Search Results
165 results found with an empty search
- Pointing the Way: A Triangular View of the World | OmniSci Magazine
< Back to Issue 7 Pointing the Way: A Triangular View of the World by Ingrid Sefton 22 October 2024 edited by Hendrick Lin illustrated by Aisyah Mohammad Sulhanuddin You, my friend, are living in a world created by triangles. Since the dawn of time, this humble three-sided polygon has quietly shaped the evolution of human civilisation. As you gaze around, you can likely spot a triangle or two tucked within your surroundings. This may be of no surprise to you. Externally, the triangle governs the material construction of our world, underpinning the foundations of countless engineering and architectural designs. Yet these more obvious physical constructions are just one contribution of this pointy, three-sided shape to modern society. Indeed, it is where the role of the triangle remains invisible that it harnesses the most power. Triangles have played an integral role in sailing and modern navigation systems, having enabled us to explore all corners of the Earth. Beyond this, let us not forget the massive contributions this shape has made to the development of 3D modelling, used everywhere from graphic design and animation to CGI. All thanks to the simple, unassuming triangle. The physical, the navigational and the digital. Three key sides of the triangle’s influence in shaping the modern world. The Physical The triangle's importance in the physical world stems from its inner strength. Unbeknownst to many, it is the strongest two-dimensional shape that exists, with its power amplified in three-dimensional polyhedrons derived from triangles. How can this unique strength be explained? Consider applying force to one corner, or apex, of a triangle. This force is distributed down either side of the triangle and as these sides are compressed, the base is stretched outwards. Weight can therefore be evenly dispersed across the shape, preventing it from bending and breaking (Saint Louis Science Center, 2020). It is for good reason that the triangular shape underpins many fundamental principles of architecture and design. Perhaps the most iconic of the structures that utilise this shape are the Pyramids of Giza, one of the Seven Wonders of the Ancient World. Constructed in the early 25th Century BCE, they housed the tombs of ancient Egyptian pharaohs and are the last remaining Wonder that exists today. The tallest of the Pyramids, known as the Great Pyramid, originally soared as high as 147 metres above the ground, though today erosion has reduced it to 138 metres (Encylopedia Britannica, 2024a). This architectural feat was monumental for its time, and to this day, how exactly the Pyramids were constructed remains a hotly contested debate amongst archeologists and engineers. One proposition is that large ramps were used in conjunction with a complex system of ropes, sledges and levers to haul stone blocks up (Handwerk, 2023). Whatever the method of construction may have been, these ancient wonders have stood the test of time for over 4500 years - a remnant of one of humanity's first advanced civilisations that exemplifies the scale, strength and resilience of construction made possible by triangles. Triangles also play a crucial role in the construction of seemingly dissimilar shapes. This is highlighted in the case of geodesic structures - spheres constructed from a network of triangles approximating a rounded shape, like a soccer ball. First developed in the 20th Century by architect Richard Buckminster Fuller, these domes are lightweight and able to distribute stress across large, arching structures (Encylopedia Britannica, 2024b). Since Fuller’s earliest constructions, these domes have been widely utilised in the construction of stadiums, planetariums and even "glamping" accommodations. One notable example is the Eden Project - the world's largest biodome botanical garden in the United Kingdom, housing thousands of plant species over 5.5 acres of land (Eden Project, 2024). The interconnectedness of the triangles allows for maximum sunlight exposure across wide spaces, creating an ideal environment for plant photosynthesis and cultivation. Intriguingly, Fuller's use of triangles in this innovative manner led to a breakthrough in the far-away field of synthetic chemistry. Scientists Robert Curl, Harold Kroto and Richard Smalley discovered the nanomaterial Buckminsterfullerene, or “the Buckyball”, after the scientists realised the structure's similarity to Fuller's geodesic spheres (The Stanford Libraries, 2024). This led to the discovery of a new class of materials known as fullerenes. The scientists were subsequently awarded the 1996 Nobel Prize in Chemistry for elucidating this molecule’s structure (The Stanford Libraries, 2024). Balancing power with versatility, triangles form the crux of our built environments at both an atomic and architectural level. The Navigational Remember those sine and cosine formulas your maths teacher insisted had important real world applications? Turns out they weren’t kidding. Triangulation is the process of finding an unknown location of an object by forming a triangle between this object and two other reference points. Sine, cosine and tangent, the main trigonometric ratios, are used to relate the sides and angles formed within a right triangle and hence, determine the position of an unknown point. For centuries, humans have turned to triangles as a means to find their ways. Sailors, in particular, have long used landmarks and celestial objects like the stars to orient themselves at sea. By observing the angle between known locations (or stars) and using basic trigonometry, navigators could calculate distances and determine their precise location. Moving to a more global scale of navigation becomes a bit more complicated, as the Earth is a sphere and not a flat surface (although some may beg to differ…). A more advanced form of triangulation known as trilateration underpins the Global Positioning System (GPS) in order to determine three-dimensional coordinates of a receiver. Instead of angles, GPS utilises the time taken for radio signals sent from satellites to reach a receiving device on Earth. A connected system of navigation satellites circles the Earth, each sending out signals with the location and time it was sent by that satellite. By measuring the delay between the time of signal reception and the broadcast time, the distance from the receiver to each satellite can be computed (Federal Aviation Administration, 2024). Once distances to at least three satellites are known, the receiving device can determine its own three-dimensional position, employing similar techniques to triangulation. GPS data is not only used to guide your Google Map directions. Analysing the positions of satellite stations and their movements is a crucial tool for monitoring volcanic and seismic activity (Murray & Svarc, 2017). Recent breakthroughs have even suggested that there may be a future for utilising the GPS to detect earthquakes before they happen (Rao, 2023). From the seas to the skies, triangles allow us to push the boundaries of exploration while always guiding us home to safety. The Digital What does connect-the-dots have to do with triangles or 3D modelling? A connect-the-dots drawing begins with nothing but some labelled dots. Yet as each dot is joined by a straight line, a complex and curved picture emerges. The more dots you use, the smoother the picture looks. Consider now trying to design a three-dimensional surface. Just as you might use dots to approximate a curve, triangles serve as building blocks for constructing complex surfaces. By taking enough triangles and joining them at their edges, we too can approximate intricate and multidimensional structures. In 3D modelling, objects are represented as meshes - models consisting of vertices (points in 3D space) connected by edges to form polygons and thus, the surface of an object (Stanton, 2023). To define a flat surface oriented in a plane, a minimum of three distinct points are needed. Triangles are the simplest shape for constructing these planes as they are coplanar, meaning any three points in space will always form a flat surface (Licata & Licata, 2015). This makes them perfect for modelling complex 3D shapes out of interconnected triangles. Animation, gaming, graphic design and computer generated imagery (CGI) in movies are just some of the many varied applications that utilise these mesh modelling techniques to create intricate 3D models, with curved and highly detailed surfaces. Additionally, there exist efficient computer algorithms that are optimised to dissect objects into hundreds of thousands of flat triangles. A complex, digital representation of any object can therefore be easily portrayed as a simple collection of points and triangles. Combined with their simple geometric properties, triangles can then be processed quickly by modern Graphics Processing Units (GPUs), optimising their performance in real-time applications. Add in lighting, shading and smooth deformation, and you will find yourself with an intricate, three-dimensional model. Pointing the Way Forward For too long, the triangle has been overshadowed by its more popular cousin, the square. Yet, what is a square? Two triangles put together. The simplicity of this three-sided shape allows it to integrate within our society, with its contributions often invisible to the naked eye. From the physical, to the navigational and the digital, modern human society is built on the triangle. Maybe that trigonometry class wasn’t so pointless after all. References Eden Project (2024). Eden Project's Mission . https://www.edenproject.com/mission/origins Encylopedia Britannica (2024a). Great Pyramid of Giza . https://www.britannica.com/place/Great-Pyramid-of-Giza Encylopedia Britannica (2024b). Geodesic Dome. https://www.britannica.com/technology/geodesic-dome Federal Aviation Administration (2024). Satellite Navigation - GPS - How It Works . United States Department of Transportation. https://www.faa.gov/about/office_org/headquarters_offices/ato/service_units/techops/navservices/gnss/gps/howitworks Handwerk, B. (2023). The Pyramids at Giza were built to endure an eternity—but how? National Geographic. https://www.nationalgeographic.com/history/article/giza-pyramids Licata, J., & Licata, A. (2015). From triangles to computer graphics . ABC Science. https://www.abc.net.au/science/articles/2015/06/10/4251713.htm Murray, J. R., & Svarc, J. (2017). Global Positioning System Data Collection, Processing, and Analysis Conducted by the U.S. Geological Survey Earthquake Hazards Program. Seismological Research Letters , 88 (3), 916-925. https://doi.org/10.1785/0220160204 Rao, R. (2023). GPS satellites may be able to detect earthquakes before they happen . Space. https://www.space.com/earthquake-prediction-gps-satellite-data Saint Louis Science Center (2020). The Secret Strength of Triangles . https://www.slsc.org/the-secret-strength-of-triangles/ Stanton, A. (2023). Exploring the World of 3D Modeling: Solid vs. Mesh Modeling . Cadmore. https://cadmore.com/blog/solid-vs-mesh-modeling-differences The Stanford Libraries (2024). What is a geodesic dome? Stanford University. https://exhibits.stanford.edu/bucky/feature/what-is-a-geodesic-dome Previous article Next article apex back to
- Interviewing Dr Karen Freilich | OmniSci Magazine
