TOny, who is in his 50s, recently did a quick calculation of how much time he’s spent watching porn in his life. “The results were horrifying,” he says. Eight years. “It’s hard to even think about. The frustration is intense.”
Tony saw his first “hardcore” movie on VHS in the 1980s, when he was 12 years old. It was in his 20s that he first got online, which turned his habit into a “full-blown addiction.” For the past 30 years, he’s managed to maintain a double life: he works in care, has friendships and relationships with men and women. But there’s one side of him he keeps completely secret.
“So far, I’ve only told three people about this: two therapists, and now you,” he says. “I’ve kept it a complete secret from everyone I’ve ever known. I’m very careful to cover my tracks, even in relationships. My lack of interest in sex with my partner might be the only thing that makes her wonder.”
Tony has tried many times to stop watching porn but has never been able to go more than a month without it. He’s tried cutting down, banned masturbation, blocked porn sites, and tried to quit completely. But “the addict’s brain is very cunning and manipulative,” he says. He also tried therapy, but found it difficult to keep up with the costs long-term.
Still, Tony is grateful for one thing: he was young before the internet. “At least I had a normal youth. Parties, shows, adventures with friends. I had a girlfriend. I had a sex life. A guy like me doesn’t have that chance now.”
All statistics on pornography use in the UK and globally have skyrocketed due to the widespread use of mobile phones: in May 2023 alone, around 13.8 million people, a third of all internet-using adults, viewed pornography online. According to Ofcom
Of these, two-thirds were male. Although pornography companies do not report (or acknowledge) statistics on underage viewers, on average, children in the UK first see pornography at age 12. In a recent study, the Children’s Commissioner for England said: Much of what young people see is violent and extreme.
You’ve probably experienced this feeling before: after a long and exhausting day, all you want to do is curl up and sleep. But instead of allowing you to rest, your brain decides it’s time for some mischief, leaving you wide awake with thoughts racing through your mind.
So why does this happen? Why does our brain keep us awake when we’re most in need of sleep? The answer may lie in the fact that we’re just too tired to sleep.
If you’ve heard of this concept before, it’s often associated with babies who become “over-fatigued” when kept awake for too long, leading to stress and sleep disturbances.
However, the same phenomenon can occur in adults when unchecked emotions interfere with the body’s ability to shut down for sleep. And the longer you stay tired, the harder it becomes to fall asleep.
Fortunately, there are ways to break this cycle. In the following sections, we’ll not only explore what excessive fatigue is, but also share three simple, scientifically-backed steps to help you overcome excessive fatigue for good.
Excessive fatigue ruins your sleep
Being excessively tired is a paradoxical situation. When you’re physically and mentally drained, your brain is actually in a state of hyperarousal, making it difficult to relax and fall asleep.
This hyperarousal state hinders the body’s natural sleep mechanisms, particularly the buildup of sleep pressure.
Sleep pressure refers to the increase in neurochemicals and hormones that signal your body’s need for sleep as you stay awake throughout the day.
According to Professor Matt Jones from the University of Bristol, “As sleep pressure builds up, the brain may also become more excitable, with neurons in the cerebral cortex firing at an increased rate.”
By maintaining hyper-vigilance and allowing intrusive thoughts to dominate your mind, you disrupt the brain’s ability to reset the sleep pressure system, making it harder to fall asleep.
Furthermore, chronic fatigue and sleep deprivation can exacerbate this cycle by feeding troubling thoughts that persist into the following night.
In a recent study, individuals with insomnia were found to ruminate more about past embarrassing events than healthy sleepers, leading to longer sleep onset times.
Additionally, insomniacs may become hypersensitive to bodily sensations like their own heartbeat, further inhibiting their ability to fall asleep.
Dr. Jones explains, “Insomnia creates a heightened awareness of irrelevant information, placing undue strain on the brain and hindering the natural process of sleep onset.”
If you find yourself feeling overly tired and mentally restless when trying to sleep, it indicates that key brain areas are still in a state of hyperarousal, preventing you from processing the events of the day.
According to Dr. Alex Scott of Keele University, modern society’s difficulty in regulating emotions and processing experiences often leaves individuals unable to positively address their emotions, leading to rumination and anxiety at bedtime.
