Space tourism’s growth blurs the line between scientific and symbolic achievement – a tourism scholar explains how
Blue Origin’s NS-31 flight lifted off on April 14, 2025. Justin Hamel/Getty ImagesBetsy Pudliner, University of Wisconsin-Stout On April 14, 2025, Blue Origin launched six women – Aisha Bowe, Amanda Nguyễn, Gayle King, Katy Perry, Kerianne Flynn and Lauren Sánchez – on a suborbital journey to the edge of space. The headlines called it a historic moment for women in space. But as a tourism educator, I paused – not because I questioned their experience, but because I questioned the language. Were they astronauts or space tourists? The distinction matters – not just for accuracy, but for understanding how experience, symbolism and motivation shape travel today. In tourism studies, my colleagues and I often ask what motivates travel and makes it a meaningful experience. These women crossed a boundary by leaving Earth’s surface. But they also stepped into a controversy about a symbolic one: the blurred line between astronaut and tourist, between scientific achievement and curated experience. This flight wasn’t just about the altitude they flew to – it was about what it meant. As commercial space travel becomes more accessible to civilians, more people are joining spaceflights not as scientists or mission specialists, but as invited guests or paying participants. The line between astronaut and space tourist is becoming increasingly blurred.Blue Origin’s NS-31 flight brought six women to the edge of space. In my own work, I explore how travelers find meaning in the way their journeys are framed. A tourism studies perspective can help unpack how experiences like the Blue Origin flight are designed, marketed and ultimately understood by travelers and the tourism industry. So, were these passengers astronauts? Not in the traditional sense. They weren’t selected through NASA’s rigorous training protocols, nor were they conducting research or exploration in orbit. Instead, they belong to a new category: space tourists. These are participants in a crafted, symbolic journey that reflects how commercial spaceflight is redefining what it means to go to space.
Space tourism as a niche market
Space tourism has its origins in 1986 with the launch of the Mir space station, which later became the first orbital platform to host nonprofessional astronauts. In the 1990s and early 2000s, Mir and its successor, the International Space Station, welcomed a handful of privately funded civilian guests – most notably U.S. businessman Dennis Tito in 2001, often cited as the first space tourist. Space tourism has since evolved into a niche market selling brief encounters to the edge of Earth’s atmosphere. While passengers on the NS-31 flight did not purchase their seats, the experience mirrors those sold by commercial space tourism providers such as Virgin Galactic. Like other forms of niche tourism – wellness retreats, heritage trails or extreme adventures – space travel appeals to those drawn to novelty, exclusivity and status, regardless of whether they purchased the ticket. These suborbital flights may last just minutes, but they offer something far more lasting: prestige, personal storytelling and the feeling of participating in something rare. Space tourism sells the experience of being somewhere few have visited, not the destination itself. For many, even a 10-minute flight can fulfill a deeply personal milestone.
Tourist motivation and space tourism’s evolution
The push-and-pull theory in tourism studies helps explain why people might want to pursue space travel. Push factors – internal desires such as curiosity, an urge to escape or an eagerness to gain fame – spark interest. Pull factors – external elements such as wishing to see the view of Earth from above or experience the sensation of weightlessness – enhance the appeal. Space tourism taps into both. It’s fueled by the internal drive to do something extraordinary and the external attraction of a highly choreographed, emotional experience.Participants in space tourism wear branded jumpsuits with the company’s logo, pose for photos and talk to the media about their experience.AP Photo/Tony Gutierrez These flights are often branded – not necessarily with flashy logos, but through storytelling and design choices that make the experience feel iconic. For example, while the New Shepard rocket the women traveled in doesn’t carry a separate emblem, it features the company’s name, Blue Origin, in bold letters along the side. Passengers wear personalized flight suits, pose for preflight photos and receive mission patches or certificates, all designed to echo the rituals of professional space missions. What’s being sold is an “astronaut-for-a-day” experience: emotionally powerful, visually compelling and rich with symbolism. But under tourism classifications, these travelers are space tourists – participants in a curated, short-duration excursion.