< Back to Issue 4 Interviewing Dr Karen Freilich by Rachel Ko 1 July 2023 Edited by Caitlin Kane Illustrated by Pia Barraza Science in the real world is never straight-forward. The realm of medicine and health is particularly intricate, riddled with myths and marvels. This makes the healthcare journey a difficult one to navigate, both for the patient, and for the provider. It is undeniably a field where an ever-evolving myriad of factors makes the bedside experience vastly different to the textbooks. In my first year studying medicine, I am constantly realising that a strong understanding of the fundamentals is often a saving grace, while learning to dispel the mirage of medicine as a simple science. Enter Humerus Hacks , a podcast recommended to me in the first week of medical school by peers who had walked the treacherous road before. A guiding light in the murky waters of medical education, Karen and Sarah’s playful banter lays out high-yield medical content with catchy mnemonics and gracious advice. In this interview, we had the special opportunity to talk to Dr Karen Freilich, one of the hosts of Humerus Hacks , about her journey in medicine so far as a young GP, and the story of how she created a podcast that masters the art of science communication in a perfect marriage of education and entertainment. Tell us about your journey with science, and your career so far. I’ve just completed my GP Fellowship training after about 12 years of study. It’s a relief to be done —medicine is a long slog! I’ve had a brilliant time and been fortunate to take part in exciting studies. I took some time off clinical medicine to complete a Masters of Reproductive and Sexual Health Research in London (LSHTM) as well as completing a Diploma of Obstetrics (DRANZCOG). I currently teach at the University of Melbourne’s Medical School as a tutor in Sexual Health, and write and train high school sexual health educators through Elephant Ed. I work as a GP most days of the week, in a clinic with a focus on sexual and reproductive health and I’m a proud medical abortion and contraception provider. I’m also fortunate to work at Monash in the Sexual Medicine and Therapy Clinic, and work together with the Australasian Society for HIV, Viral Hepatitis and Sexual Health Medicine (ASHM). It’s a tricky balance wearing a number of hats, but I love the diversity. Unsurprisingly everything I do is focused in sexual and reproductive health through clinical work, education, advising and science communication. My career is certainly tailor-made to my interests and passion, and took quite some time to get to this point! I love being able to educate on both a one-on-one and broader level on sexual and reproductive health care, particularly through a reproductive justice lens. What was the inspiration behind Humerus Hacks ? In the early years of medical school, my mate Sarah and I used to spend hours and hours trying to memorise different antibiotics and the differences between them. It felt incomprehensible to have to learn not only a new science, but an entirely new language behind it. It felt like a Duolingo course! So in order to scrape through exams, we made silly little stories to try and remember the differences between gentamicin, amoxicillin etc.. Fast forward a few years and Sarah and I ended up running a weekly study group for the year below us, filled with our mnemonics and silly stories. We developed a bit of a cult following (if I say so myself!). It seemed there was a real appetite for otherwise tedious and dry medical education made fun and entertaining. In final year, we both ended up on placements requiring huge drives. We turned to podcasts for ‘edutainment’ — and found there simply were none. So we did what everyone in 2016 was doing, bought a microphone and recorded our own. We were a bit mortified at the start and convinced we wouldn’t get internships if our future employers heard us swearing and being inappropriate online, so we hid our faces and were anonymous with our names. Fortunately it turned out we had nothing to be nervous about, and Humerus Hacks was a hit. Sarah is a musical genius and recorded the intro song with her band. It’s now been over 50 episodes and over 150,000 downloads. We’re often in the iTunes Medical Podcasts Top 10! The inspiration has and always will be pure study laziness — trying to make studying more interesting, fun and accessible and ultimately, more memorable. What is the process of developing and recording an episode? Me, Sarah, or another co-host or friend (Callum, Bridget, Robbie and Dan to name a few!) sitting on a couch with a microphone and chinwagging about a topic. If we’re lucky, maybe some prep. I’d love to suggest it’s more fancy than that! I have brilliant colleagues who play an integral role. Alex edits our episodes and does a brilliant job. And Bella creates fantastic art for the episodes. Sometimes I play around on Canva too for some social media. Shout out as well to our friends who helped with some graphic design and audio. It’s definitely a team effort, and so many people to thank for their ongoing contributions and support. What is your relationship with your audience like? Our audience sends us messages and emails all the time — even if we haven’t made an episode in months! It’s a joy to receive any messages and warms our hearts every time. We get the most delightful and lovely messages. We also get a lot of requests which I wish we could keep up with more, the irony of doing our own exams over the past few years! We try to respond to all messages and keep up with requests. Knowing that our silly little mnemonics has helped anyone with exams is a huge joy. How has science communication evolved since you began? Mnemonics have been a huge part of medicine for a very long time. In fact, I have my uncle’s Medical Mnemonic book from 1958! Some of them have aged terribly, unsurprisingly, but many we still use to this day. So, we are far from inventing the wheel. In saying that, the boom of social media and podcasts over the past few years has lent itself to subspecialised Instagram pages, YouTube channels and more podcasts than I could have ever imagined. Making medical education (and science communication) fun has become much more mainstream and accepted as a genuine study tool. Who knew, making dry education entertaining actually works…! What has been the biggest challenge in your science communication journey? Hands down, time. I run Humerus Hacks with a group of excellent friends and colleagues, but we all happen to be medical students or doctors. Unsurprisingly, it means we are all always bogged down with shift work, exams, and burn out. Humerus Hacks is a labour of love. So we make an effort if and when we can, without any time pressure. I wish we had more time! What role would you say science communication plays in your daily practice? I’m a GP with a special interest in sexual medicine as well as a sexual health tutor for medical students. I also write and train individuals to run high school sexual health education. I’ve also been fortunate to be a guest host on ABC Breakfast Radio under ‘Doctor Breakfast’ providing science communication for a number of medical topics. So, it plays a huge role in my daily practice! I particularly enjoy the interplay of small scale science communication through one-on-one patient interactions compared with larger scale communication through radio, teaching and podcasts. They balance each other really well, and I enjoy the individualised, tailored approach whilst simultaneously thinking of the broader public health messaging. What role would you say science communication plays in society generally? There is so much misinformation floating around. As a huge fan of social media and TikTok myself, I can see how these avenues can be both a wonderful source of information but simultaneously promote unnuanced, oversimplified and often blatantly incorrect health messaging. Social media (including podcasts) provides a really accessible, often free avenue for science information that is otherwise inaccessible. However, we have a responsibility to ensure the information is correct, up to date, and safe. Social media loves a quick snap messaging, but science is almost always more nuanced and complex. A 30 second TikTok often unsurprisingly misses the mark! So, accurate and accessible science communication is the key — the hard thing is making it fun and interesting. What are your immediate goals in science communication this year, and what do you hope to achieve in science communication in the long-term? Great question! I am thoroughly enjoying my career balance at the moment. It’s a great mix of GP clinic, sexual medicine and therapy clinical work, sexual health teaching, and radio/podcasting. I’d love to make more Humerus Hacks episodes now that I’ve finished my own training and have (hopefully) both more knowledge and time! I’ve put together a SPHERE Sexual and Reproductive Health podcast focusing on upskilling clinicians to provide medical abortion and contraception in primary care. I am also loving radio work and would love to keep going with this. I may or may not delve into the TikTok world… watch this space! Long term, hopefully ongoing science communication in the field of sexual and reproductive healthcare. What advice would you give to students exploring the world of science communication? Social media is a game changer that had only just begun when I was a student. TikTok, Instagram etc all provide a free and accessibly way to both gain knowledge and skills, and to educate others. Science students in all disciplines have such incredibly knowledge and insight, and if you’re interested, there’s a willing and enthusiastic audience out there. The phrase ‘see one, do one, teach one’ forever rings true. Teaching and providing science communication helps your own education, and has always been my favourite learning tool. Finally, and I cannot emphasise this enough, being a student is long, tedious, and exhausting. Enjoy the process and look after yourself and your colleagues as a priority! ------------------- It is undeniable that Humerus Hacks is a project succeeding on its steadfast mission to uncover the mirage of medicine. Through a blend of education and entertainment, it reveals the intricate realities of science in health, as a complex and ever-changing landscape that demands a strong foundation of knowledge and willingness to adapt. We extend our heartfelt gratitude to Dr Karen Frielich, for not only agreeing to talk to us, but also for all of her work to demystify the healthcare journey, both for the professional, and for the patient. You can check out 'Humerus Hacks' on Spotify , on Apple Music , or online! Previous article Next article back to MIRAGE
- On the Folklore of Fossils | OmniSci Magazine
< Back to Issue 5 On the Folklore of Fossils Ethan Bisogni 24 October 2023 Edited by Arwen Nguyen-Ngo Illustrated by Aisyah Mohammad Sulhanuddin We inhabit an incredible world, one shaped by the ancient mysteries of our past and the imaginative stories they inspire. Throughout human history, we have tried to comprehend the bigger picture - using mythology and science to explain the presence of any natural phenomena we can observe. Between the movement of the stars and shape of the land, most scientific explanations of our world share a fascinating mythical counterpart. One particular area of science that has been bestowed with some truly incredible folklore is palaeontology. A History of Palaeontology To best understand some of the amazing mythologies surrounding fossils, we should first briefly explore the history of modern palaeontology. Some of the earliest attempts at understanding fossils can be seen in ancient Greece and Rome, where philosophers such as Herodotus understood that the presence of petrified shells indicated the recession of a past marine environment (Forli & Guerrini, 2022a). However, much of the groundwork for modern palaeontology was only developed in the late 17th century (Boudreau et al., 2023). Regarded as one of the most influential figures in modern geology, Nicholas Steno had outlined the Principles of Stratigraphy in his 1669 Dissertationis Prodromus - to be used as a jumping board for many earth scientists to come (Berthault, 2022). In the early 1800’s, William Smith had utilised his fossil knowledge to differentiate and match layers of rock known as strata, published in Strata Identified by Organised Fossils (Scott, 2008). And perhaps one of the largest contributions to modern palaeontology, Darwin's theory of evolution outlined in On the Origin of Species allowed for natural scientists to better understand the evolution of species throughout time. Considering how much of what we know about modern palaeontology was only published in the last 350 years, it becomes clear why so many cultures had developed their own interesting interpretations of fossils. From magical spells to infernal beasts, these legends highlight the prominent ideologies of their time. So let us explore some of the more interesting and diverse fossil myths from the ages. Merlinia To start, we will be discussing the folklore origin of Merlinia, an extinct genus of trilobite from the Early Ordivician age, 470 million years ago (British Geological Survey, n.d.). Trilobites were small sea-faring invertebrates who first appeared following the Cambrian Explosion, and were prominent throughout the fossil record until their unfortunate extinction 250 million years ago during the Late Permian mass extinction (American Museum of Natural History, n.d.). According