To combat excessive fatigue and improve sleep quality, Scott recommends three simple strategies:
1. Stop counting sheep
Contrary to popular belief, focusing on falling asleep can actually make it more difficult to do so. Rather than forcing yourself to sleep, Dr. Scott suggests acknowledging that sleep is an automatic process that can’t be rushed. Instead of counting sheep, focus on processing your emotions through activities like journaling.
2. Keep a worry diary
Keeping a worry journal before bed can help you identify and address troubling thoughts that may be contributing to your inability to sleep. By writing down your worries and potential solutions, you can externalize and process these concerns, allowing your mind to relax and prepare for sleep.
3. Set a Bedtime Timer
To create a buffer between daily activities and bedtime, set a bedtime alarm to allow time for relaxation and decompression. Engaging in calming activities like reading or meditation before bed can help ease mental fatigue and promote restful sleep.
About our experts
Professor Matt Jones: A neuroscientist at the University of Bristol specializing in sleep science, memory, and decision-making.
Dr. Alex Scott: A psychology lecturer at Keele University whose research focuses on the role of sleep in mental health.
Is removing carbon dioxide from the atmosphere one of the best weapons against climate change? Climeworks, a Swiss company, believes so, as they have recently unveiled the world’s largest direct carbon capture and storage plant.
The new facility, Mammoth, will be located in Hellisheiði, Iceland, and will be nine times larger than Climeworks’ original plant, Orka. Mammoth’s goal is to extract 36,000 tonnes of carbon dioxide from the atmosphere annually, equivalent to removing approximately 8,600 cars from the road.
Powered by renewable energy, Mammoth captures carbon dioxide from the air and transports it to a facility where it is combined with water and injected deep underground. The carbonated water reacts with porous basalt rocks, transforming them into solid carbonate minerals that securely sequester the carbon underground for thousands of years.
The Mammoth Power Plant aims to have 12 of its 72 heat collection containers installed and fully operational by the end of 2024.
Climeworks co-founders and co-CEOs Christoph Gevaert and Jan Wurzbacher oversee the early stages of construction of the mammoth factory. Photo courtesy of Climeworks
Swiss mechanical engineers and Climeworks founders Christoph Gevaert and Jan Wurzbacher introduced the concept of a direct air capture plant in 2015. Since then, the company has expanded rapidly, with Orka and Mammoth just the beginning of their efforts to reduce atmospheric carbon levels.
Construction of the foundations for the maintenance floor at the Mammoth factory in Hellisheiði, Iceland, December 2022. Photo courtesy of Climeworks
Keeling Curve, a daily measurement from the Scripps Institution of Oceanography, shows an atmospheric concentration of CO2 around 427 ppm, well above pre-industrial levels below 300 ppm.
An aerial view of the Mammoth Climeworks carbon capture plant as it nears its launch in December 2023. Photo: ClimeworksWorkers at the Mammoth factory monitor progress shortly after the start of operations in May 2024. Photo courtesy of ClimeworksA worker stands next to a nearly completed CO2 collection container tower in December 2023. Photo courtesy of Climeworks
Climeworks is developing third-generation direct air capture technology for a large-scale facility in the US, paving the way for additional carbon capture plants worldwide.
Collector containers at Climeworks’ Mammoth Factory in Hellisheiði, Iceland, May 2024. Photo: Climeworks
By expanding with facilities like Orka and Mammoth, Climeworks aims to achieve megatonne-scale carbon removal capacity by 2030 and gigatonne-scale capacity by 2050.
While the impact on atmospheric carbon levels remains uncertain, the technology is expected to play a significant role in shaping the planet’s future over the coming decades.
Rendering of Climeworks’ proposed third-generation carbon capture plant in the United States. Photo courtesy of Climeworks
Music and physics are two disciplines that transcend mere study to become intertwined aspects of human creativity. This hidden harmony between music and physics has been acknowledged by luminaries such as Albert Einstein, who expressed a longing for music had he not pursued physics.
As someone who navigates both fields, I have uncovered deeper connections between them. My journey began in the Bronx, where the worlds of hip hop and science collided in unexpected ways. Later, while studying at Imperial College London, I witnessed the fusion of artistic expression and scientific inquiry in Brian Eno’s studio.
This intersection between art and science inspired me to explore further and led me to write the book “Physics Jazz.” Through this exploration, I delved into the commonalities between music and physics, from improvisation to quantum uncertainty.
My passion for sharing these discoveries prompted the creation of the course “Jazz in Modern Physics” at Brown University, bridging the gap between disciplines and offering students a new way to appreciate the symphony of the universe through mathematics and melody.
