The building blocks of life — how atoms form in extreme heat
How do atoms form? – Joshua (7), Shoreview, Minnesota, US
Richard Feynman, a famous theoretical physicist who won the Nobel Prize, said that if he could pass on only one piece of scientific information to future generations, it would be that all things are made of atoms.
Understanding how atoms form is a fundamental and important question, since they make up everything with mass.
The question of where atoms come from requires a lot of physics to be answered completely – and even then, physicists like me only have good guesses to explain how some atoms are formed.
What is an atom?
An atom consists of a heavy centre, called the nucleus, made of particles called protons and neutrons. An atom has lighter particles called electrons that you can think of as orbiting the nucleus.
The electrons each carry one unit of negative charge, the protons each carry one unit of positive charge, and the neutrons have no charge. An atom has the same number of protons as electrons, so it is neutral − it has no overall charge.
Now, most of the atoms in the universe are the two simplest kinds: hydrogen, which has one proton, zero neutrons and one electron; and helium, which has two protons, two neutrons and two electrons. Of course, on Earth there are lots of atoms besides these that are just as common, such as carbon and oxygen, but I'll talk about those soon.
An element is what scientists call a group of atoms that are all the same, because they all have the same number of protons.
The first atoms form
Most of the universe's hydrogen and helium atoms formed about 400,000 years after the Big Bang, which is the name for when scientists think the universe began, about 14 billion years ago.
Why did they form at that time? Astronomers know from observing distant exploding stars that the size of the universe has been getting bigger since the Big Bang. When the hydrogen and helium atoms first formed, the universe was about 1,000 times smaller than it is now.
Before this time, the electrons had too much energy to settle into orbits around the hydrogen and helium nuclei. So, the hydrogen and helium atoms could form only once the universe cooled down to something like 2,760 degrees Celsius. For historical reasons, this process is misleadingly called recombination, but combination would be more descriptive.
The helium and deuterium − a heavier form of hydrogen − nuclei formed even earlier, just a few minutes after the Big Bang, when the temperature was above 556 million degrees Celsius. Protons and neutrons can collide and form nuclei like these only at very high temperatures.
Scientists believe that almost all the ordinary matter in the universe is made of about 90% hydrogen atoms and 8% helium atoms.
How do more massive atoms form?
So, the hydrogen and helium atoms formed during recombination, when the cooler temperature allowed electrons to fall into orbits. But you, I and almost everything on Earth is made of many more massive atoms than just hydrogen and helium. How were these atoms made?
The surprising answer is that more massive atoms are made in stars. To make atoms with several protons and neutrons stuck together in the nucleus requires the type of high-energy collisions that occur in very hot places. The energy needed to form a heavier nucleus needs to be large enough to overcome the repulsive electric force that positive charges, like two protons, feel.
Protons and neutrons also have another property – kind of like a different type of charge – that is strong enough to bind them together once they are able to get very close together. This property is called the strong force, and the process that sticks these particles together is called fusion.
Scientists believe that most of the elements from carbon up to iron are fused in stars heavier than our sun, where the temperature can exceed 556 million degrees Celsius – the same temperature that the universe was when it was a few minutes old.
But even in hot stars, elements heavier than iron and nickel won't form. These require extra energy, because the heavier elements can more easily break into pieces.
In a dramatic event called a supernova, the inner core of a heavy star suddenly collapses after it runs out of fuel to burn. During the powerful explosion this collapse triggers, elements that are heavier than iron can form and get ejected into the universe.
Astronomers are still figuring out the details of other fantastic stellar events that form larger atoms. For example, colliding neutron stars can release enormous amounts of energy – and elements such as gold – on their way to forming black holes.
Understanding how atoms are made requires learning a little general relativity, plus some nuclear, particle and atomic physics. But to complicate matters, there is other stuff in the universe that doesn't appear to be made from normal atoms at all, called dark matter. Scientists are investigating what dark matter is and how it forms. DM
First published by The Conversation.
Stephen L Levy is associate professor of physics, applied physics and astronomy at the State University of New York at Binghamton.
This story first appeared in our weekly Daily Maverick 168 newspaper, which is available countrywide for R35.