Representation and marketing experience
The image from the Blue Origin flight of six women boarding a rocket was framed as a symbolic victory – a girl-power moment designed for visibility and celebration – but it was also carefully curated. This wasn’t the first time women entered space. Since its inception, NASA has selected 61 women as astronaut candidates, many of them making groundbreaking contributions to space science and exploration. Sally Ride, Mae Jemison, Christina Koch and Jessica Meir not only entered space – they trained as astronauts and contributed significantly to science, engineering and long-duration missions. Their journeys marked historic achievements in space exploration rather than curated moments in tourism. Recognizing their legacy is important as commercial spaceflight creates new kinds of unique, tailored experiences, ones shaped more by media performance than by scientific milestones. The Blue Origin flight was not a scientific mission but rather was framed as a symbolic event. In tourism, companies, marketers and media outlets often create these performances to maximize their visibility. SpaceX has taken a similar approach with its Inspiration4 mission, turning a private orbital flight into a global media event complete with a Netflix documentary and emotional storytelling. The Blue Origin flight sold a feeling of progress while blending the roles between astronaut and guest. For Blue Origin, the symbolic value was significant. By launching the first all-female crew into suborbital space, the company was able to claim a historic milestone – one that aligned them with inclusion – without the cost, complexity or risk associated with a scientific mission. In doing so, they generated enormous media attention.
Tourism education and media literacy
In today’s world, space travel is all about the story that gets told about the flight. From curated visuals to social media posts and press coverage, much of the experience’s meaning is shaped by marketing and media. Understanding that process matters – not just for scholars or industry insiders, but for members of the public, who follow these trips through the narratives produced by the companies’ marketing teams and media outlets. Another theory in tourism studies describes how destinations evolve over time – from exploration, to development, to mass adoption. Many forms of tourism begin in an exploration phase, accessible only to the wealthy or well connected. For example, the Grand Tour of Europe was once a rite of passage for aristocrats. Its legacy helped shape and develop modern travel.As more people travel to a destination over time, it moves through the tourism area life cycle. During the early exploration phase, the destination has only a few tourists.Coba56/Wikimedia Commons Right now, space tourism is in the exploration stage. It’s expensive, exclusive and available only to a few. There’s limited infrastructure to support it, and companies are still experimenting with what the experience should look like. This isn’t mass tourism yet, it’s more like a high-profile playground for early adopters, drawing media attention and curiosity with every launch. Advances in technology, economic shifts and changing cultural norms can increase access to unique destinations that start as out of bounds to a majority of tourists. Space tourism could be the next to evolve this way in the tourism industry. How it’s framed now – who gets to go, how the participants are labeled and how their stories are told – will set the tone moving forward. Understanding these trips helps people see how society packages and sells an inspirational experience long before most people can afford to join the journey. Betsy Pudliner, Associate Professor of Hospitality and Technology Innovation, University of Wisconsin-Stout This article is republished from The Conversation under a Creative Commons license. Read the original article.
When darkness shines: How dark stars could illuminate the early universe
Scientists using the James Webb Space Telescope identified three unusual early-universe objects that may be “dark stars”—not dark, and not quite stars—powered by dark matter annihilation, potentially reshaping how we understand the first stars and the origins of supermassive black holes.
NASA’s James Webb Space Telescope has spotted some potential dark star candidates. NASA, ESA, CSA, and STScIAlexey A. Petrov, University of South Carolina Scientists working with the James Webb Space Telescope discovered three unusual astronomical objects in early 2025, which may be examples of dark stars. The concept of dark stars has existed for some time and could alter scientists’ understanding of how ordinary stars form. However, their name is somewhat misleading. “Dark stars” is one of those unfortunate names that, on the surface, does not accurately describe the objects it represents. Dark stars are not exactly stars, and they are certainly not dark. Still, the name captures the essence of this phenomenon. The “dark” in the name refers not to how bright these objects are, but to the process that makes them shine — driven by a mysterious substance called dark matter. The sheer size of these objects makes it difficult to classify them as stars. As a physicist, I’ve been fascinated by dark matter, and I’ve been trying to find a way to see its traces using particle accelerators. I’m curious whether dark stars could provide an alternative method to find dark matter.