Believing in the transformative power of education, I founded the “Sound + Science” after-school program to provide underserved students with an opportunity to explore the fusion of music and physics through hands-on experimentation and collaboration.
This fusion of art and science celebrates human ingenuity and the interconnectedness of the universe. In embracing this harmonious blend, we can unlock the mysteries of the universe and delve into the depths of the human soul.
Our dogs have been our companions for thousands of years. Every wag of a tail, flick of an ear, and furrowed brow speaks volumes if you know how to interpret them.
Despite thinking we know our dogs well, research suggests that dogs are actually better than humans at reading body language. To help us understand dog communication better, we sought advice from experts in animal behavior, such as Dr. Zazie Todd. Learn more about the hidden meaning behind your dog’s behavior, from their nose to their tail, ears to paws.
Understanding Dog Facial Expressions
Humans often rely on facial expressions to understand each other, but can we do the same with dogs? Some dogs have very expressive faces, which can help us interpret their emotions. A relaxed jaw and slightly open mouth can be the equivalent of a “smile” in dogs, while a grinning dog may be signaling aggression. It’s important not to anthropomorphize too much, as dogs may have different expressions than humans.
In some cases, what may seem like a “guilty look” from a dog may actually be their fear of getting scolded. Research has shown that dogs may not fully understand their actions but are responding to the owner’s potential reaction. Eye contact and ear positioning can also reveal a lot about a dog’s feelings and intentions.
Signs of Stress in Dogs
While it’s easy to spot when a dog is happy, signs of anxiety or fear can be harder to detect. Yawning, licking lips, and other subtle cues may indicate stress in dogs. Understanding these signals can help prevent misunderstandings and improve communication between you and your pet.
Interpreting Dog Posture
Dog posture can reveal a lot about their emotions. A low, hunched body may indicate fear, while a playful “play bow” posture signals a desire to engage. Observing your dog’s body language can help you understand their intentions and mood better.
Decoding Tail Wagging
Tail wagging is a common form of communication for dogs. A big, loose wag can indicate happiness, while a stiff, vertical tail may signal stress or aggression. Pay attention to the direction of the wag to better understand your dog’s emotions. Research has shown that the direction of the wag can reflect the dog’s mood.
Understanding Vocalizations
Barking and growling are essential forms of vocal communication for dogs. Different sounds can convey various emotions or intentions. Research has shown that dogs can use growls to express their size and feelings honestly in different situations. Understanding your dog’s vocalizations can help you better respond to their needs.
About Our Expert
Zazie Todd is an animal behavior expert and award-winning author. She founded Pet Psychology in 2012 to explore how science can improve the happiness of cats and dogs. With over 50,000 monthly visitors, Companion Animal Psychology is a valuable resource for pet owners.
In the UK, there are over 11 million people aged 65 and above, a number expected to rise to 13 million, constituting 22% of the population in a decade. This demographic change has drawn attention to often overlooked health issues, particularly in women: osteoporosis and bone fractures.
Globally, over 8.9 million osteoporotic fractures occur annually, equating to one osteoporotic fracture happening every three seconds somewhere in the world.
But why does bone health deteriorate with age? Our bones house specialized cells known as osteoblasts that generate new bone tissue. Conversely, osteoclasts are cells at the other end of the skeletal cycle responsible for dissolving old, damaged bone tissue and replacing it with fresh, healthy tissue.
The balance of activity between these cell types is crucial for bone health. Up to the age of 30, osteoblast activity generally exceeds osteoclast activity, resulting in more bone formation than loss. However, as individuals reach 35, osteoclast activity becomes dominant, leading to a gradual decline in bone quality and density.
Most concerning is the rapid decrease in estrogen production in postmenopausal women, which triggers increased osteoclast activity due to reduced osteoblast numbers and extended osteoclast lifespans. This change is believed to contribute to osteoporosis development.
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When a certain level of bone density loss occurs, osteopenia may develop, leading to extremely low bone density and increased fracture risk, potentially progressing to osteoporosis. This condition is often referred to as “bone thinning,” but it results from changes in bone density, microstructure, and quality that compromise bone strength.
Unfortunately, both osteopenia and osteoporosis are typically asymptomatic until a fracture occurs, making diagnosis incidental. Various risk factors may contribute to the development of these conditions, including smoking, thyroid disease, diabetes, and certain medications like steroids.
