Environment
Microplastic storms are coming
Published
10 months agoon
Microplastic storms are coming. When Hurricane Larry made landfall two years ago, more than 100,000 microplastics were dumped per square meter per day. This is another indication that the environment is full of plastic.
Microplastic storms are coming
As Hurricane Larry curved northward in the Atlantic Ocean in 2021 and the East Coast of the United States was spared, a special tool was waiting on the coast of Newfoundland, according to Wired.
Because hurricanes feed on warm ocean water, scientists wondered if such a storm could pick up microplastics from the sea surface and deposit them as they make landfall. “Larry” was literally a perfect storm, and since it hadn’t touched land before reaching the island, anything that fell from it would have come from water or air, contrary to what one would expect from major cities. in which large amounts of microplastics are found.
As Larry passed through Newfoundland, the instrument on board picked up what was falling from the sky, including rain and pieces of microplastics smaller than five millimeters.
In an article recently published in the journal Communications Earth and Environment, researchers wrote that at the peak of its activity, Hurricane Larry dumped more than 100,000 microplastics per square meter on the ground every day. With this in mind, hurricanes should be added to the growing list of ways by which microplastic particles not only penetrate every corner of the environment, but are also easily transported between land, sea, and air.
As humanity in general produces exponentially more plastic, the environment becomes exponentially more polluted with microplastics. The prevailing belief was that microplastics end up in the ocean and stay there. For example, washing polyester clothes releases millions of microfibers in each wash, which are washed into the sea with the sewage. However recent research has shown that the seas actually bring particles into the atmosphere to return to land. This happens both when waves form and when bubbles rise to the surface of the water.
The device, located in a Newfoundland compound, was very simple, consisting of a glass cylinder holding a small amount of ultrapure water, attached to the ground with sturdy sticks. Every six hours, during and after the storm, researchers would come in and dump water to collect every drop that fell in Newfoundland, with or without rain.
Read More: Climate changes will continue for 50 thousand years
“This is a place that experiences a lot of extreme weather events,” said Anna Ryan, a geoscientist at Dalhousie University and lead author of the paper. Also, it is relatively remote and has a very low population density. So there’s not a bunch of microplastic sources nearby.
The group found that even before and after Hurricane Larry, tens of thousands of microplastics per square meter were dumped on the ground every day. But when the storm hit, this number increased to 113,000. “We found a lot of microplastics that were deposited at the height of the storm, and the overall sediment was relatively high compared to previous studies,” Ryan says. He says that these studies have been done under normal conditions, but also in more remote locations.
The researchers also used a method called return path modeling, which basically simulates where the air entering the device has been before. This work confirms that Hurricane Larry picked up microplastics from the sea, carried them into the air, and deposited them in Newfoundland.
In fact, previous research has estimated that anywhere from 12 to 21 million tons of microplastics are circulating just 200 meters above the Atlantic Ocean. The Newfoundland study notes that Hurricane Larry passed over a polluted area in the North Atlantic, where currents piled up floating plastic.
These new figures from Newfoundland are probably underestimated. Searching for the smallest particles of plastic is difficult and expensive. The research looked at particles as small as 1.2 microns (1.2 millionths of a meter), but there are likely plastic particles much smaller than what falls into the device.
Researchers can also determine what type of plastic fell from the sky. “We didn’t see a lot of a particular polymer, and there’s real variation,” Ryan says.
Microplastic pollution comes from many sources, including clothes, car tires, paint chips, broken bottles, and bags, all of which mix into a multi-polymer soup in the ocean. This happens both in the oceans and in the sky. In remote areas of the American West, microplastic sampling tools like the one in Newfoundland collect large numbers of particles that fall as plastic rain. Microplastics are not only airborne but have become an essential component of the Earth’s atmosphere.