What makes dark matter dark?
Dark matter, which makes up approximately 27% of the universe but cannot be directly observed, is a key idea behind the phenomenon of dark stars. Astrophysicists have studied this mysterious substance for nearly a century, yet we haven’t seen any direct evidence of it besides its gravitational effects. So, what makes dark matter dark?Despite physicists not knowing much about it, dark matter makes up around 27% of the universe.Visual Capitalist/Science Photo Library via Getty Images Humans primarily observe the universe by detecting electromagnetic waves emitted by or reflected off various objects. For instance, the Moon is visible to the naked eye because it reflects sunlight. Atoms on the Moon’s surface absorb photons – the particles of light – sent from the Sun, causing electrons within atoms to move and send some of that light toward us. More advanced telescopes detect electromagnetic waves beyond the visible spectrum, such as ultraviolet, infrared or radio waves. They use the same principle: Electrically charged components of atoms react to these electromagnetic waves. But how can they detect a substance – dark matter – that not only has no electric charge but also has no electrically charged components? Although scientists don’t know the exact nature of dark matter, many models suggest that it is made up of electrically neutral particles – those without an electric charge. This trait makes it impossible to observe dark matter in the same way that we observe ordinary matter. Dark matter is thought to be made of particles that are their own antiparticles. Antiparticles are the “mirror” versions of particles. They have the same mass but opposite electric charge and other properties. When a particle encounters its antiparticle, the two annihilate each other in a burst of energy. If dark matter particles are their own antiparticles, they would annihilate upon colliding with each other, potentially releasing large amounts of energy. Scientists predict that this process plays a key role in the formation of dark stars, as long as the density of dark matter particles inside these stars is sufficiently high. The dark matter density determines how often dark matter particles encounter, and annihilate, each other. If the dark matter density inside dark stars is high, they would annihilate frequently.
What makes a dark star shine?
The concept of dark stars stems from a fundamental yet unresolved question in astrophysics: How do stars form? In the widely accepted view, clouds of primordial hydrogen and helium — the chemical elements formed in the first minutes after the Big Bang, approximately 13.8 billion years ago — collapsed under gravity. They heated up and initiated nuclear fusion, which formed heavier elements from the hydrogen and helium. This process led to the formation of the first generation of stars.Stars form when clouds of dust collapse inward and condense around a small, bright, dense core.NASA, ESA, CSA, and STScI, J. DePasquale (STScI), CC BY-ND In the standard view of star formation, dark matter is seen as a passive element that merely exerts a gravitational pull on everything around it, including primordial hydrogen and helium. But what if dark matter had a more active role in the process? That’s exactly the question a group of astrophysicists raised in 2008. In the dense environment of the early universe, dark matter particles would collide with, and annihilate, each other, releasing energy in the process. This energy could heat the hydrogen and helium gas, preventing it from further collapse and delaying, or even preventing, the typical ignition of nuclear fusion. The outcome would be a starlike object — but one powered by dark matter heating instead of fusion. Unlike regular stars, these dark stars might live much longer because they would continue to shine as long as they attracted dark matter. This trait would make them distinct from ordinary stars, as their cooler temperature would result in lower emissions of various particles.
Can we observe dark stars?