Preventive measures for bone health should be initiated early. A balanced, calcium-rich diet is crucial, with dairy products serving as primary sources of calcium. Individuals with restricted dairy intake may need calcium supplements, emphasizing the importance of vitamin D production through sunlight exposure or supplementation.
While calcium and vitamin D are essential for bone health, engaging in bone-straining exercises, especially resistance training, can stimulate osteoblast activity, preventing osteoporosis progression. Exercise not only enhances bone mineralization but also improves muscle strength, balance, and posture, reducing the risk of falls and fractures.
For menopausal women, exercising efficacy in promoting bone mineralization hinges on adequate calcium and vitamin D intake, making supplementation vital. Additionally, various medications are available to treat or slow osteoporosis progression, with estrogen therapies recommended for menopausal women, particularly those with premature ovarian insufficiency.
Education and awareness about bone health can significantly impact prevention and proper management of osteoporosis, especially as societies aged. Addressing these issues is crucial as we navigate the future of an aging population.
A mother manatee (pictured above) swims up to a cave diver in a flooded cave in Quintana Roo, Mexico's Yucatan Peninsula. Klaus ThiemannThey captured amazing photos of these endangered mammals living in unique, unexplored habitats. “Of course I think she's looking at me,” Tyman says. “But in reality, she's probably seeing what's on camera.”
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Carved into the limestone by flowing water, this cave system is thought to be up to 16,000 kilometers long and connects coastal and inland cenotes, freshwater-filled sinkholes created when cave roofs collapse. is. Timan and his fellow divers have been exploring this system (pictured above) to photograph manatees, which, unlike humans, can easily navigate passages.
Although manatees have likely lived in the area for generations, it is estimated that fewer than 250 manatees exist in the Mexican Caribbean, Tiemann said. Timan is concerned that nearby construction projects are endangering aquatic species in the area. A new railway line will further develop this popular tourist destination (pictured above). Construction can impede the flow of water through the system, starving it of oxygen and trapping manatees. Wastewater from surface runoff and sewage systems degrades the water quality of local aquifers.
Although the coastal area is protected as a manatee sanctuary, it does not extend as far inland as the manatees were photographed. So while the discovery of manatees in a relatively pristine cave system is good news, these habitats may not remain pristine for very long.
Its mauve, suction cup-covered arms gently unfold to grab an egg shaped like an elongated ping-pong ball. A jet of water from a siphon next to the octopus's head ensures that the unhatched cubs get enough oxygen.
From a distance, she is surrounded by hundreds of females, living up to her nickname. The pearl octopus (Muusoctopus robotus) resembles a spherical gem that sits on the ocean floor. This is the largest known assemblage of eight-armed molluscs on Earth, numbering approximately 20,000 individuals, and has been witnessed by people all over the world in astonishingly high resolution. “Oceans” episode BBC series Planet Earth III.
This view would have been amazing enough even if it were from shallow water, including tropical coral reefs and kelp forests. But these octopus mothers tend to their eggs in freezing cold and darkness, about 2 miles below the surface. of the deep sea.
“The fact that there is life there is amazing in itself,” says the producer and director. Will Ridgeon They spent two years photographing the octopus, collaborating with scientists and technicians at California's Monterey Bay Aquarium Research Institute (MBARI).
The aptly named pearl octopus rears its eggs in an octopus garden surrounded by flower-like anemones. – Credit: Monterey Bay Aquarium Research Institute
The octopus farm, as the site is now known, is located on a hill in the eastern Pacific Ocean, 160 km (100 miles) southwest of Monterey Bay, near a giant underwater mountain called Davidson Seamount. This place was discovered during his expedition in 2018. live streamed over the internet.
It was the first time I had ever seen so many creatures in one place, let alone in the deep sea. (Octopuses are notoriously solitary animals and tend to be cannibalistic when kept together in captivity.) ).
Ridgeon watched the livestream of the discovery and immediately knew it was a story to be filmed in a new BBC series.he teamed up with Dr. Jim Barrya senior scientist at MBARI, began regularly visiting octopus farms in 2019 to learn more about why so many octopuses congregate in certain areas.
“The question is, why is it there?” Barry says. Barry and his colleagues gathered specialized tools and began a series of detailed studies. They created a photomosaic of his 2.5-hectare (about 27,000 square feet2) portion of the property and stitched together high-resolution images that allowed them to count the octopus population.