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
eNCA
a day ago
- eNCA
China urges global consensus on balancing AI development, security
BEIJING - China's Premier Li Qiang warned Saturday that artificial intelligence development must be weighed against the security risks, saying global consensus was urgently needed even as the tech race between Beijing and Washington shows no sign of abating. His remarks came just days after US President Donald Trump unveiled an aggressive low-regulation strategy aimed at cementing US dominance in the fast-moving field, promising to "remove red tape and onerous regulation" that could hinder private sector AI development. Opening the World AI Conference (WAIC) in Shanghai on Saturday, Li emphasised the need for governance and open-source development, announcing the establishment of a Chinese-led body for international AI cooperation. "The risks and challenges brought by artificial intelligence have drawn widespread attention... How to find a balance between development and security urgently requires further consensus from the entire society," the premier said. He gave no further details about the newly announced organisation, though state media later reported "the preliminary consideration" was that it would be headquartered in Shanghai. The organisation would "promote global governance featuring extensive consultation, joint contribution and shared benefits", state news agency Xinhua reported, without elaborating on its set-up or mechanisms. At a time when AI is being integrated across virtually all industries, its uses have raised major questions, including about the spread of misinformation, its impact on employment and the potential loss of technological control. In a speech at WAIC on Saturday, Nobel Prize-winning physicist Geoffrey Hinton compared the situation to keeping "a very cute tiger cub as a pet". To survive, he said, you need to ensure you can train it not to kill you when it grows up. - Pledge to share AI advances - The enormous strides AI technology has made in recent years have seen it move to the forefront of the US-China rivalry. Premier Li said China would "actively promote" the development of open-source AI, adding Beijing was willing to share advances with other countries, particularly developing ones. "If we engage in technological monopolies, controls and blockage, artificial intelligence will become the preserve of a few countries and a few enterprises," he said. Vice Foreign Minister Ma Zhaoxu warned against "unilateralism and protectionism" at a later meeting. Washington has expanded its efforts in recent years to curb exports of state-of-the-art chips to China, concerned that they can be used to advance Beijing's military systems and erode US tech dominance. Li, in his speech, highlighted "insufficient supply of computing power and chips" as a bottleneck to AI progress. China has made AI a pillar of its plans for technological self-reliance, with the government pledging a raft of measures to boost the sector. In January, Chinese startup DeepSeek unveiled an AI model that performed as well as top US systems despite using less powerful chips. - 'Defining test' - In a video message played at the WAIC opening ceremony, UN Secretary-General Antonio Guterres said AI governance would be "a defining test of international cooperation". The ceremony saw the French president's AI envoy, Anne Bouverot, underscore "an urgent need" for global action and for the United Nations to play a "leading role". Bouverot called for a framework "that is open, transparent and effective, giving each and everyone an opportunity to have their views taken into account". Li's speech "posed a clear contrast to the Trump administration's 'America First' view on AI" and the US measures announced this week, said WAIC attendee George Chen, a partner at Washington-based policy consultancy The Asia Group. "The world is now clearly divided into at least three camps: the United States and its allies, China (and perhaps many Belt and Road or Global South countries), and the EU -- which prefers regulating AI through legislation, like the EU AI Act," Chen told AFP. At an AI summit in Paris in February, 58 countries including China, France and India -- as well as the European Union and African Union Commission -- called for enhanced coordination on AI governance. But the United States warned against "excessive regulation", and alongside the United Kingdom, refused to sign the summit's appeal for an "open", "inclusive" and "ethical" AI.
Daily Maverick
4 days ago
- Daily Maverick
The building blocks of life — how atoms form in extreme heat
Most of the universe is made up of hydrogen and helium atoms, which came into being after the Big Bang cooled down a little. Heavier atoms are formed during high-energy collisions in stars. How do atoms form? – Joshua (7), Shoreview, Minnesota, US Richard Feynman, a famous theoretical physicist who won the Nobel Prize, said that if he could pass on only one piece of scientific information to future generations, it would be that all things are made of atoms. Understanding how atoms form is a fundamental and important question, since they make up everything with mass. The question of where atoms come from requires a lot of physics to be answered completely – and even then, physicists like me only have good guesses to explain how some atoms are formed. What is an atom? An atom consists of a heavy centre, called the nucleus, made of particles called protons and neutrons. An atom has lighter particles called electrons that you can think of as orbiting the nucleus. The electrons each carry one unit of negative charge, the protons each carry one unit of positive charge, and the neutrons have no charge. An atom has the same number of protons as electrons, so it is neutral − it has no overall charge. Now, most of the atoms in the universe are the two simplest kinds: hydrogen, which has one proton, zero neutrons and one electron; and helium, which has two protons, two neutrons and two electrons. Of course, on Earth there are lots of atoms besides these that are just as common, such as carbon and oxygen, but I'll talk about those soon. An element is what scientists call a group of atoms that are all the same, because they all have the same number of protons. The first atoms form Most of the universe's hydrogen and helium atoms formed about 400,000 years after the Big Bang, which is the name for when scientists think the universe began, about 14 billion years ago. Why did they form at that time? Astronomers know from observing distant exploding stars that the size of the universe has been getting bigger since the Big Bang. When the hydrogen and helium atoms first formed, the universe was about 1,000 times smaller than it is now. Before this time, the electrons had too much energy to settle into orbits around the hydrogen and helium