Several unique characteristics help astronomers identify potential dark stars. First, these objects must be very old. As the universe expands, the frequency of light coming from objects far away from Earth decreases, shifting toward the infrared end of the electromagnetic spectrum, meaning it gets “redshifted.” The oldest objects appear the most redshifted to observers. Since dark stars form from primordial hydrogen and helium, they are expected to contain little to no heavier elements, such as oxygen. They would be very large and cooler on the surface, yet highly luminous because their size — and the surface area emitting light — compensates for their lower surface brightness. They are also expected to be enormous, with radii of about tens of astronomical units — a cosmic distance measurement equal to the average distance between Earth and the Sun. Some supermassive dark stars are theorized to reach masses of roughly 10,000 to 10 million times that of the Sun, depending on how much dark matter and hydrogen or helium gas they can accumulate during their growth. So, have astronomers observed dark stars? Possibly. Data from the James Webb Space Telescope has revealed some very high-redshift objects that seem brighter — and possibly more massive — than what scientists expect of typical early galaxies or stars. These results have led some researchers to propose that dark stars might explain these objects.The James Webb Space Telescope, shown in this illustration, detects light coming from objects in the universe.Northrup Grumman/NASA In particular, a recent study analyzing James Webb Space Telescope data identified three candidates consistent with supermassive dark star models. Researchers looked at how much helium these objects contained to identify them. Since it is dark matter annihilation that heats up those dark stars, rather than nuclear fusion turning helium into heavier elements, dark stars should have more helium. The researchers highlight that one of these objects indeed exhibited a potential “smoking gun” helium absorption signature: a far higher helium abundance than one would expect in typical early galaxies.
Dark stars may explain early black holes
What happens when a dark star runs out of dark matter? It depends on the size of the dark star. For the lightest dark stars, the depletion of dark matter would mean gravity compresses the remaining hydrogen, igniting nuclear fusion. In this case, the dark star would eventually become an ordinary star, so some stars may have begun as dark stars. Supermassive dark stars are even more intriguing. At the end of their lifespan, a dead supermassive dark star would collapse directly into a black hole. This black hole could start the formation of a supermassive black hole, like the kind astronomers observe at the centers of galaxies, including our own Milky Way. Dark stars might also explain how supermassive black holes formed in the early universe. They could shed light on some unique black holes observed by astronomers. For example, a black hole in the galaxy UHZ-1 has a mass approaching 10 million solar masses, and is very old – it formed just 500 million years after the Big Bang. Traditional models struggle to explain how such massive black holes could form so quickly. The idea of dark stars is not universally accepted. These dark star candidates might still turn out just to be unusual galaxies. Some astrophysicists argue that matter accretion — a process in which massive objects pull in surrounding matter — alone can produce massive stars, and that studies using observations from the James Webb telescope cannot distinguish between massive ordinary stars and less dense, cooler dark stars. Researchers emphasize that they will need more observational data and theoretical advancements to solve this mystery. Alexey A. Petrov, Professor of physics and astronomy, University of South Carolina This article is republished from The Conversation under a Creative Commons license. Read the original article.
If evolution is real, then why isn’t it happening now? An anthropologist explains that humans actually are still evolving
Humans are still evolving! From skin color to lactose tolerance and disease resistance, discover how our bodies keep adapting to changing environments and why evolution is an ongoing process—even in the modern world.
Inuit people such as these Greenlanders have evolved to be able to eat fatty foods with a low risk of getting heart disease. Olivier Morin/AFP via Getty Images
If evolution is real, then why isn’t it happening now? An anthropologist explains that humans actually are still evolving
If evolution is real, then why is it not happening now? – Dee, Memphis, Tennessee
Many people believe that we humans have conquered nature through the wonders of civilization and technology. Some also believe that because we are different from other creatures, we have complete control over our destiny and have no need to evolve. Even though lots of people believe this, it’s not true. Like other living creatures, humans have been shaped by evolution. Over time, we have developed – and continue to develop – the traits that help us survive and flourish in the environments where we live. I’m an anthropologist. I study how humans adapt to different environments. Adaptation is an important part of evolution. Adaptations are traits that give someone an advantage in their environment. People with those traits are more likely to survive and pass those traits on to their children. Over many generations, those traits become widespread in the population.