to the British Geological Survey, this genus of trilobite was extensively found throughout the rocks of Carmarthen - a Welsh town famous for being the supposed birthplace of Merlin, the legendary wizard and advisor to King Arthur (‘P550303’, 2009). Often mistaken by the townspeople as stone butterflies, these fossils were naturally attributed to Merlin and thought to be the product of a petrification spell (American Museum of Natural History, n.d.). Whilst disheartening for the butterflies, the real trilobites behind the myth likely faced a much more wicked and sorrowful demise. Snakestones Much like Merlinia, snakestones were also named after a prominent figure with a habit for turning creatures to stone. Saint Hilda of Whitby was the abbess of the local town monastery during the sixteen hundreds, and was widely credited for the creation of these fossils - which are otherwise known as Hildoceras, after herself (Lotzof, n.d.). With the town facing a plague of snakes, St Hilda was said to have performed a miracle that petrified the serpents and forced them to coil into the fossils we see today (National Museums Scotland, n.d.). These stony serpents however are really just ammonites, a group of molluscs that went extinct alongside the dinosaurs 66 million years ago (Osterloff, n.d.). The legend of St Hilda isn’t the only instance of snake-repellent folklore either, with St Patrick earning himself a holiday after supposedly clearing the snakes out of Ireland. Much of the rise of European anguine-based legends can be attributed to growing Christian influences during the second millennium. The biblical depiction of snakes as tempting and disingenuous has caused them to be portrayed harshly throughout older western media (Migdol, 2021). Unsurprisingly, this isn't the only time that palaeontology and Christianity have crossed paths. The Devil Perhaps the most infamous figure in human culture, the Devil is outlined in Christian doctrine as the embodiment of sin and evil. References to their influence can be found throughout human history, and have naturally found their way into geological folklore. Many geological features have been attributed to a satanic presence, thought to be remnants from when the Devil would walk the earth (Forli & Guerrini, 2022b). Gryphaea was a fossil widely mistaken as the authentic nails of Satan himself, hence nicknamed the ‘Devil’s Nails’, and was used as a proxy to determine areas of evil (Forli & Guerrini, 2022b). However, these fossils were not the byproduct of Satan’s occasional beauty treatments, but rather an extinct genus of mollusc from the early Jurassic, 200 million years ago (Forli & Guerrini, 2022b). Nail clippings were not the only features observed that people considered to be a sign of the Devil’s unholy pilgrimage. Devilish hoof-shaped steps embedded into stone have been reported throughout the world. Referred to as ‘il-passi tax-xitan’ by the Maltese, meaning ‘the devil's footsteps’, these tracks were considered further proof of the Devil's presence amongst mankind (Duffin & Davidson, 2011). In Malta these footprints were really just fossilised echinoids - innocent former sea urchins facing unkind accusations of being demonic (Duffin & Davidson, 2011). That's not to say all Maltese fossils were considered unholy: some 16th century priests conversely believed them to be the footsteps of St Paul the Apostle, following his shipwrecking on the island in the 1st century (Mayor & Sarjeant, 2001). Dragons Dragons are some of the most well known mythical creatures, with many cultures around the world having their own rendition of a mystic dragon-like beast. Unlike some of the other legends explored so far, it is unlikely that fossilised remains were the initial cause of this myth, but were rather used as evidence to cement it in truth. Dragons were considered prominent creatures throughout the Indian mountains, with evidence of dragon hunts being displayed in the ancient city of Paraka (Mayor, 2000). Apollonius of Tyana, a 1st century Greek philosopher, was said to have observed these dragons during his passage through the Siwalik Hills - an Indian range known for its preservation of larger fossils (Mayor, 2000). Described by Apollonius as considerable tusked creatures, these dragon remains were more than likely the fossils of extinct elephants and giraffids - such as Elephas hysudricus or Sivatherium giganteum (Mayor, 2000). India is not the only country to have experienced this phenomenon either, with many Asian and European societies said to have also continuously misdiagnose large vertebrate fossils as dragon bones. Whether it is mischievous spellcasting or the indication of a demonic evil, myths surrounding fossils have existed throughout centuries of human society. These legends provide a fascinating window into the creative minds of past cultures, and their beliefs at the time. While modern palaeontologists have proven these legends to be no more than captivating stories, it is important to view this folklore with a certain understanding and respect. These early attempts at trying to understand the world around us provides an interesting insight into human nature, and our innate desire to search for answers. References American Museum of Natural History. (n.d.) End of the Line - The demise of the Trilobites . American Museum of Natural History. https://www.amnh.org/research/paleontology/collections/fossil-invertebrate-collection/trilobite-website/trilobite-localities/end-of-the-line-the-demise-of-the-trilobites Berthault, G. (2002). Analysis of Main Principles of Stratigraphy on the Basis of Experimental Data . Lithology and Mineral Resources, 22(5), 442-446. https://doi.org/10.1023/A:1020220232661 Boudreau, D., McDaniel, M., Sprout, E., & Turgeon, A. (2023). Paleontology . National Geographic Society. https://education.nationalgeographic.org/resource/paleontology/ British Geological Survey (n.d.). Trilobites . https://www.bgs.ac.uk/discovering-geology/fossilsand-geological-time/trilobites/ Duffin, C. J., & Davidson, J. P. (2011). Geology and the dark side . Proceedings of the Geologists’ Association, 122(1), 7-15. https://doi.org/10.1016/j.pgeola.2010.08.002 Forli, M., & Guerrini, A. (2022). Bivalvia: Devil’s Nails, Reflections Between Superstition and Science. In The History of Fossils Over Centuries (pp. 181-206). Springer, Cham. https://doi.org/10.1007/978-3-031-04687-2_2 Forli, M., & Guerrini, A. (2022). Fossilia and Fossils: Considerations on Their Understanding Over the Centuries . In The History of Fossils Over Centuries (pp. 5-25). Springer, Cham. https://doi.org/10.1007/978-3-031-04687-2_12 Lotzof, K. (n.d.). Snakestones: The Myth, Magic, and Science of Ammonites . Natural History Museum. https://www.nhm.ac.uk/discover/snakestones-ammonites-myth-magic-science.html Mayor, A. (2000). CHAPTER 3 Ancient Discoveries of Giant Bones . In The First Fossil Hunters (pp. 104-156). Princeton University Press. https://www.jstor.org/stable/j.ctt7s6mm.11 Mayor, A., & Sarjeant, W.A.S. (2001). The Folklore of Footprints in Stone: From Classical Antiquity to the Present . An International Journal for Plant and Animal Traces, 8(2), 143-163. https://www.jstor.org/stable/j.ctt7s6mm.11 Migdol, E., Morrison, E., & Grollemond, L. (2021). What Did People Believe about Animals in the Middle Ages? Getty Conservation Institute. https://www.getty.edu/news/what-did-people-believe-about-animals-in-the-middle-ages/ National Museums Scotland (n.d.). Snakestones . https://www.nms.ac.uk/explore-our- collections/stories/natural-sciences/fossil-tales/fossil-tales-menu/snakestones/ Osterloff, E. (n.d.). What Is an Ammonite? Natural History Museum. https://www.nhm.ac.uk/discover/what-is-an-ammonite.html P550303. (2009). British Geological Survey . http://geoscenic.bgs.ac.uk/asset- bank/action/viewAsset?id=113713&index=4&total=6&view=viewSearchItem Scott, M. (2008). William Smith (1769-1839) . NASA Earth Observatory. https://earthobservatory.nasa.gov/features/WilliamSmith Wicked back to
- How Population Biobanks Shed Light on Disease | OmniSci Magazine
< Back to Issue 10 How Population Biobanks Shed Light on Disease by Jason Chien 2 June 2026 Illustrated by Chris Cao Edited by Cady Jacobson Imagine yourself as a researcher. Perhaps your work requires biological samples from a rare disease, but finding and collecting these samples from patients is difficult. Or maybe your research depends on comparing a person’s current cell or tissue data to what it was ten years ago, but you cannot afford to wait a decade. Thankfully, there are biobanks: specialised facilities that store biological samples and other relevant medical information from donors, while also distributing samples to researchers regardless of where they are based. Biobanks also act as data custodians, de-identifying and anonymising patient information. In addition, they work with Institutional Review Boards (essentially, university or agency ethics boards) to review the merits of each access request before deciding whether to deliver samples to applicants (1). For some biobanks and sample types, samples can even be returned after being used for research (2). There are biobanks storing non-human data, such as the Svalbard Global Seed Vault or Australia’s Victorian Conservation Seedbank, which store viable seeds of many plant species and their various strains (3). Even within biomedical biobanks, they vary in the types of samples stored and by extension, their intended and fulfilled functions, as well as why they were built (4).There are disease-specific biobanks storing samples relevant to specific diseases; for example, a cardiovascular biobank that specialises in storing tissue immediately following a patient’s death, such that it can be used for physiological studies (2). However, this article will focus specifically on population biobanks, a subset of biomedical biobanks, in the context of disease investigation. Ethical issues surrounding biobanking will not be a major focus, including matters such as how sample donors provide consent for the use of their samples during research (4). Population biobanks store tissue samples, plus health and personal information of donors. Large sites have sample counts ranging from hundreds of thousands to millions (1). Population biobanks aim to have enough samples to represent the huge variation among a region or country’s population, and store many parameters of each sample donor, such as lifestyle data (e.g. cardiovascular disease or smoking status) and omics data (5). Biomedical scientists study many aspects of what goes on in human cells and tissues, down to the molecular level, due to their relevance for our understanding of disease. These factors include our genetic makeup, regulation and expression of genes, as well as the effects of environmental factors and metabolism (6). In such omics approaches, our existing knowledge of the complete set of genes in species such as humans allows information from an individual’s own genome to be generated and then compared or combined with data from other individuals. This gives rise to approaches such as genomics (concerning genes), proteomics (concerning proteins) and metabolomics (concerning molecules involved in metabolism). Large subsets of this data from individuals, as well as population-level variations associated with specific diseases, can be used for research. For example, the number of genes involved in cancer alone can easily exceed thousands (7). Large sample quantities allow researchers doing many different investigations to identify factors correlated with disease resistance and susceptibility to many diseases (1). This complements methods of investigating disease mechanisms involving specific genes and molecules by helping researchers identify candidate genes and molecules for further investigation. As a consequence, many samples in population biobanks are actually from healthy donors rather than hospital patients (5). Beyond providing samples, some of these large biobanks are also direct providers of omics data. While biobanks are not necessary for generating omics data from one or a few individuals, they enable the collection of data from enough samples to represent the diversity of the population and capture variants as rare as those in 0.1% of the population (6). Because of rigorous sample processing and quality control procedures standardised across biobanks, the omics data generated from samples collected by different biobanks can also be more easily combined by researchers to