? Well, 11-year-old Maya from London wanted to know why that happens.

She joins our host Eloise to get the answer from biologist Tom Smulders on the first episode of season two of The Conversation’s Curious Kids podcast.

In each episode of The Conversation’s Curious Kids, a curious kid joins host Eloise to ask a top researcher their burning question. There’s an experiment in this episode which you can try out too while you listen. If you want to join in, prepare a bowl of warm water.

To listen to season two, follow us wherever you get your podcasts, or listen on the Yoto Player via the Discover section on the Yoto interactive audio platform for kids.

You can also listen back to season one and read lots of answers to questions sent in by children around the world in our Curious Kids series.

Got a question? Pop it in an email, or record it and send us the audio to curiouskids@theconversation.com.

This season of The Conversation’s Curious Kids is supported by the University of Southampton in the UK, a world-leading research-intensive university with a global network of international students and campuses in Malaysia and Delhi.

Disclosure statement

Tom Smulders does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.

Credits

This episode of The Conversation’s Curious Kids was hosted and mixed by Eloise Stevens. The producer was Katie Flood and the executive producer was Gemma Ware. Sounds of Marlin and Dory getting eaten by, and being inside a whale from Finding Nemo.

Eloise Stevens, Host, The Conversation's Curious Kids podcast, The Conversation and Gemma Ware, Head of Audio, The Conversation UK, The Conversation

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 is a headache? Is it our brain hurting? – Question from the students of Ms Young’s Grade 5/6 class, Baden Powell College, Victoria.

Scientists and doctors define “a headache” as a situation in which your “head” “aches”.

Sorry for getting technical right off the bat, but that’s the simple answer.

If we look a little deeper, things get very interesting: an ache is a kind of pain, but what is pain? And more importantly, why is it happening to your head?

A closer look at pain

Pain is the brain’s way of telling you that things are bad for you. For example, a hot stove or a slammed door can damage your skin and muscle. If you, say, burn your finger or slam a door on it, information about the damage is sent to your brain.

When it arrives there you will, unfortunately, experience it as pain.

As most of us know, pain feels terrible, but it is actually very useful. It is the brain’s way of convincing you not to do things that can hurt you.

“Come on, mate,” you whisper, rubbing your temples, “get to the headaches already.”

Brain pain?

The brain itself (that is, the thinking bits of it) can’t sense damage the way your fingers can. To my knowledge, nobody has accidentally burned their brain on a hot stove, so we can’t ask them what it feels like (as always, do not try this at home, or anywhere else for that matter).

However, we do know that we can poke or even cut a brain and it won’t feel painful to the person. We know this because people can have brain surgery while they are totally awake.

In fact, this is the safest way to do it. That said, I’m sure we can agree that having someone perform surgery on your brain (hopefully, a surgeon) while they also chat to you about the weather is probably a very weird experience.

“Come on, David!” you whisper, grimacing against the light as your patience frays and your headache intensifies. “If the brain can’t sense injury, then why does my head hurt?”

The brain itself can’t sense injury, but do you know what can? The muscles and membranes that surround the brain, and the veins and arteries that run through the brain.

These near-brain but not-brain things can experience things like irritation, inflammation or dehydration. If they do, your brain will interpret this information as pain that is happening inside your head, and so you experience a headache.

This irritation, inflammation or dehydration could occur because you are getting sick, or have banged your head, or spent a hot day in the sun without drinking enough water.

If you do have a headache, it is a good idea to tell your parents or teacher and then have a lie down in a quiet, dark, cool room. If the pain doesn’t go away after a lie down, you might ask your parents for a trip to the doctor.

Sometimes, for some reason that I don’t understand, people around me seem to get a headache when I talk to them about science things (like headaches) for too long.

In this case, getting rid of a headache is a two-step process in which you first wait for me to go away, and then lie down and wait for the pain to go away as normal.

The first bit of good news is that, if I am not the cause of your headache, you just need to do the lying down part.

The second bit of good news is that this is the last sentence of this article about headaches and the headache-inducing nature of pain.

David Farmer is the brains (pun absolutely intended) behind the Melbourne Comedy Festival show “Why You’re Not Dead Yet” which is all about brain function.

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.

David Farmer, Senior Research Officer, Florey Institute of Neuroscience and Mental Health

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.

Could you please tell me how many dinosaurs in total lived on Earth during all periods? - Viren, age 6, Scotch College, Victoria.

This is a really great question.

The short answer is we know of about 900 valid dinosaur species that existed. “Valid” means scientists know the dinosaur from enough of the skeleton bones to feel pretty sure that it differs from all other known dinosaurs. There are hundreds of others which have been named, but are not considered “valid” as they were not based on well-enough preserved fossils.

To give you the long answer, first I need to explain what a dinosaur is, and when they lived.

What exactly is a dinosaur, anyway?

Dinosaurs were a group of medium to large reptiles that lived between 235 million years ago and 66 million years ago. Not many people know this, but the main thing that makes a dinosaur a dinosaur is their foot structure; they have a special kind of ankle joint. Their feet bones are like that of a bird.