The role of culture
We humans have two hands that help us skillfully use tools and other objects. We are able to walk and run on two legs, which frees our hands for these skilled tasks. And we have large brains that let us reason, create ideas and live successfully with other people in social groups. All of these traits have helped humans develop culture. Culture includes all of our ideas and beliefs and our abilities to plan and think about the present and the future. It also includes our ability to change our environment, for example by making tools and growing food. Although we humans have changed our environment in many ways during the past few thousand years, we are still changed by evolution. We have not stopped evolving, but we are evolving right now in different ways than our ancient ancestors. Our environments are often changed by our culture. We usually think of an environment as the weather, plants and animals in a place. But environments include the foods we eat and the infectious diseases we are exposed to. A very important part of the environment is the climate and what kinds of conditions we can live in. Our culture helps us change our exposure to the climate. For example, we build houses and put furnaces and air conditioners in them. But culture doesn’t fully protect us from extremes of heat, cold and the sun’s rays.The Turkana people in Kenya have evolved to survive with less water than other people, which helps them live in a desert environment.Tony Karumba/AFP via Getty Images Here are some examples of how humans have evolved over the past 10,000 years and how we are continuing to evolve today.
The power of the sun’s rays
While the sun’s rays are important for life on our planet, ultraviolet rays can damage human skin. Those of us with pale skin are in danger of serious sunburn and equally dangerous kinds of skin cancer. In contrast, those of us with a lot of skin pigment, called melanin, have some protection against damaging ultraviolet rays from sunshine. People in the tropics with dark skin are more likely to thrive under frequent bright sunlight. Yet, when ancient humans moved to cloudy, cooler places, the dark skin was not needed. Dark skin in cloudy places blocked the production of vitamin D in the skin, which is necessary for normal bone growth in children and adults. The amount of melanin pigment in our skin is controlled by our genes. So in this way, human evolution is driven by the environment – sunny or cloudy – in different parts of the world.
The food that we eat
Ten thousand years ago, our human ancestors began to tame or domesticate animals such as cattle and goats to eat their meat. Then about 2,000 years later, they learned how to milk cows and goats for this rich food. Unfortunately, like most other mammals at that time, human adults back then could not digest milk without feeling ill. Yet a few people were able to digest milk because they had genes that let them do so. Milk was such an important source of food in these societies that the people who could digest milk were better able to survive and have many children. So the genes that allowed them to digest milk increased in the population until nearly everyone could drink milk as adults. This process, which occurred and spread thousands of years ago, is an example of what is called cultural and biological co-evolution. It was the cultural practice of milking animals that led to these genetic or biological changes. Other people, such as the Inuit in Greenland, have genes that enable them to digest fats without suffering from heart diseases. The Turkana people herd livestock in Kenya in a very dry part of Africa. They have a gene that allows them to go for long periods without drinking much water. This practice would cause kidney damage in other people because the kidney regulates water in your body. These examples show how the remarkable diversity of foods that people eat around the world can affect evolution.These bacteria caused a devastating pandemic nearly 700 years ago that led humans to evolve resistance to them.Image Point FR/NIH/NIAID/BSIP/Universal Images Group via Getty Images
Diseases that threaten us
Like all living creatures, humans have been exposed to many infectious diseases. During the 14th century a deadly disease called the bubonic plague struck and spread rapidly throughout Europe and Asia. It killed about one-third of the population in Europe. Many of those who survived had a specific gene that gave them resistance against the disease. Those people and their descendants were better able to survive epidemics that followed for several centuries. Some diseases have struck quite recently. COVID-19, for instance, swept the globe in 2020. Vaccinations saved many lives. Some people have a natural resistance to the virus based on their genes. It may be that evolution increases this resistance in the population and helps humans fight future virus epidemics. As human beings, we are exposed to a variety of changing environments. And so evolution in many human populations continues across generations, including right now.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.Michael A. Little, Distinguished Professor Emeritus of Anthropology, Binghamton University, State University of New York This article is republished from The Conversation under a Creative Commons license. Read the original article.
Why can’t I wiggle my toes one at a time, like my fingers?
why can’t I wiggle my toes? Ever wondered why you can’t wiggle your toes one at a time like your fingers? Learn how evolution, muscles, and your brain all play a part in making fingers more independent than toes—and why that’s key for walking and balance.