yield insights (1). Furthermore, as new higher-resolution biotechnology develops, they can be used to investigate samples collected in the past (1). For example, the UK biobank enrolled 500,000 participants for its first cohort in 2006, collecting blood, urine, and saliva samples, in addition to substantial lifestyle data and physical measurements for each participant (5). Though there is no flashy silver-bullet discovery like penicillin directly resulting from the biobank, it has greatly increased our knowledge of which genes and proteins to target when designing new drugs, along with which genetic variants increase our predisposition to a range of diseases, such as cancer and cardiovascular diseases (8). Population biobanks are huge, long-term investments. For example, funding from the UK government and various non-profits for the UK biobank have exceeded £90 million British Pounds from its inception to 2014 (1). Reasons for their construction include understanding the mechanisms of disease, translating research into interventions, improving health outcomes, and promoting biotechnology (1). Population biobanks that are able to effectively engage sample donors can generate population data to support research into diseases that most heavily affect a country (1). The majority of the world’s biobank datasets are still composed primarily of individuals with white Northern European ancestry (9), and using data from one population can be significantly less effective for identifying risk factors in another population. This limitation serves as a driver for developing countries to build their own population biobanks (9). Part of the reason most biobanks are built is to serve as a national public good, with data made accessible to both academic researchers at affordable rates and to industry researchers (1, 10). Large population biobanks are usually run as a public entity or as public-private partnerships with a large proportion of public funding (10). In fact, even with cost recovery measures that charge users for accessing biobank samples — often with higher rates for industry researchers — revenues still fall below operating costs (1). That said, biobanks create benefits beyond their own countries, and multinational collaborations have expanded their scale and reach (1), allowing researchers to access omics data and request samples from biobanks overseas. With biobanking infrastructures in place, multinational collaborations have emerged that facilitate data sharing between research institutions across different countries through consortia – formal collaborations between participating institutions that establish common research goals and reduce competition over the use of specialised facilities (11). In other words, they seek to minimise situations in which multiple research groups inadvertently work on the exact same project, leading to an inefficient allocation of resources. One example is the International Cancer Genome Consortium (ICGC). This agreement creates a collaboration framework for data exchange in around 200 large-scale cancer research projects, with participating biobanks from Europe, China, Australia, USA, and other countries. Participating biobanks include large population biobanks, but also other types such as disease-specific biobanks (12). To finalise, biobanks are not simply a place where biological samples are stored. They are dynamic entities that can be scaled up and down, places where samples are sent in and out, and they face financial pressures as national research priorities change. They are places where innovation occurs in a wide range of areas, from cryostorage to management of digital information. The power of population biobanks and their research potential lies in their cohort sizes. Hopefully, biobanks will continue to generate valuable new discoveries as newly established cohorts around the world begin to mature. References Chalmers D, Nicol D, Kaye J. et al. Has the biobank bubble burst? Withstanding the challenges for sustainable biobanking in the digital era. BMC Med Ethics. 2016;17(1):39. doi:10.1186/s12910-016-0124-2. PMID: 27405974; PMCID: PMC4941036. Yamada, K.A., Patel, A.Y., Ewald, G.A. et al . How to Build an Integrated Biobank: The Washington University Translational Cardiovascular Biobank & Repository Experience. Clinical And Translational Science . 2013;6(3):226-231. doi: https://doi.org/10.1111/cts.12032 Seed deposit at Doomsday Vault ensures Australia’s plant future. ABC News. 2018 Mar 1. https://www.abc.net.au/news/2018-03-01/australia-makes-deposit-in-to-doomsday-vault-to-ensure-survival/9496308 De Souza, Yvonne G.; Greenspan, John S. Biobanking past, present and future: responsibilities and benefits. AIDS. 2013 ; 27(3):303-312. doi: 10.1097/QAD.0b013e32835c1244 Busby H, Martin P. Biobanks, national identity and imagined communities: The case of UK biobank. Science as Culture. 2006 Sep;15(3):237–51. doi:10.1080/09505430600890693 Murtagh, M.J., Demir, I., Harris, J.R. et al. Realizing the promise of population biobanks: a new model for translation. Hum Genet . 2011;130:333–345. doi: https://doi.org/10.1007/s00439-011-1036-3 Ferolito BR, Dashti H, Giambartolomei C, Peloso GM, Golden DJ, Gravel-Pucillo K, et al. Leveraging large-scale biobanks for therapeutic target discovery. Human Genetics and Genomics Advances. 2026 Jan;7(1):100556. doi:10.1016/j.xhgg.2025.100556 Szustakowski JD, Balasubramanian S, Kvikstad E, Khalid S, Bronson PG, Sasson A, et al. Advancing human genetics research and drug discovery through exome sequencing of the UK Biobank. Nat Genet. 2021 Jul;53(7):942–8. doi:10.1038/s41588-021-00885-0 Rudan I, Marušić A, Campbell H. Developing biobanks in developing countries. J Glob Health. 2011 Jun;1(1):2–4. PubMed PMID: 23198094; PubMed Central PMCID: PMC3484738. Caulfield T, Burningham S, Joly Y, Master Z, Shabani M, Borry P, et al. A review of the key issues associated with the commercialization of biobanks. Journal of Law and the Biosciences. 2014 Mar 1;1(1):94–110. doi:10.1093/jlb/lst004 Nature Index. 2021. How to be part of a research consortium. Available from: https://www.nature.com/nature-index/news/how-to-be-part-of-a-research-consortium Hudson (Chairperson) TJ, Anderson W, Aretz A, Barker AD, Bell C, Bernabé RR, et al. International network of cancer genome projects. Nature. 2010 Apr;464(7291):993–8. doi:10.1038/nature08987 Previous article back to Fact & Fiction Next article
- Print Edition 2: Issue 4, 5 and 6 | OmniSci Magazine
< Back to Print Editions Print Edition 2: Issue 4, 5 and 6 2023/2024 ABOUT THIS EDITION In various languages, the word ‘science’ can be traced back to its Latin origins of simply meaning ‘to know’. Today, explorers, curators, and researchers of scientific knowledge understand this as a systematic acquisition of information, with observations made and theories tested as we try to comprehend our world. For true advancement, science requires reciprocity: the mutual sharing between ‘scientists’ and individuals of society alike. In such a discourse we celebrate the beauty of scientific progress, whilst too holding space for the unease new unknowns can bring. Science communication is how we can continue to alleviate this dissonance, bridging knowledge gaps and seeking scientific understanding for all. The creation of Issue 4: Mirage, Issue 5: Wicked and Issue 6: Elemental over 2023 and 2024 has seen contributors create ever more informative content, aiming to make the innovations of science readily accessible to the public. Through experimenting with new formats, genres and mediums for illustrations, our contributors have formed a body of work that seeks to captivate and question. FEATURED ISSUES Issue 4: Mirage This issue explores the realms of science that are not what they seem. Is that shape in the distance reality or just a figment of your imagination? Issue 5: Wicked This issue spotlights the mischievous, malevolent and morally dubious. Issue 6: Elemental This issue explores the building blocks that comprise the world we live in. PURCHASE A COPY Keen to purchase a copy of the magazine? Click here to do so, at an OmniSci Magazine exclusive price! Alternatively, visit the Science Gallery Melbourne to find our magazines stocked in person. back to print editions
- The Intellectual's False Dilemma | OmniSci Magazine
The Intellectual’s False Dilemma: Art vs Science By Natalie Cierpisz The age-old debate once again resurfaces. How do art and science truly interact? Is one dependent on the other? How does the ‘art intellectual’ embrace science, and how does the ‘science intellectual’ embrace art? Is this all a meaningless debate anyway? Edited by Andrew Lim, Mia Horsfall & Hamish Payne Issue 1: September 24, 2021 Illustration by Casey Boswell The autumnal Melbourne wind whistles through the naked plane trees lining South Lawn, the sky is flat and grey. Two individuals who regard themselves and only themselves as ‘intellectual paragons’ are seated on a somewhat uncomfortable wooden bench, a perfect perch for people-watching, yet they are rather egotistical and notice only their own presence. One carefully places down their black coffee to light a hand-rolled cigarette; they are a liberal arts intellectual. As the wind grows stronger, the other tightly wraps a lab coat around themselves, and pushes a pair of wire-rimmed spectacles up their nose for the nth time. This would be our scientist. “So, are you still fooling around with your test tubes and pretty lights?” asks the liberal arts academic, cigarette hanging out the corner of their mouth. “If you mean, am I still investigating antiprotons using laser spectroscopy, then yes, indubitably so. How’s your fooling around with Hegel going?” replies the scientist, again pushing their glasses back up to a suitable height. The liberal arts intellectual is quick to retort the scientist’s trite remarks - they are in fact composing a Hegelian analysis of The Communist Manifesto, and not ‘fooling around’ by any means. The tension between the two self-professed intellectuals is building. The two appear to be fighting for dominance in their passive attacks on ego. So goes the age-old feud between the arts and the sciences. These two shallow characters play into the false dilemma that science and art are separate, distinct, alien. Two polar opposites. A total and unequivocal dichotomy. In all fairness, it is difficult to imagine many people will take this polarised a stance on the relationship between art and science. And now, as we delve into the complex relationship between the two domains, it should become clear that science and art are functionally interdependent (1), and considering art and science as totally separate is simply absurd. Let’s get back to our two feuding intellectuals. There seems to be much stereotypical disjunction between the two. But how does this translate to the true relationship between art and science? If the liberal arts intellectual and scientist were not so wrapped up in their self-interested ways, perhaps their gaze would slowly drift to the grandiose arches and imposing columns of the Old Quad. The harmonious form and mathematical ratios of these monuments are an enduring reminder of the architectural leaps and bounds made in the early 14th century, a blended pursuit of art and science. Ergo, we will head to one of the greatest paradigm shifts in Western history – the Renaissance. The Renaissance roughly spanned from the 14th to the 17th century and was a period of complete intellectual revolution – for both science and the arts (2). Everyone is familiar with Leonardo da Vinci, the great Renaissance artist. Less people know that he was also an inventor and a man whose artistic practice was heavily influenced by science (3). To ensure his paintings were as realistic as possible, Da Vinci dissected cadavers to better understand human anatomy, and studied optics and astronomy to perfect his use of space and form in paintings like The Last Supper. Likewise, scientists like Nicholas Copernicus and Galileo Galilei kickstarted a revolutionary paradigm shift towards the heliocentric model, their work in optics and astronomy being heavily reflected in artworks of the same era. Both science and art challenged what was for centuries prior considered the status quo. Source: Leonardo da Vinci, The Last Supper, 1498, tempera on gesso, pitch, and mastic, 460 cm × 880 cm, Wikipedia, https://en.wikipedia.org (4). This certainly isn’t a call for readers to head to the Melbourne General Cemetery and begin digging up