nuclei. So, the hydrogen and helium atoms could form only once the universe cooled down to something like 2,760 degrees Celsius. For historical reasons, this process is misleadingly called recombination, but combination would be more descriptive. The helium and deuterium − a heavier form of hydrogen − nuclei formed even earlier, just a few minutes after the Big Bang, when the temperature was above 556 million degrees Celsius. Protons and neutrons can collide and form nuclei like these only at very high temperatures. Scientists believe that almost all the ordinary matter in the universe is made of about 90% hydrogen atoms and 8% helium atoms. How do more massive atoms form? So, the hydrogen and helium atoms formed during recombination, when the cooler temperature allowed electrons to fall into orbits. But you, I and almost everything on Earth is made of many more massive atoms than just hydrogen and helium. How were these atoms made? The surprising answer is that more massive atoms are made in stars. To make atoms with several protons and neutrons stuck together in the nucleus requires the type of high-energy collisions that occur in very hot places. The energy needed to form a heavier nucleus needs to be large enough to overcome the repulsive electric force that positive charges, like two protons, feel. Protons and neutrons also have another property – kind of like a different type of charge – that is strong enough to bind them together once they are able to get very close together. This property is called the strong force, and the process that sticks these particles together is called fusion. Scientists believe that most of the elements from carbon up to iron are fused in stars heavier than our sun, where the temperature can exceed 556 million degrees Celsius – the same temperature that the universe was when it was a few minutes old. But even in hot stars, elements heavier than iron and nickel won't form. These require extra energy, because the heavier elements can more easily break into pieces. In a dramatic event called a supernova, the inner core of a heavy star suddenly collapses after it runs out of fuel to burn. During the powerful explosion this collapse triggers, elements that are heavier than iron can form and get ejected into the universe. Astronomers are still figuring out the details of other fantastic stellar events that form larger atoms. For example, colliding neutron stars can release enormous amounts of energy – and elements such as gold – on their way to forming black holes. Understanding how atoms are made requires learning a little general relativity, plus some nuclear, particle and atomic physics. But to complicate matters, there is other stuff in the universe that doesn't appear to be made from normal atoms at all, called dark matter. Scientists are investigating what dark matter is and how it forms. DM First published by The Conversation. Stephen L Levy is associate professor of physics, applied physics and astronomy at the State University of New York at Binghamton. This story first appeared in our weekly Daily Maverick 168 newspaper, which is available countrywide for R35.
IOL News
07-07-2025
- IOL News
Lovebugs swarm South Korea's cities and hiking trails
A portion of Incheon is seen behind a cloud of lovebugs. Image: Jintak Han/The Washington Post Lovebugs - so named for how the male and female cling together as they mate in flight - are swarming South Korea. They can be seen in the hilltops that dot South Korea's bustling cities. They're on the windows of high-rise office buildings. They're on sidewalks, inside convenience stores, on hiking trails and all over city streetlights. They're everywhere. The bugs are harmless, but they are becoming increasingly annoying to the country's more than 50 million residents. 'I thought it was the apocalypse,' said Kim Jaewoong, a 36-year-old welder who ran into a swarm of these bugs last week on Gyeyangsan, a small mountain in the port city of Incheon, an hour drive west of Seoul. Mating lovebugs cover the side of a rock. Image: Jintak Han/The Washington Post Kim was jogging up the mountain on his usual weekend exercise route on Saturday and noticed clumps of dead and live plecia longiforceps, better known as lovebugs. the dark, winged insects typically measure just under half an inch. There were many of them, but Kim shrugged them off, thinking he would see fewer on the mountaintop. At the summit, dead lovebugs were piled up in mounds up to 4 inches tall, he said. Adult lovebugs have a lifespan of three to seven days, according to South Korea's Ministry of Environment. 'It became difficult to breathe. If you tried to breathe, you would get them in your nose and mouth,' he said. The insects are not native to South Korea. The first photographic evidence of the lovebugs in South Korea is from 2015 in Incheon, according to Shin Seunggwan, an associate professor at Seoul National University's School of Biological Sciences. Shin suspects they could be from China's Shandong Peninsula, home to lovebugs whose genetics are the most similar to those in South Korea. 'We haven't confirmed they're from there,' Shin said. 'But it's the likeliest place of origin,' he added. A municipal worker at the Gyeyangsan peak sprays water to clean dead lovebugs off of the stairs. Image: Jintak Han/The Washington Post The lovebugs are expected to abound in South Korea for the next several years, possibly a decade or more, according to Shin. Adult lovebugs have no natural predators and have high breeding rates, he said. Animals that could feed on the insects need time to learn they are edible. It took at least a decade for native animals to recognize other nonindigenous species in Korea like the American bullfrog and Spotted Lanternfly as prey, he said. It took 30 years for adult lovebugs in Florida to become prey, he added. Climate change could be a factor in their proliferation, Shin said. South Korea's temperatures have risen by 1.4 degrees Celsius, or 2.5 degrees Fahrenheit, in the last 30 years compared to the 1912-1941 period, according to government tallies. But the more direct cause for the explosion of the lovebug population here, Shin said, is likelier to be the urban heat island effect - a term used to describe how cities are hotter than rural areas due to the abundance of concrete and the lack of natural shade. Higher temperatures in urban areas - where lovebugs tend to be found - allow more of the insects and their larvae to survive the winter, he said. Gyeyangsan, while covered with trees, is in the urban Incheon area. At the bottom of Gyeyangsan on Thursday, store owners were busy trying to keep out the pesky insects, warning patrons to close the door quickly to prevent more of the insects from entering the establishment. But they were already getting settled - resting on the floor, the freezer windows and the lights.