Why can’t I wiggle my toes individually, like I can with my fingers? – Vincent, age 15, Arlington, Virginia
One of my favorite activities is going to the zoo where I live in Knoxville when it first opens and the animals are most active. On one recent weekend, I headed to the chimpanzees first. Their breakfast was still scattered around their enclosure for them to find. Ripley, one of the male chimpanzees, quickly gathered up some fruits and vegetables, sometimes using his feet almost like hands. After he ate, he used his feet to grab the fire hoses hanging around the enclosure and even held pieces of straw and other toys in his toes. I found myself feeling a bit envious. Why can’t people use our feet like this, quickly and easily grasping things with our toes just as easily as we do with our fingers? I’m a biological anthropologist who studies the biomechanics of the modern human foot and ankle, using mechanical principles of movement to understand how forces affect the shape of our bodies and how humans have changed over time. Your muscles, brain and how human feet evolved all play a part in why you can’t wiggle individual toes one by one.Chimpanzee hands and feet do similar jobs.Manoj Shah/Stone via Getty Images
Comparing humans to a close relative
Humans are primates, which means we belong to the same group of animals that includes apes like Riley the chimp. In fact, chimpanzees are our closest genetic relatives, sharing almost 98.8% of our DNA. Evolution is part of the answer to why chimpanzees have such dexterous toes while ours seem much more clumsy. Our very ancient ancestors probably moved around the way chimpanzees do, using both their arms and legs. But over time our lineage started walking on two legs. Human feet needed to change to help us stay balanced and to support our bodies as we walk upright. It became less important for our toes to move individually than to keep us from toppling over as we moved through the world in this new way.Feet adapted so we could walk and balance on just two legs.Karina Mansfield/Moment via Getty Images Human hands became more important for things such as using tools, one of the hallmark skills of human beings. Over time, our fingers became better at moving on their own. People use their hands to do lots of things, such as drawing, texting or playing a musical instrument. Even typing this article is possible only because my fingers can make small, careful and controlled movements. People’s feet and hands evolved for different purposes.
Muscles that move your fingers or toes
Evolution brought these differences about by physically adapting our muscles, bones and tendons to better support walking and balance. Hands and feet have similar anatomy; both have five fingers or toes that are moved by muscles and tendons. The human foot contains 29 muscles that all work to help you walk and stay balanced when you stand. In comparison, a hand has 34 muscles. Most of the muscles of your foot let you point your toes down, like when you stand on tiptoes, or lift them up, like when you walk on your heels. These muscles also help feet roll slightly inward or outward, which lets you keep your balance on uneven ground. All these movements work together to help you walk and run safely. The big toe on each foot is special because it helps push your body forward when you walk and has extra muscles just for its movement. The other four toes don’t have their own separate muscles. A few main muscles in the bottom of your foot and in your calf move all four toes at once. Because they share muscles, those toes can wiggle, but not very independently like your fingers can. The calf muscles also have long tendons that reach into the foot; they’re better at keeping you steady and helping you walk than at making tiny, precise movements.Your hand is capable of delicate movements thanks to the muscles and ligaments that control its bones.Henry Gray, ‘Anatomy of the Human Body’/Wikimedia Commons, CC BY In contrast, six main muscle groups help move each finger. The fingers share these muscles, which sit mostly in the forearm and connect to the fingers by tendons. The thumb and pinky have extra muscles that let you grip and hold objects more easily. All of these muscles are specialized to allow careful, controlled movements, such as writing. So, yes, I have more muscles dedicated to moving my fingers, but that is not the only reason I can’t wiggle my toes one by one.
Divvying up brain power
You also need to look inside your brain to understand why toes and fingers work differently. Part of your brain called the motor cortex tells your body how to move. It’s made of cells called neurons that act like tiny messengers, sending signals to the rest of your body. Your motor cortex devotes many more neurons to controlling your fingers than your toes, so it can send much more detailed instructions to your fingers. Because of the way your motor cortex is organized, it takes more “brain power,” meaning more signals and more activity, to move your fingers than your toes.The motor cortex of your brain sends orders to move parts of your body.Kateryna Kon/Science Photo Library via Getty Images Even though you can’t grab things with your feet like Ripley the chimp can, you can understand why.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.Steven Lautzenheiser, Assistant Professor of Biological Anthropology, University of Tennessee This article is republished from The Conversation under a Creative Commons license. Read the original article.