specimens, nor to transfer to a double degree in fine arts and biomedicine. Instead, the point is more about how fruitful interaction between the two domains can be, and how one requires the other to flourish. Returning briefly to South Lawn, the snarky liberal arts intellectual continues looking bored and takes out their copy of The Myth of Sisyphus. Sitting directly opposite them the scientist has gone back to finishing the latest New Scientist podcast and calculating a quantum theory of gravity. We have seen that science can inspire art, but how can art inspire science? “The greatest scientists are artists as well.” (5) So said perhaps the most well-known scientist of the modern century. Not only did Albert Einstein develop the special and general theory of relativity (we won’t get into the mathematical specifics for both our sakes), he was also a talented violinist and pianist. Einstein often credited his artistic side for his success in science, testifying that, "the theory of relativity occurred to me by intuition, and music is the driving force behind this intuition. My parents had me study the violin from the time I was six. My new discovery is the result of musical perception.” (6) We have already seen how science prompts art to create new visions, and Einstein was no exception. His revolutionary ideas about space and time have been acknowledged as a prime artistic influence for Picasso’s arguably infamous Cubist style, as well as for the Surrealist art movement. (7) But the arts are not just confined to visual and musical expression. How about the area of expertise of our liberal arts friends? Liberal arts as they are known today, include sociology, literature, philosophy, psychology, politics, and more. The knowledge and, most importantly, critical thinking that is learnt through humanistic education is perhaps key to the future of science. As the world changes and evolves, humans must change and evolve with it, creating innovative solutions along the way. If we shift our focus to around the 1st century BCE, we will encounter what is widely regarded as the coining of the term artes liberales, or liberal arts. Roman statesman, scholar and writer Marcus Tullius Cicero wrote extensively about a wide array of topics, from politics and education to Stoic philosophy. “Artes liberales” roughly translates to “subjects worthy of a free person” - academic study that would enable one to actively participate in society (8). This curriculum consisted of a focus on seven key disciplines of rhetoric, geometry, grammar, music, astronomy, arithmetic, and logic. Liberal arts by nature are not the antithesis of science. From the crux of the artes liberales evolved the study of mathematics, physics, philology, history, and so on. Today we have reached a point where these seven disciplines have evolved and branched out so expansively that we have lost sight of the fact that our modern-day science and arts curriculums are sown from the same seed. Both science and art stem from the real world. Simply put, science is a lens into the study of this world and the inhabitants within it. Art is another lens into this complex system, providing a different but equally valuable perspective. Life is not binary, so neither should be our approach to studying it, and by virtue studying ourselves. Now is the time to embrace such transdisciplinary thinking. We need to bridge the gap between rigorous climate science facts and currently inadequate policy making, assess the ethics of the future of gene-editing, and ultimately become better thinkers. The combined intellectual strength of analytical thinking associated with science, where we learn how to test hypotheses, interpret data and draw valid conclusions; and the arts, where we learn critical thinking, how to develop arguments, how to understand a diverse audience, is necessary to keep humanity’s head above water as our world rapidly changes. Take for example the future of the CRISPR-Cas9 editing tool. This enzyme-based tool allows scientists to remove or add sections of DNA sequence in our genome, our code for life. With this ‘hand of God’ comes great responsibility. Collaboration needs to be made between scientific thinkers and humanistic thinkers to identify what type of robust legislation needs to be implemented to ensure ethical use of this tool. It is no longer a case of scientists working in isolation in underground bunkers. Scientists are making huge strides in research that extend to and greatly impact the wider community. Cases like CRISPR-Cas9 demand a lens from science and a lens from the arts in order to see the full picture – and in this case, to ensure the ethical and safe practise of a tool that has potential to save lives and improve individuals’ quality of life – but this only happens if science and art function in harmony. So back to you, the reader. Perhaps think about enrolling in that philosophy breadth subject next semester that your liberal arts friend raves about. Pick up that popular science book you have been eyeing off at Readings on Lygon St. Listen to that science podcast that keeps popping up on your Spotify homepage (The BBC’s The Infinite Monkey Cage is excellent). Pick up that paintbrush. Go visit Science Gallery Melbourne, a recent art scene addition affiliated with University of Melbourne – how fitting! This isn’t Romeo and Juliet, where you are either a Capulet or a Montague. Rather, this is a case of wave-particle duality, where an electron is both a wave and a particle, and you are both an artist and a scientist. As the typical Melbourne wind continues to pick up and the Old Arts clocktower strikes 7:00 pm, it appears the liberal arts intellectual just swapped their copy of The Myth of Sisyphus for the scientists’ copy of Brief Answers to the Big Questions. Looks like they’re making progress. References: 1. Richmond, Sheldon. “The Interaction of Art and Science.” The MIT Press 17, no. 2 (1984): 81-86. https://www.jstor.org/stable/1574993 . 2. History.com Editors. “Renaissance.” History.com. April 4, 2018. https://www.history.com/topics/renaissance/renaissance . 3. Powers, Anna. “Why Art is Vital to the Study of Science.” Forbes. July 13, 2020. https://www.forbes.com/sites/annapowers/2020/07/31/why-art-is-vital-to-the-study-of-science/?sh=7dfd8f8942eb . 4. Da Vinci, Leonardo. The Last Supper. 1498. Tempera on gesso, pitch, and mastic. 460 cm × 880 cm. Wikipedia. https://en.wikipedia.org . 5, 6. Root-Bernstein, Michelle. “Einstein On Creative Thinking: Music and the Intuitive Art of Scientific Imagination.” Psychology Today. March 31, 2010. https://www.psychologytoday.com/au/blog/imagine/201003/einstein-creative-thinking-music-and-the-intuitive-art-scientific-imagination . 7. Muldoon, Ciara. “Did Picasso know about Einstein?” Physics World. November 1, 2002. https://physicsworld.com/a/did-picasso-know-about-einstein/ . 8. Tempest, Kathryn. “Cicero’s Artes Liberales and the Liberal Arts.” Ciceronian on Line 4, no. 2 (2020): 479-500. https://doi.org/10.13135/2532-5353/5502 . Feynman, Richard, P. The Pleasure of Finding Things Out: The Best Short Works of Richard P. Feynman. New York: Basic Books, 2005. Science Gallery Melbourne. “Inspiring and Transforming Curious Minds.” Published 2021. https://melbourne.sciencegallery.com/what-we-do . White, Fiona. “Why art and science are better together.” The University of Sydney News. September 17, 2020. https://www.sydney.edu.au/science/news-and-events/2020/09/17/arts-and-science-better-together.html .
- Fiction Disguised as Fact: The Cost of Scientific Misinformation | OmniSci Magazine
< Back to Issue 10 Fiction Disguised as Fact: The Cost of Scientific Misinformation by Kara Miwa-Dale 2 June 2026 Edited by Nushi Singh In 1998, Andrew Wakefield published a paper in The Lancet claiming that the MMR vaccine was linked to autism. For such a serious claim, the evidence was astonishingly weak (1). The study included only 12 hand-picked participants, had no control group, and was riddled with inconsistencies. To make matters worse, Wakefield failed to disclose that he had received funding from a lawyer representing parents taking legal action against vaccine manufacturers. He further concealed that he had filed a patent for a rival vaccine that stood to benefit if confidence in the MMR vaccine fell. Despite these glaring flaws, the paper gained enormous influence. Media outlets across the world amplified its alarming claims, often with little scientific scrutiny (2). The Wakefield study became one of the clearest examples of fiction disguising itself as fact: a false narrative cloaked in the appearance of scientific credibility. Once released into the public sphere, emotionally charged claims quickly began to overshadow scientific evidence. Wakefield’s paper sparked widespread concern about the MMR vaccine. Few members of the public were likely to read the original study themselves, let alone critically evaluate its methods. Instead, many depended on journalists and news reports to interpret the findings. In doing so, they relied on a broader trust in scientific institutions and science communication, often assuming that published research had already been thoroughly vetted (3). This misplaced trust had far-reaching consequences. Before the paper was published, MMR vaccination rates in the UK sat at around 91-92%. Within five years, by 2003, this had fallen to approximately 80% (4). Although it is impossible to prove that Wakefield’s paper alone caused this drop, there is little doubt that it ignited widespread anxiety. By the time subsequent research had comprehensively refuted the claims (5, 6, 7), public trust had already been badly damaged. The media played an important role in amplifying parental fear. News coverage often prioritised emotional headlines and personal anecdotes over scientific evidence. Although evidence supporting vaccine safety was reported during this time, it accounted for only 37% of media stories during the controversy (2). Parents who were unsure about vaccinating their children were strongly influenced by mass media coverage (8). In one Welsh study, parents who chose not to vaccinate their children were 4.5 times more likely to rely on newspapers for information about the MMR vaccine (9). Twelve years later, Wakefield’s paper was finally retracted (10). By then, however, the damage had already been done. Despite overwhelming evidence disproving the claims, many people continued to believe them. Psychologists describe this as the ‘continued influence effect’, where misinformation can continue shaping attitudes and behaviour even after it has been debunked (11). Misinformation is not only persuasive — in some cases, it can also be deadly. It would be comforting to believe that society has become better at recognising misinformation. Unfortunately, the problem remains deeply entrenched. In some cases, misinformation does not originate from fraudulent researchers, but from governments themselves. This is perhaps even more insidious, because institutional authority can give misinformation an appearance of legitimacy that is extraordinarily difficult to undo. A striking example emerged in Japan in 2013, following the introduction of a national HPV vaccination program for teenage girls. The vaccine was supported by strong scientific evidence demonstrating its effectiveness in preventing cervical cancer (12). Yet only two months after launching the program, the Japanese government suspended its active recommendation of the vaccine due to growing public concern about safety (13). These concerns were largely driven by media reports of alleged side effects following vaccination. Television programs and newspaper stories featured emotional stories from young women reporting chronic pain and neurological symptoms, triggering widespread panic across the country (14). Crucially, many media outlets failed to emphasise that no scientific evidence had established a causal link between the vaccine and these symptoms. Although the government described the suspension as temporary while investigations continued, political caution and public pressure transformed it into a prolonged policy pause. Vaccination rates plummeted from 70% to barely 1% within a single year (15). The suspension ultimately lasted more than eight years, creating what researchers have described as a ‘lost generation’ of women who missed the opportunity to be protected against HPV (14). While the program has since been reinstated, public trust has not fully recovered. As of 2025, vaccination rates remain around 30% — a far reach from the World Health Organisation target of 90% (16). The long-term consequences may not become apparent for decades, as cervical cancer rates rise in under-vaccinated populations. This case highlights the powerful role of the media in shaping public perceptions of risk, and in turn, influencing policy decisions with enduring public health consequences. Addressing misinformation is not solely the responsibility of scientists or governments. Journalists and media organisations also play a critical role in shaping public understanding. The persistence of misinformation highlights an important reality: scientific evidence alone is not enough. Even the most robust research can be undermined if it is not communicated in a way that is accessible, transparent and trustworthy. This is where science communication becomes essential — helping to bridge the gap between evidence and public understanding so that scientific knowledge can inform real-world decisions. In the space between fact and fiction, communication determines which voice is heard. In an age where information moves faster than ever, the ability to communicate science clearly, honestly, and effectively may be just as important as the science itself. References 1. Flaherty DK. The Vaccine-Autism Connection: A Public Health Crisis Caused by Unethical Medical Practices and Fraudulent Science. Annals of Pharmacotherapy . 