They also installed time-lapse cameras on the ocean floor, taking close-up photos every 20 minutes at a time for months to show what the octopuses were doing, and Barry's team gradually expanded the octopus park's largest began to unravel some of the mysteries.
Octopus farm location. – Image credit: MBARI
work remotely
Ridgeon took part in an expedition to an octopus farm early on. Initially, filming took place during lockdown, so he participated via live video link from his bedroom in Bristol, England (with occasional interruptions from his five-year-old daughter).
Once COVID-19 restrictions allowed, Ridgeon joined Barry and his team aboard MBARI's vessel, the research vessel Western Flyer. However, no one visited the octopus farm directly. All surveys and filming were done using a car-sized remotely operated vehicle (ROV) equipped with a camera and a robotic arm.
The dive began around 6 a.m., and the ROV was lowered into the ocean through a hole in the Western Flyer's hull called the moonpool. “It's very James Bond,” Ridgeon says. The descent to the octopus garden can take up to two hours, and the ROV will remain there all day.
The pilot controls the ROV via a cable connected to a control room on the ship on the ground, and everyone watches the video feed to see what's happening below.
Researchers survey the octopus farm from the Western Flyer's ROV control room. – Credit: Monterey Bay Aquarium Research Institute
“You forget you're looking at a screen,” Ridgeon says. “You think you're there,” says the MBARI engineer. He worked with the BBC to find the ideal camera setup to photograph the octopus garden. It was not possible to use footage from a camera fixed to the ROV due to too much vibration.
“I think the BBC will do a little bit about that.” [shivering]“But not as much as we had,” Barry says. ROVs “shudder” not because of the cold temperatures of the deep ocean, but because the thrusters must be activated constantly to ensure they stay close to the ocean floor (ROVs are positively buoyant, so if they fail they will ). .
To get around this, Barry and Ridgeon used a separate 4K camera mounted on a specially designed stand that could be placed on the ocean floor.
“I think that's the secret behind the images,” Ridgeon says. Unlike the ROV cameras used by scientists, which can only reach within a few meters of objects on the ocean floor, the 4K camera's focal length of about 20 centimeters (7 to 8 inches) allows it to precisely navigate between octopuses. can be captured.
But it was difficult to use. It took up to 40 minutes to get into position, and the team had to hope it wouldn't fall over and the action would happen in front of it. Ridgeon operated the camera from the ship using his PlayStation controller, which MBARI engineers adapted for the job. “At first it's like trying to film him with his hands tied behind his back,” Ridgeon said.
Another challenge with deep-sea photography is light. “Put the light as far away from the camera as possible, ideally around the sides so it’s three-quarters backlit. [the scene]That way, there are no reflections from any debris in the water,” explains Ridgeon.
The octopus garden provides insight into the life and reproduction of molluscs. – Credit: Monterey Bay Aquarium Research Institute
Those “fragments” are marine snow. These are organic particles that constantly rain down from the shallow ocean above. Marine snow is made up of dead plankton and their feces stuck together by microbial glue, and is the main food source for deep-sea animals. However, it makes filming difficult as the movie can look like it was shot in a snowstorm.
To see through the snowstorm and achieve the desired three-quarters backlighting effect, the MBARI team built a lighting system that the ROV could hold on its side, away from the camera. “That's how we got some really great shots,” Barry says.
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Accelerate development
As Barry's investigation and BBC filming progressed, the team made some surprising discoveries. First, no medium-sized octopus ever visited this location, and there were no signs of it feeding. It was only a fully grown adult octopus.
They were here to breed and for no other purpose. It may be called an octopus farm, but this place is definitely an octopus farm. The researchers also collected evidence that incubating females use on-site hot springs to speed up the development of their offspring.
For octopuses, there is a strong relationship between temperature and hatching time. The colder it is, the longer it will take and the more dangerous it will be. This is because there are scavengers that prey on unborn, unprotected octopus eggs.
Temperature studies have shown that the seawater surrounding each octopus nest can reach 10°C (50°F), much warmer than the 1.6°C (34°F) seawater just a few meters away. It was shown. By observing specific octopuses (identifiable by scratch and scar patterns) in the field, Barry and his colleagues determined that their eggs take an average of 1.8 years to hatch.