So microplastics don’t just end up in the sea and stay there, they move through the atmosphere and back to land and are picked up again by the winds and out to sea. “It’s becoming clear that ocean-atmosphere exchange is a very real thing,” Allen says. The numbers in this article are staggering. The microplastics arrive in Newfoundland just at the time of year when all the living things in the ponds are trying to fatten up and reproduce for the winter.
Because microplastics move so easily on winds and ocean currents, places that were once pristine are no longer the same as before. Scientists are trying to find out how these particles affect the organisms in these places.
For example, microplastics from Europe have contaminated the Arctic, contaminating the algae Melosira arctica that grows on the underside of sea ice. Algae are the mainstay of the Arctic food chain, meaning that all kinds of organisms consume them, along with the microplastics that accumulate in them.
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Environment
Do animals have an understanding of the concept of death?
Published
3 weeks agoon
16/09/2024butPreposition, except (for), excluding.
Preposition: outside of.
Adverb: merely, only, just, no more than
Adverb: though, however.
Conjunction: except that (introducing a subordinate clause which qualifies a negative statement); also, with omission of the subject of the subordinate clause, acting as a negative relative, “except one that”, “except such that”.
Conjunction: Without it also being the case that; unless that (introducing a necessary concomitant).
Conjunction: Except with; unless with; without.
Conjunction: Only; solely; merely.
Conjunction: until.
Noun: An instance of using the word “but”; an objection or caveat.
Noun: The outer room of a small two-room cottage.
Noun: A limit; a boundary.
Noun: The end; especially the larger or thicker end, or the blunt, in distinction from the sharp, end; the butt.
Verb: Use the word “but”.
Do animals have an understanding of the concept of death?
A chimpanzee named Muni had just been brought to a zoo in the Netherlands when she lost her child. The zookeepers did not know that she was pregnant. Zoe Goldsborough, a student who spent months studying and recording social interaction among chimpanzees, did not know this either.
One cold winter morning, Goldsborough saw Mooney sitting alone on a tree trunk in the center of the compound, holding something in her arms. It wasn’t unusual for Muni to be alone, as she had trouble bonding with the zoo’s 14 other chimpanzees. But when Goldsborough approached him, he knew something was wrong. Muni was holding a baby in her arms and the baby was not moving.
Goldsborough rushed to the room where the zookeepers were preparing food for the chimpanzees and told them what he had seen. At first, they didn’t believe Goldsboro’s words and said that Mooney was probably playing some tricks. But after the guards saw the baby with their own eyes, they entered the compound and tried to take it from Muni. Mooney wouldn’t let go and the guards decided to wait for a while and then try again.
At this moment, another female chimpanzee named Toshi was roaming around Muni. Toshi was one of Goldsboro’s favorite chimps. A few years ago, he became world-famous for a planned attack on a drone that was filming chimpanzees. Toshi had experienced a miscarriage long before. Maybe for Toshi, seeing Muni and her baby was a reminder of that old memory or similar feelings. Over the next two days, she stayed close to Mooney, while Mooney still held her baby’s body in her arms.
Finally, in a struggle with the guards, the body falls from Mooney’s hands, Toshi takes it and refuses to give it back. Muni was very angry. The guards put Toshi in a separate room and Muni angrily bangs on the door. Goldsborough was not sure about the cause of this behavior. Mooney seemed to be under the influence of intense maternal attachment, and Toshi was perhaps reacting to a repetition of feelings she had experienced in the past.
It is unclear whether any of the chimps actually understood what had happened to the child. Maybe they mistakenly thought the child would come back to life. Even though chimpanzees are our closest relatives in the tree of life and one of the most well-studied animals, we still cannot interpret their behavior with certainty.
An old question
Last June, more than 20 scientists gathered at Kyoto University in Japan for the largest-ever conference on comparative morphology (the study of animals’ experience of death). Although this scientific field is small, its works date back to the time of Aristotle. In 350 BC, Aristotle wrote about a pair of dolphins he saw coming to the surface of the Aegean Sea supporting a dead baby, “out of compassion trying to prevent it from being eaten.”