2011;45 (10):1302-1304. doi: 10.1345/aph.1Q318 2. Lewis J, Speers, T. Misleading media reporting? The MMR story. Nature Reviews Immunology . 2003; 3 (11):913-918. doi:10.1038/nri1228 3. Howell EL, Wirz CD, Scheufele DA, Brossard D, Xenos MA. Deference and decision-making in science and society: How deference to scientific authority goes beyond confidence in science and scientists to become authoritarianism. Public Understanding of Science . 2020; 29 (8):800-818. doi:10.1177/0963662520962741 4. Pearce A, Law C, Elliman D, Cole TJ, Bedford H. Factors associated with uptake of measles, mumps, and rubella vaccine (MMR) and use of single antigen vaccines in a contemporary UK cohort: prospective cohort study. BMJ . 2008; 336 (7647):754-757. doi:10.1136/bmj.39489.590671.25 5. Peltola H, Patja A, Leinikki P, Valle M, Davidkin I, Paunio M. No evidence for measles, mumps, and rubella vaccine-associated inflammatory bowel disease or autism in a 14-year prospective study. The Lancet . 1998; 351 (9112):1327-1328. 6. Madsen KM, Hviid A, Vestergaard M, et al. A population-based study of measles, mumps, and rubella vaccination and autism. New England Journal of Medicine . 2002; 347 (19):1477-1482. doi:10.1056/NEJMoa021134 7. Taylor B, Miller E, Farrington C, et al. Autism and measles, mumps, and rubella vaccine: no epidemiological evidence for a causal association. The Lancet . 1999; 353 (9169):2026-2029. doi:10.1016/S0140-6736(99)01239-8 8. Evans M, Stoddart H, Condon L, Freeman E, Grizzell M, Mullen R. Parents' perspectives on the MMR immunisation: a focus group study. Br J Gen Pract . 2001; 51 (472):904-910. https://pmc.ncbi.nlm.nih.gov/articles/PMC1314147/ 9. Walsh S, Thomas DR, Mason BW, Evans MR. The impact of the media on the decision of parents in South Wales to accept measles-mumps-rubella (MMR) immunization. Epidemiol Infect . 2015; 43 (3):550-560. doi:10.1017/s0950268814000752 10. Rao TS, Andrade C. The MMR vaccine and autism: Sensation, refutation, retraction, and fraud. Indian J Psychiatry . 2011; 53 (2):95-96. doi:0.4103/0019-5545.82529 11. Johnson HM, Seifert CM. Sources of the continued influence effect: When misinformation in memory affects later inferences. Journal of Experimental Psychology: Learning, Memory, and Cognition . 1994; 20 (6):1420. doi:10.1037/0278-7393.20.6.1420 12. Paavonen L, Naud P, Salmerón J, et al. Efficacy of human papillomavirus (HPV)-16/18 AS04-adjuvanted vaccine against cervical infection and precancer caused by oncogenic HPV types (PATRICIA): final analysis of a double-blind, randomised study in young women. The Lancet . 2009; 374 (9686):301-314. doi:10.1016/S0140-6736(09)61248-4 13. Iked S, Ueda Y, Yagi A, et al. HPV vaccination in Japan: what is happening in Japan? Expert Review of Vaccines . 2019; 18 (4):323-325. doi:10.1080/14760584.2019.1584040 14. Takahashi T, Ichimiya M, Tomono M, et al. Overcoming HPV Vaccine Hesitancy in Japan: A Narrative Review of Safety Evidence, Risk Communication, and Policy Approaches. Vaccines . 2015; 13 (6):590. https://www.mdpi.com/2076-393X/13/6/590 15. Yagi A, Ueda Y, Oka E, Nakagawa S, Kimura T. Human papillomavirus vaccination by birth fiscal year in Japan. JAMA network open . 2024; 7 (7):e2422513. https://doi.org/10.1001/jamanetworkopen.2024.22513 16. Sazawa M, Ishiguro C, Mimura W, Maeda M, Murata F, Fukuda H. Impact of the resumption of proactive recommendation of HPV vaccination on HPV vaccination rates in Japan: an interrupted time series analysis based on the VENUS study. BMJ Public Health . 2025; 3 (2):e000982. doi:10.1136/bmjph-2024-000982 Previous article back to Fact & Fiction Next article
- To Prevent Climate Catastrophe, Keep Reading | OmniSci Magazine
< Back to Issue 10 To Prevent Climate Catastrophe, Keep Reading by Madeleine Kelly 2 June 2026 Illustrated by Kylie Wang Edited by Nushi Singh SPOILERS AHEAD: The Ministry for the Future, Strange World You’d be forgiven for thinking the world is ending. I’ve thought it’s happening too. As a climate science student who has left lectures in tears and had to put a cap on how many times I check the news, I often feel anxious for what the future will hold. What really frustrates me though, is that when I sit down to tune out the horrors, I’m presented with the same looming catastrophe in books and movies. Ecological collapse, war, deadly diseases and extreme weather events not only dominate our daily headlines, but also our entertainment. The way we imagine the future in fiction is too often bleak and dystopian. Stories like 1984 , The Hunger Games or The Handmaid’s Tale predict a future where ecological collapse has led to oppressive control by totalitarian governments (1, 2, 3). In Mad Max and Waterworld it has left us hunting each other for sport (4, 5). Eco-fascists destroy worlds in Snowpiercer (6) ; sea level rise has inundated Melbourne’s poorest in The Sea and Summer (7); and collective inaction leads to the literal end of the world in Don’t Look Up (8). Everywhere you look, the apocalypse is inescapable. Even comical stories like Sharknado forecast that devastating climate change is inevitable and will leave humanity scrambling to survive (9). We can’t catch a break. If this is all we can tell of our future, then this is cause for concern. Stories are more than just entertainment – they have real world impact. Science fiction, in particular, has already changed the world countless times over. Video phone calls, automatic sliding doors and self-driving cars are amongst the dozens of inventions inspired by the words and worlds of science fiction (10). Fiction can also influence and act as a warning of political and social systems. Cyberpunk as a genre anticipated worlds defined by mass surveillance, corporate greed and societal decay – all of which you can find inside a Coles supermarket today. Stories can become self-fulfilling prophecies. Warnings are all well and good to raise awareness, but when it comes to the climate crisis, we certainly don’t need any more catastrophising. Climate change is recognised as a serious threat to mental health, with eco-anxiety on the rise, especially amongst young people (11,12). In 2021, a survey found that 75% of young people believe the future is “frightening” and more than 50% felt “helpless and powerless” (13). For some, this can encourage them to engage in climate action (14), but for others it can be debilitating. Severe eco-anxiety has been linked to a feeling coined ‘eco-paralysis’, where individuals are too overwhelmed to take action on climate change (15, 16). Disaster and dystopian stories have, ironically, aided this rise of eco-anxiety and inaction. The Day After Tomorrow (2004), arguably the most famous piece of climate fiction, is set in a near future where the North Atlantic Oceanic current has broken down due to climate change, shepherding in an ice age that freezes over New York City (17). While the movie increased awareness and concern over climate change, research found it left audiences unsure of how to act and scared for the future (18, 19). With our crippled imagination for optimistic alternatives, we’re left stranded in the dystopia, watching helplessly as our future is swept away by Sharknado. We need to rewrite the script. Solarpunk, an emerging sci-fi subgenre and social movement, is trying to do just that. Solarpunk stories reject the doomism and imagine futures where humanity has succeeded in warding off devastating climate change. They include stories like Disney’s Strange World where humanity swaps an unsustainable fuel source for renewable energy (20), as well as stories like Arco and A Psalm for the Wild Built where we rely only on green technology, live within our means and rewild most of the planet (21, 22). What makes solarpunk stories so compelling is that they don’t shy away from showing how complex the problem is and how difficult system change can be. The Ministry for the Future by Kim Stanley Robinson centres around an organisation that is formed to protect the rights of future generations from climate change (23). Using different perspectives and writing styles, Robinson explains the science of climate change and the complicated world of climate economics and policy. He illustrates just how much needs to be changed, but without overwhelm. The story does not leave you eco-paralysed. Instead, it acts as a roadmap showing all the possible pathways to a sustainable future. In taking these actions, we not only address climate change, but also the social inequalities that are intertwined with it. The energy transition is complete, and a successful and equitable restructuring of the global economy has abolished billionaires. It’s a future we can look forward to. At their core, solarpunk stories have hope. A realistic hope that we can achieve a sustainable future using the tools we already have. We need this right now, because hope is incredibly useful in inspiring and navigating change. People with higher levels of hope are generally better equipped to navigate traumatic or stressful circumstances (24). Hopeful people are also more likely to engage in pro-environmental behaviour. One study of more than 500 high school students found that students who felt hopeful about the future were more likely to engage in sustainable behaviours (25). While a number of students also exhibited eco-anxiety, the study concluded that hope was the stronger predictor for actually taking action. If dystopian stories are becoming a self-fulling prophecy, I’m willing to bet – and science is too – that if we tell them, the same could be true for stories of ecological and societal care. The main challenge here is that these stories remain niche. Like most climate fiction, they often only circulate within audiences already concerned about environmental issues, rather than reaching people who are disengaged from or hostile towards climate action (26). This is precisely why these stories need to become more visible. To normalise this future, more of us need to be creating and consuming solarpunk stories. Preventing the climate apocalypse requires you to pick up a book or watch a movie. The stories we tell today shape the world we build tomorrow. So, let them be stories of hope. References Orwell G. 1984 . Martin Secker & Warburg Ltd; 1949. Collins S. The Hunger Games . Scholastic Press; 2008. Atwood M. The Handmaid’s Tale . McClelland & Stewart; 1985. Miller G. Mad Max . Roadshow Film Distributors; 1979. Reynolds K. Waterworld . Universal Pictures; 1995. Ho BJ. Snowpiercer . CJ Entertainment; 2013. Turner G. The Sea and Summer. Faber & Faber; 1987. McKay A. Don’t Look Up . Netflix; 2021. Ferrante AC. Sharknado . The Asylum and Syfy Films; 2013. BBC News. Science fact: Sci-fi inventions that became reality. 2016. Accessed May 24 2026. https://www.bbc.com/news/health-38026393 Clayton S, Karazsia BT. Development and validation of a measure of climate change anxiety. Journal of Environmental Psychology . 2020;69:101434. doi:10.1016/j.jenvp.2020.101434 Passmore H, Lutz PK, Howell AJ. Eco-Anxiety: A Cascade of Fundamental Existential Anxieties. Journal of Constructivist Psychology . 