During this time, the female does not move but is constantly fighting off predators and guarding her approximately 60 eggs. “Once you plant an egg on a rock, that's it. You can't leave that spot,” Barry says. At just under two years, it's not the longest parenting period for an octopus. This record is given to another species that other MBARI scientists discovered nearby, Graneledon boreopafica, clinging to the sides of Monterey She Canyon 1.4 km (just under a mile) deep. I did.
Researchers watched one female incubate her eggs for four and a half years, longer than any other recorded animal. However, she was growing her eggs in water that was much warmer than the octopus park's ambient temperature of 1.6 degrees Celsius. Without the hot springs, the eggs in the octopus garden would take more than 10 years to hatch. When this site was discovered, biologists were surprised to find octopuses nesting there.
But geologists were fascinated by warm water seeping through the ocean floor, something they had never seen before. These springs are much cooler than the red-hot hydrothermal vents that form at the edges of tectonic plates where new molten ocean floors are created.
Although the enormous pressure will not cause the water to boil, the temperature around the vent can reach hundreds of degrees. These were first discovered in his 1970s, and plumes of hydrothermal water rise up to hundreds of meters in the water column, making them relatively easy to detect with temperature probes. In contrast, hot springs are more difficult to find because they form away from these tectonically active regions and have much cooler temperatures.
But geologists believe they could exist in the thousands and are highly stable, likely remaining in the same location for hundreds or even thousands of years. Therefore, biologists believe that more octopus farms may be established around these springs.
birth and death
In the final scene of the “Octopus Garden” episode Planet Earth III, a cluster of tiny sucker-like arms appears beneath the brooding female, then a wobbling young octopus swims away into the darkness like a mini-umbrella. More chicks follow and begin life at sea.
No one knows where they're going…yet. “That's what I want to understand next,” Barry says. The hatchlings are large for a newborn octopus, at about 6 cm (2 inches), so they have the best chance of survival. But as anyone who has seen the Octopus documentary knows, this comes at a heavy cost to mothers.
“These mothers are trying so hard to protect their bloodlines, and they're just dying out,” Barry says. Her father died a few years ago, shortly after mating. On the screen, we see the women's eyes cloudy and their bodies wrinkled. Ridgeon saw what happened next, but she decided it was not suitable for an evening television audience.
Dead octopuses are quickly attacked by scavengers such as fish, snails, sea anemones, and shrimp. For Barry, this is another important part of his discovery at the octopus farm. The nesting season is asynchronous, with octopuses hatching and mothers dying throughout the year. Approximately 9 each day. The female octopus' body nourishes the rest of the ecosystem and helps supplement the energy input from marine snow by 72 percent.
Graneledon boreopafica (a species of octopus that incubates eggs in cold water) has a 4.5 year rearing period, which holds the record for the longest rearing period of any animal. – Credit: Alamy
“This is clearly a huge food subsidy for the local ecosystem,” Barry says. “That wouldn't happen in shallow water,” he added. Because there is a lot of food around. But in the more barren depths, nothing goes to waste.
The BBC has finished filming at the octopus farm, but Barry's research continues. One of the things he wants to know is the age of the sea anemone. These are giant orange flower-like animals that make the octopus garden look like a real garden.
Barry studies sea anemones, which live for decades in shallow coastal waters, and finds that deep-sea species can survive for centuries, in contrast to octopuses, which are relatively short-lived. That's what I'm thinking.
“They're like sentinels that just sit there while the octopus cycles,” he says. There are many more questions Barry would like to answer. “Are octopuses confined to this breeding form in warm areas, or are they able to breed elsewhere with cooler ambient temperatures? Is there fidelity to specific nest sites? ?Will they return to their place of birth?'' he asks.
No one knows how far the octopuses travel before they reach the garden or how they found them, but Barry said he was surprised by the large number of dead and dying octopuses floating around. I suspect I smelled it. “We'll definitely be back,” he says.
Groundbreaking research led by Professor Motoki Shiga has unraveled the complex atomic structure of glass, revealing its unique patterns and anisotropy. This research paves the way for advanced exploration of glass materials using AI and machine learning techniques.Credit: Motoki Shiga
Glass is an essential material in our daily life and serves a variety of purposes, such as insulating our homes and forming the screens of our computers and smartphones. However, its widespread historical use stands in contrast to the scientific mystery posed by its disordered atomic structure. This puzzling arrangement of atoms complicates efforts to fully understand and manipulate the structural properties of glasses. Therefore, designing effective functional materials from glass remains a difficult challenge for scientists.