Dinosaurs lived during three periods of geological time - the Triassic period (which was 252-201 million years ago), the Jurassic period (about 201-145 million years ago) and the Cretaceous period (145-66 million years ago). These three periods together make up the Mesozoic Era.

Just how many dinosaurs in total lived on Earth during the Mesozoic era is impossible to answer. One study by a Polish scientist called Jerzy Trammer estimated that the total dinosaur combined weight was greater than all the mammals on Earth today, but their individual numbers were much lower than species of today’s living mammals.

Birds are descended from one group of dinosaurs called the predatory theropods. Theropods have hollow bones and three-toed limbs. Dinosaurs from the Tyrannosaurus are a type of predatory theropods. So, technically speaking, all living birds are “living dinosaurs”.

Discovering dinosaurs

Megalosaurus was one of the first dinosaurs to be properly studied. It lived in the Jurassic Period, about 160 million years ago.

The English scientist Richard Owen created the word “dinosaur” in 1842, meaning “terrible lizard” because at the time he thought they were similar looking to large lizards. Today, we know they are not lizards, but a totally different kind of reptile.

Each year scientists dig up more new dinosaurs and get to name them. About 50 new dinosaurs are named every year.

I discovered a new dinosaur based on one bone in the museum collection in Perth. It came from the Geraldton region in Western Australia. It is Australia’s only named Jurassic theropod. I named it Ozraptor, meaning “the Lizard of Aus”.

As the fossil record of life is vastly incomplete, we can only guess that many, many more species existed - but we might never find their fossil remains.

At least we know that many new dinosaurs will continue to be found as expeditions keep going out searching for them every year. Most of the world’s new dinosaurs are coming from China, Mongolia and South America.

I’m really glad you are interested in dinosaurs. Who knows - maybe one day you will be part of an expedition that discovers a new dinosaur. If you found a new dinosaur, what would you name it?

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.

John Long, Strategic Professor in Palaeontology, Flinders 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.

What existed before the big bang? Did something have to be be there in order to go boom? – Ethan, 10, Sydney.

Ethan, what a question. To be truthful, we’re not sure what was before the Big Bang. The whole idea of “before” is not as simple as it sounds – as we’ll soon discover.

But before we get into a total head spin of answering your great question, let’s step all the way back to the beginning of our Universe nearly 14 billion years ago.

A quick recap on the beginning

The Big Bang wasn’t actually a bang. It was not an explosion of metal shards, like in a firework, nor any material; but the rapid expansion of space itself.

At the start, the Universe was infinitely small. Everything around us – the stuff that makes up the galaxies, stars, planets, me and you – was all squished together, creating what is known as a singularity. A singularity has been defined as “a point in space-time where the laws of physics as we know them break down.”

For whatever reason, this singularity rapidly expanded into the Universe we now call home.

After this rapid expansion, our Universe started to cool down – leaving a pattern on the Universe known as the Cosmic Microwave Background.

So if the Big Bang caused the Cosmic Microwave Background, did something else cause the Big Bang?

The time before time?

Your question is nailing an important idea in physics, which we call causality.

In the world we observe around us, all effects must have a cause. Take, for example, a fallen tree. Maybe a vicious storm knocked the tree down. Or maybe it was cut down by a chainsaw-weilding madman.

But if you were to zoom down into the quantum world of atoms (the tiny building blocks of everything), you would notice something very different. In this quantum world, effects can occur without any cause whatsoever.

Long ago in the distant past, our entire Universe was microscopic – just like an atom. Since some effects in the microscopic world do not require causes, it is possible that there was no cause to start off the Big Bang!

And things can get even weirder. It is also possible that time did not exist before the Big Bang. So it may not make any sense to ask what happened “before”. It would be like asking “What part of Earth is north of the North Pole?”. The North Pole is the most northern point on Earth, and so there is nowhere north of it.

But what if something was there before the Big Bang happened?

Beginning the beginning

Some scientists suggest our Universe is the recycled result of another Universe dying and collapsing in on itself. This is known as “the Big Bounce”. This collapsing Universe would meet back to a singularity before bouncing back out, causing the Big Bang and starting off a brand new universe.

In that case, gravity would not only need to stop the Universe from stretching, but bring everything within it back to one single point. Unfortunately, current observations show us that our Universe won’t follow this trend, as it’s stretching out faster than ever before.

Or maybe our Universe is at the other end of a black hole called a white hole. White holes are the hypothetical “opposites” of a black hole, spewing material into space rather than sucking material in.

Or maybe our Universe bubbled out of an even bigger universe! The Cosmic Microwave Background image earlier on shows the leftover radiation isn’t the same all over, but has lumps and bumps concentrated in certain areas. Some cosmologists – people who research how our Universe started – suggest our Universe is one of many universes in the grand multiverse.

The fact is, we don’t really know for sure what started the Big Bang. Maybe you’ll be the very person to answer your question. If you find out, can we please be the first to know?

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.

Jake Clark, PhD Candidate, University of Southern Queensland; Belinda Nicholson, PhD Candidate, University of Southern Queensland, and Josh Calcino, PhD Candidate, The University of Queensland

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