2020;36(2):138-153. doi:10.1080/10720537.2022.2068706 Hickman C, Marks E, Pihkala P, et al. Climate anxiety in children and young people and their beliefs about government responses to climate change: a global survey. Lancet Planet Health . 2021;5:e863-73. doi: 10.1016/S2542-5196(21)00278-3 Verplanken B, Marks E, Dobromir AI. On the nature of eco-anxiety: How constructive or unconstructive is habitual worry about global warming? Journal of Environmental Psychology . 2020;72:101528. doi:10.1016/j.jenvp.2020.101528 Innocenti M, Santarelli G, Lombardi GS, et al. How Can Climate Change Anxiety Induce Both Pro-Environmental Behaviours and Eco-Paralysis? The Mediating Role of General Self-Efficacy. International Journal of Environmental Research and Public Health . 2023;20(4):3085. doi:10.3390/ijerph20043085 Leger-Goodes T, Malboeuf-Hurtubise C, Mastine T, Généreux M, Paradis P, Camden C. Eco-anxiety in children: A scoping review of the mental health impacts of the awareness of climate change. Frontiers in Psychology . 2022;13:872544. doi: 10.3389/fpsyg.2022.872544 Emmerich R. The Day After Tomorrow . 20th Century Fox; 2004. Svoboda, M. The lingering influence of ‘Day After Tomorrow’. Yale Climate Connections. 2014. Accessed May 24 2026. https://yaleclimateconnections.org/2014/11/the-long-melt-the-lingering-influence-of-the-day-after-tomorrow/ Lowe T, Brown K, Dessai S, Doria MF, Haynes K, Vincent K. Does tomorrow ever come? Disaster narrative and public perceptions of climate change. Public Understanding of Science . 2006;15(4):435-457. doi:10.1177/0963662506063796 Hall D. Strange World . Walt Disney Studios and Motion Pictures; 2022. Bienvenu U. Arco . Diaphana Distribution; 2025. Chambers B. A Psalm for the Wild Built . Tor Books; 2021. Robinson KS. The Ministry for the Future . Orbit Books; 2021. Ritschel LA, Cassiello-Robbons C. Hope and depression and personality disorders. Current Opinion in Psychology . 2023;49:101507. doi:10.1016/j.copsyc.2022.101507 Finnegan W. Educating for hope and action competence: a study of secondary school students and teachers in England. Environmental Education Research . 2022;29:1617-1636. doi:10.1080/13504622.2022.2120963 Schneider-Mayerson M. The Influence of Climate Fiction: An Empirical Survey of Readers. Environmental Humanities . 2018;10(2):473-500. doi: 10.1215/22011919-7156848 Previous article back to Fact & Fiction Next article
- Ancient Asian Alchemy: Big Booms | OmniSci Magazine
< Back to Issue 9 Ancient Asian Alchemy: Big Booms by Isaac Tian 28 October 2025 Illustrated by Aisyah Mohammad Sulhanuddin Edited by Luci Ackland One question has plagued the human condition since the beginning of time: how can we escape death? Well, we certainly know who didn’t find the answer – the alchemists of ancient China. It’s 210 BC, and you are an alchemist standing before Emperor Qin Shi Huang in his court. You hand him an elixir supposed to grant him immortality and eternal reign. Only the serum contains what we now call “mercury” and if anything, you granted him mortality, as he drops dead before you (1). Where does one begin in this journey to immortality? How do we combine chemicals to find the perfect serum? Keep in mind, we have not even come close to establishing the periodic table at this point (no, that will occur about 1000 years later) (2). Saltpetre – or potassium nitrate – had been used extensively to treat common illnesses and to maintain good health. There’s our starting point (3). The search for this magic elixir persists for the next eleven centuries. We never give up… do we? The ingenuity of the alchemists spoke to them: it told them to mix in a few other ingredients to the saltpetre. With the trio of saltpetre, sulfur and charcoal, gunpowder was henceforth born into this world (4). The alchemists must have been in for a surprise when their “potion of immortality” sparked and exploded before them. So how does gunpowder explode? Why don’t other flammable items like match tips and dry wood explode when we set them alight? It comes down to a few key things. First is our perception of explosions. Chemicals don’t simply “explode” – it’s not an inherent quality of reactions – however, they can combust. Combustion is the release of energy from a fuel. Wood and matches combust, but they do so in a way that is relatively slower than gunpowder. Gunpowder combusts rapidly – so there is a large amount of energy release within a short period of time. Secondly, it’s about the availability of oxygen. Items that combust slowly typically have to wait for the oxygen to trickle in from the surrounding air, since oxygen is a critical component of combustion. This does not apply to gunpowder. The oxygen for its combustion is right there in the nitrate compound (of potassium nitrate – or saltpetre). So unlike burning wood or matches, the combustion does not need to wait for oxygen to arrive from the surrounding environment – it’s already in there with the rest of the powder (5)! To go further on that point: the closer the atoms are, the faster the combustion reaction can progress, because chemical compounds don’t need to wait long for the heat to get to them. Since gunpowder is… well… a powder, it’s rather compact and all the molecules of potassium nitrate, sulfur, and carbon sit tightly next to one another. It is this physical arrangement that permits the fast transfer of heat between molecules, ensuring that a lot of energy can be released at once. Ultimately, when all these physical and chemical phenomena occur in perfect unison, the high temperatures rapidly increase the kinetic energy of surrounding air molecules, causing them to shoot outwards at great speeds to form a “barrier” of sorts. When this barrier, also known as a shockwave, hits your eardrums, the gunpowder delivers what it does best: BOOM! Now, let’s combust some gunpowder, build up some gaseous pressure, and launch ourselves into the modern day. It’s been about twelve centuries – what have we been doing with all the gunpowder? As it turns out, we humans are very inventive, but also violent (Wow – who knew?). We quickly realised that the physical properties of the resulting gases can be harnessed to quickly move very heavy objects (6). Said heavy objects could then be guided in the direction of, say, a human being or a structure. Weaponry derived from gunpowder has existed for a very long time, albeit rather inefficient at first. The introduction of gunpowder to warfare came in the early 10th century, when soldiers applied gunpowder to arrows that would ignite and create fire arrows. Of course, whilst it might have been effective in creating a hole in humans, it was significantly less so when it came to creating holes in walls and structures. Only after 300 years did we then invent cannons and guns. However, those guns were slow – really, really slow – to the point that bows and arrows were actually preferred during warfare of that era. It would be another 600 years before we realised that there were more effective ways of reloading a gun; brandishing a new trend of military technology that would set the stage for the First and Second World Wars (7). By that point, the most terrifying of weapons had begun to stray away from the use of gunpowder. Missiles and rockets began employing other chemicals as propellants, owing to the advantage it had over gunpowder (7). It would also be remiss of this article to omit the exploitation of atomic power – pervading the world with such destruction that gunpowder appeared like a child’s toy (8). The tragic irony of a supposed innovation in immortality leading to mortality by war and conflict will forever embed itself into our history. Even with the right intentions, the invention by the great minds of alchemy has sparked a chain reaction for widespread destruction and warfare. It only makes you wonder – what are we making now that will lead us further astray in the future? References 1. Glancey J. The army that conquered the world. BBC. Accessed August 24, 2025. https://www.bbc.com/culture/article/20170411-the-army-that-conquered-the-world 2. Guharay DM. A brief history of the periodic table. ASBMBTODAY. Accessed August 28, 2025. https://www.asbmb.org/asbmb-today/science/020721/a-brief-history-of-the-periodic-table 3. Butler A, Moffett J. Saltpetre in Early and Medieval Chinese Medicine. Asian Medicine . 2009;5(1):173-185. doi: 10.1163/157342109X568982 4. Paradowski, R.J. Invention of Gunpowder and Guns. EBSCO Research Starters. 2022. Accessed August 24, 2025. https://www.ebsco.com/research-starters/history/invention-gunpowder-and-guns 5. Stanford University. Detonation and Combustion. Stanford University. Accessed September 4, 2025. https://cs.stanford.edu/people/eroberts/courses/ww2/projects/firebombing/detonation-and-combustion.htm 6. Britannica. Ammunition | Bullets, Shells & Cartridges. Britannica. 2025. Accessed September 25, 2025. https://www.britannica.com/technology/ammunition 7. Beyer G. How Did Gunpowder Change Warfare? TheCollector. 2025. Accessed October 4, 2025. https://www.thecollector.com/how-did-gunpowder-change-warfare/ 8. ICAN. History of Nuclear Weapons. ICAN. Accessed October 4, 2025. https://www.icanw.org/nuclear_weapons_history Previous article Next article Entwined back to
- Glowing Limelight, Fashioned Stars | OmniSci Magazine
< Back to Issue 8 Glowing Limelight, Fashioned Stars by Aisyah Mohammad Sulhanuddin 3 June 2025 Edited by Kylie Wang Illustrated by Jessica Walton Good evening Rose Bowl, Pasadena! The crowd erupts into a roar, the stadium air overcome with a thunder of adulation. Between throngs of teenagers tearing through streets in pursuit of the Beatles, concert-goers fainting at the sight of Michael Jackson, and Top Tens of the day made to navigate flirty fan calls on daytime TV in front of live audiences (1), pop history as we know it has always revolved around the deep, fanatic reverence of the star . Stars in all corners of the entertainment cosmos, be it music, film or TV, have long had their lives glamorised. Tales told of luxurious jet-setting, post-show mischief and infamous public appearances peppered with paparazzi. Fame turned into fables, circulated eagerly by the wider populace. Having avidly followed a plethora of musicians, actors and comedians at different points of my own life, the gurgling vortex of stardom culture has remained ever-intriguing. Why do our relationships with stars mean so much to our society, and have they shifted over time? Public perceptions & parasocial relationships Our journey begins with the making of a star. A star is born from an assemblage of artistic choices: artwork, stage personas, press releases, bold onstage costumes and more, which constellate into a fashioned image. Or, a ‘manufactured personal reality’ (2). This reality is what audiences draw upon when forming attachments to stars, a process that moulds complex, contradicting human beings into idealised forms that may resonate, validate or provide meaning to them. The mid-century women empowered by the feminine sexuality and intelligence of Marilyn Monroe (2), or the working class Eastern European following of Depeche Mode who saw the band as an emblem of social rebellion under the USSR in the late 80s (3), are such examples. Such attachment gives rise to the infamous ‘parasocial relationship’ (PSR). An often derisive term aptly used today to call out toxic, boundary-crossing online fan behaviour, parasocial relationships at their core simply encompass socio-emotional connections formed with media figures (4). In it, audiences extend emotional energy, time or interest towards figures that whilst unreciprocated, create a perceived idea of intimacy similar to that of two-way relationships. For the audience, PSRs can evoke feelings of safety, trust and various forms of devotion, self-strengthened through personal habits – think dressing like a favourite ‘bias’, or diligently watching a favourite director’s closet picks. PSRs have historically been one-sided. Audience reactions to sensation and scandal have had the power to make or break an artist’s image, but restricted channels of dialogue meant that direct two-way feedback was often “fragmented” (2). The influencing power of the star’s image lay within reach of the star themselves, and more often than not, was shaped by the wider commercial agendas of their agency or labels. That is, until recently… The rise of the Internet Whilst the glitz and glamour of stardom remains strongly relevant, we can focus on the advent of the