Advances in glass research
To further elucidate the structural regularities hidden in glassy materials, the research group focused on the ring shape of the chemically bonded glass network. A research group including Professor Motoki Shiga of Tohoku University’s unprecedented scale data analysis center has developed a new method to quantify the three-dimensional structure of the ring and the symmetry of the structure, “roundness” and “roughness.”
Spatial atomic density around rings of silica crystal (left) and glass (right). Blue and red regions indicate areas with high density of silicon and oxygen atoms, respectively.Credit: Motoki Shiga et al.
Breakthroughs and future directions
“Structural units and structural order beyond chemical bonds have long been inferred through experimental observations, but until now scientists have avoided identifying them,” Professor Shiga says. “Furthermore, our successful analysis contributes to the understanding of phase transitions such as vitrification and crystallization in materials and provides the necessary mathematical explanations to control the structure and material properties of materials.”
Looking to the future, Shiga and his colleagues plan to use these techniques to devise procedures for exploring glass materials, procedures based on data-driven approaches such as: machine learning And AI.
Reference: “Ring-derived anisotropy of local structural order in amorphous and crystalline silicon dioxide” by Motoki Shiga, Akihiko Hirata, Yohei Onodera, and Hirokazu Masai, November 3, 2023. Communication materials. DOI: 10.1038/s43246-023-00416-w
byInstitute of Atmospheric Physics, Chinese Academy of SciencesDecember 16, 2023
A groundbreaking study investigated the complex relationship between Earth’s surface temperature and emitted longwave radiation, revealing deviations from the expected quaternary pattern. This research improves our understanding of climate sensitivity and the factors that influence it, such as greenhouse gases and atmospheric dynamics. Credit: SciTechDaily.com
Climate science research has revealed new insights into the relationship between surface temperature and emitted longwave radiation, challenging traditional models and improving our understanding of Earth’s climate sensitivity.
Want to know what causes Earth’s climate sensitivity? Recent research shows Advances in atmospheric science. We investigate a complex relationship that transforms the relationship between surface temperature and outgoing longwave radiation (OLR) from fourth-order to sublinear. Led by Dr. Jie Sun florida state university this study elucidates the hidden mechanisms that shape Earth’s climate and provides new insights into why the relationship between temperature and OLR deviates from the fourth-order pattern described by the Stefan-Boltzmann law. Masu.
Stefan-Boltzmann law and climate dynamics
What is the Stefan-Boltzmann law? Atmospheric greenhouse gases create a contrast between surface heat release and OLR, which is related to the fourth power of surface temperature.
Professor Hu Xiaoming of Sun Yat-sen University, corresponding author of the study, explained: This allows the relationship between surface temperature and OLR to follow a quartic pattern, since the radiation-emitting layer is lowered. ”
Diagram showing two main processes: sublinear surface temperature and outgoing longwave radiation (OLR). Left: Increased meridional surface temperature gradient due to the greenhouse effect of water vapor. Right: Poleward energy transport reroutes part of the OLR from warmer to colder regions. Credit: Ming Cai and Xiaoming Hu
Factors affecting surface temperature and OLR
This study reveals how various factors influence surface temperature and OLR. The water vapor greenhouse effect acts as a magnifying glass, amplifying temperature differences across the Earth’s surface without changing the latitudinal variation of the OLR. This suppresses the nonlinearity between OLR and surface temperature.
Polar energy transport, on the other hand, acts as an equalizer to harmonize temperature differences across different regions of the Earth. One of the by-products of this global heat redistribution is the rerouting of OLR from warmer to colder regions, which acts to reduce the differences in OLR between different regions. This further suppresses nonlinearities.
“Understanding these complex climate interactions is like deciphering a puzzle. Each piece brings us closer to deciphering the complexity of Earth’s climate,” said Ming Kai, a professor at Florida State University. Masu.”
By uncovering these relationships, scientists are learning more about Earth’s climate and how its complex components regulate overall climate sensitivity, i.e., not just the rate of energy output, but also where the output occurs to make significant progress in understanding.
Reference: “Sublinear relationship between planetary outward longwave radiation and surface temperature in a gray atmosphere radiative-convective transport climate model” Jie Sun, Michael Secor, Ming Cai, Xiaoming Hu, November 25, 2023. Advances in atmospheric science. DOI: 10.1007/s00376-023-2386-1
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