internet as the most powerful force in reshaping the relationship between fan and star. Termed the “o ne and a half sided” PSR (4), seen today is a shift in power dynamics towards one of increased fan-star symbiosis. As the theory notes, technology has allowed for greater perceived proximity and reciprocity, blurring the line between social and parasocial. Under the extensive nature of the current digital world, our internet presence has become increasingly considered a material extension of our real-life selves (4), whether through Zoom calls, real-time story updates or live vlogs. Direct messages or comments that allow instant reply have muddied the realm of physical and virtual reality, thus leading audiences to feel ‘physically’ closer to the figures in question. This decrease in constructed social distance has fostered notions of reciprocity, viewing stars as people they can reach out to and touch, converse with, and most importantly, influence in return – regardless of any actual ability to do so (4). As we witness stars defend their personal choices against an onslaught of ‘netizen’ backlash or wryly reply to a barrage of invasive thirst tweets (5), we see the increased power that global audiences have over said stars’ images. Eroded power barriers between the star and fan have heightened both positive and negative emotional engagement. Well-documented are various behaviours that disrespect boundaries between personal and professional lives, such as harassment, stalking, and other breaches of privacy. Yet, the rise of the ordinary, accessible star has also allowed greater exposure to previously hidden or stigmatised facets of figures’ lives, fostering safe spaces for perceived authenticity and vulnerability that can counter blind idealisation (6). Evolving industries & societies Under the diluted power networks of stardom today, we can describe celebrity image production as increasingly decentralised (6). Technology has made entry into the entertainment industry more accessible by providing numerous channels for artistic output, whether it be through releasing music independently on streaming services like Spotify, Bandcamp or Soundcloud, or creating short-form video skits on platforms like TikTok or Instagram. With top-down connections to age-old media institutions no longer required, the pool of faces that audiences can form relationships with has drastically expanded (7). Social norms – at the time of writing – have also welcomed the notion of diversified talents. As prevailing social, cultural and political structures shape value judgments made of stars (2), we have seen increased audience meaning-making in the dimensions of gender, ethnicity, class or sexual orientation over past decades (8) aligned with a gradual direction towards progressive and learned landscapes. Here, celebrity advocacy for causes and movements beyond the stage is nothing new, but fan bases can now dissect their forays into activism more publicly than ever before. A world unapologetically critical of “out of touch” (9) wealthy stars crooning out Lennon’s Imagine at the beginning of the pandemic would unlikely have welcomed the white-saviorist charity event that was Live Aid 1985 with as open arms as the dominant media narrative did then (10). A hyper-consumerist present If the exclusive stardom of yore can be likened to the dominance of a supermarket monopoly, then stardom today looks more like a diverse hub of online stores for buyers to ‘Click and Collect’ from. Whilst this setup offers diversified perspectives to a consuming audience, it embodies wider societal trends towards hyper-commodification. Market an image that sells well, and everyone will be famous for 15 minutes , as Andy Warhol supposedly declared (11). Reinforcing the ephemerality of mass consumerism are internet memes or trends (12) that morph and dilute rebellious celebrity motifs for overarching capitalistic agendas – think Brat Summer campaigns in the style of Charli xcx’s 2024 album co-opted by the most unethical multinational corporation you’ve ever come across. Like with the discourse exposing ‘nepo’ babies in the entertainment industry (13), we are reminded that despite the semblances of democratisation, the limelight remains far from a level stage. Stardom, beyond So what then? What lies in store for the future star? On one hand, the perception of proximity with the decline of ‘untouchable’ star personas can strengthen fan worship and deification, with frenzied consequences. On the other hand, increased artist-audience dialogue can pave the way for real change over performative gestures as lessening power imbalances bring a form of democratisation that can platform diverse and marginalised voices in art. All in all, stars today may no longer be able to fully present themselves and be perceived solely as spectral, enigmatic illusions that audiences can latch upon, but the new freedoms and avenues that come with being more truly known may be just as bedazzling. References 1. Robinson P. The great pop power shift: how online armies replaced fan clubs. The Guardian [Internet]. 2014 Aug 25; Available from: https://www.theguardian.com/music/2014/aug/25/great-pop-power-shift-how-online-armies-replaced-fan-clubs 2. Dyer R. Introduction. In: Heavenly Bodies [Internet]. Routledge; 2004. Available from: https://doi.org/10.4324/9780203605516 3. Wynarczyk N. Tracing Eastern Europe’s obsession with Depeche Mode [Internet]. Dazed. 2017. Available from: https://www.dazeddigital.com/music/article/36659/1/tracing-eastern-europe-s-obsession-with-depeche-mode 4. Hoffner CA, Bond BJ. Parasocial Relationships, Social Media, & Well-Being. Current Opinion in Psychology [Internet]. 2022 Feb;45(1):1–6. Available from: https://doi.org/10.1016/j.copsyc.2022.101306 5. Yodovich N. Buzzfeed’s “celebrities reading thirst tweets”: examining the sexualization of men and women in the #MeToo era. Journal of gender studies. 2024 Feb 28;33(8):1–11. Available from: https://doi.org/10.1080/09589236.2024.2324263 6. Driessens O. The Celebritization of Society and Culture: Understanding the Structural Dynamics of Celebrity Culture. International Journal of Cultural Studies [Internet]. 2013;16(6):641–57. Available from: https://doi.org/10.1177/1367877912459140 7. Carboni M. The digitization of music and the accessibility of the artist. Journal of Professional Communication [Internet]. 2014 Jun 4;3(2). Available from: https://doi.org/10.15173/jpc.v3i2.163 8. Stewart S, Giles D. Celebrity status and the attribution of value. European Journal of Cultural Studies [Internet]. 2019 Jul 21;23(1). Available from: https://doi.org/10.1177/1367549419861618 9. Caramanica J. This “Imagine” Cover Is No Heaven. The New York Times [Internet]. 2020 Mar 20; Available from: https://www.nytimes.com/2020/03/20/arts/music/coronavirus-gal-gadot-imagine.html 10. Grant J. Live Aid/8: perpetuating the superiority myth. Critical Arts [Internet]. 2015 May 4;29(3):310–26. Available from: https://doi.org/10.1080/02560046.2015.1059547 11. Nuwer R. Andy Warhol Probably Never Said His Celebrated “Fifteen Minutes of Fame” Line [Internet]. Smithsonian Magazine. Smithsonian Magazine; 2014. Available from: https://www.smithsonianmag.com/smart-news/andy-warhol-probably-never-said-his-celebrated-fame-line-180950456/ 12. Cirisano T. “Brat” summer and the dilemmas of going mainstream [Internet]. MIDiA Research. 2024. Available from: https://www.midiaresearch.com/blog/brat-summer-and-the-dilemmas-of-going-mainstream 13. Jones N. How a Nepo Baby Is Born [Internet]. Vulture. 2022. Available from: https://www.vulture.com/article/what-is-a-nepotism-baby.html Previous article Next article Enigma back to
- Everything, Everywhere, All at Once: The Art of Decomposition | OmniSci Magazine
< Back to Issue 6 Everything, Everywhere, All at Once: The Art of Decomposition by Arwen Nguyen-Ngo 28 May 2024 Edited by Subham Priya Illustrated by Jessica Walton From a single point in time, to a burst of colour and light, our universe came along into existence (The National Academy of Sciences, 2022). Within the multitude of galaxies and stars sprinkled across the universe, our little planet sits inside the solar system within the Milky Way. Like the way the universe came from a singularity, we were created from a singular cell. Over time, this cell divided and divided until we became these complex beings filled with different flavours of cells and the elements that comprise them. We are ever growing, just as the universe is ever expanding (Harvey, A., & Choi, C. Q., 2022). Though the fate of our universe is still a mystery, our fate is a little less mystical and thought-provoking – but that doesn’t make it any less interesting. Our less mystical yet fascinating fate begins with decomposition. Decomposition is the process in which dead tissue is broken down and converted into simpler forms. Large scavengers, such as vultures, foxes and crows, eat chunks of the corpse using it as a source of energy (Trees for Life, 2024). When these scavengers excrete waste — which is certainly not a pretty sight — their dung attracts smaller organisms like dung beetles. Little creepy crawlies — beetles, maggots and earthworms — all come along to the corpse, munching on its bits and pieces. They even lay their eggs in the openings of the corpse like the eyes, nose and mouth, an even LESSER pretty sight! If we zoom in further, we see microscopic bugs grow upon this dead body and take up nutrients. These bacteria then proceed with anaerobic decomposition, which occurs in the absence of oxygen. This produces gases like methane and carbon dioxide, causing the corpse to swell – the reason why dead bodies smell so bad (Trees for Life, 2024). After all that decaying, eventually, all that will remain of the carcass would be the cartilage, skin and bone, which a range of flies, beetles and parasites take advantage of (Trees for Life, 2024). Small critters such as mice and voles may come along, gnawing on the bone for calcium. How else are such little creatures supposed to get strong bones? Decomposition of dead flora is slightly different than the process for animals. For plant decomposition, fungi are the key players. When the tree leaves die and fall to the ground, they form a thick layer on the soil surface along with other dead plants, termed the litter layer (Trees for Life, 2024). Fungi have a body structure of white thread-like filaments called the hyphae, which resemble the white strings of floss. These white fungal floss take over the litter layer and consume nutrients whilst breaking down the litter layer. Unlike the decomposition of an animal, the decomposition process for plants is odourless. Phew! Over time, little wriggly earthworms begin to take control of breakdown. We use earthworms in our compost bins because they are great decomposers for dead plants and make organic fertiliser for our gardens. Whether an animal or a plant, decomposition takes each and every atom, from the carbon to the sodium atoms and recycles them to be used to create something new. It may be daunting from a human perspective to think that after all we’ve lived for, we would only be broken down and that the littlest bits of us, recycled. As our body takes its final breath, the brain fires the last of its neurons flooding our mind with bursts of colour, the way different elements cause the explosion of colours in fireworks lighting up the night sky. As the body decomposes, slowly each molecule of our body returns to the Earth, allowing for new life to take place. A sapling to sprout out from the depths of the soil. We are carried through the life of a new being; perhaps a tree, the grass or the flowers. Once again each molecule and atom in that being will return to the Earth like clockwork. And perhaps, return to the universe, a part of little sparkles that litter the night sky. References Harvey, A., & Choi, C. Q. (2022). Our expanding universe: Age, history & other facts . https://www.space.com/52-the-expanding-universe-from-the-big-bang-to-today.html Trees for Life. (2024). Decomposition and decay . https://treesforlife.org.uk/into-the-forest/habitats-and-ecology/ecology/decomposition-and-decay/#:~:text=Decomposition%20is%20the%20first%20 The National Academy of Sciences. (2022). How did the universe begin? How will it end? https://thesciencebehindit.org/how-did-the-universe-begin-how-will-it-end/#:~:text=The%20Big%20Bang%20theory%20says,in%20an%20already%20existing%20spac e Previous article Next article Elemental back to