Much of the scientific literature on comparative mortology contains similar stories. Some of them are short, like Aristotle’s story, and some, like the story of Muni and her baby, published in 2019 in the journal Primates, contain much more social detail.
Scientists want to find out what emotions animals experience when they lose loved ones. They are trying to understand if animals fear death like we do. However, there are many obstacles in the way of studying this issue. Researchers cannot interview animals. While hormonal changes can be observed (cortisol levels rise in bereaved baboons), these changes may be caused by other stressors.
So far, the best comparative mortality data have come from observing animals in the wild or captive animals in zoos, but even here there are problems.
Species with more interesting responses to death (such as nonhuman primates, whales, and elephants) have long lifespans and low mortality rates in their societies. Obtaining systematic data on their response to death usually requires years or even decades of study.
Alecia Carter, an evolutionary anthropologist at University College London, says she has identified a group of about 1,000 rhesus monkeys on Cayo Santiago Island, off Puerto Rico, that would be ideal for such studies. Rhesus monkeys are very social and usually live 15 to 20 years, which is enough time to establish deep relationships; But it is not so long that deaths among them are very rare.
Understanding of death
Humans have spent months in hot, humid forests or zoo enclosures and overcome difficult obstacles to study animals’ reactions to death. Anyway, we humans have been sensitive to death, if not very much, at least since the beginning of written history. The oldest work of epic literature tells the story of King Gilgamesh and his struggle with death. “Death is sitting in my bedroom and everywhere I turn, I feel death,” he says, searching for a plant that promises immortality.
Between the ages of 4 and 7, human children learn that death is an irreversible situation
Human cultures have devised symbol-laden rituals for the pre-death and post-death periods. For more than 10,000 years, we have buried our lost children in the ground and planted flowers around them. We are the species of faithful guardians of tombs, builders of pyramids, and inventors of various funeral ceremonies. We have envisioned the afterlife both in heaven above and here on earth on the wheel of reincarnation. Our philosophers have also dealt with the issue of death in a very subtle way, and their definitions of death currently exceed 10,000 words.
We humans have even extended our finitude to the universe itself. Scientists tell us that trillions of years from now, after the last galaxies have collapsed and the black holes have vaporized bit by bit, the entire universe will be destroyed.
As humans, our complex ideas about death are not passed on to future generations through our genes. They are formed in people’s minds over time and gradually accumulate in our culture. Human children usually learn between the ages of 4 and 7 that death is not temporary or irreversible, and if they lose a family member or pet, they may understand this a little earlier.
In a new book, ” Pretending to Die: How Animals Understand Death, ” Spanish philosopher Susana Monceau argues that many other animals probably understand the same simple concept of death (i.e., loss of agency). Of course, without access to their minds, we cannot be sure about this.
Mammals, fish, birds, reptiles, and insects are all aware of agency in the natural world. They monitor their environments for movement and differentiate between stationary objects and things that move in some way to achieve their goal. Some of them behave in ways that show they understand that other animals may lose this ability forever. But we don’t know whether these behaviors are caused by the understanding of death or simply by instinct.
Pay attention to the termites. At the June meeting in Kyoto, an entomologist from Louisiana State University presented a paper on carcass management methods in eastern groundhogs. More than a million of these insects may congregate in nested subterranean colonies tens of meters wide. When worker ants encounter a dead mate in one of the colony’s tunnels, they react differently depending on the condition of the corpse. When the corpse is fresh, they eat it; But they bury old and rotten bodies. Other social insects that live in similar environments behave in similar ways. Bees remove dead bodies from the hive, but these behaviors do not appear to be caused by an understanding of the concept of death.
Termite corpses produce oleic acid, which apparently stimulates burial behavior. When the American biologist Edward Wilson smeared a live ant with this substance, the members of the colony immediately assumed him dead and took him out of the colony, even as he moved his legs in protest.
Death is a complicated concept for us
Chimpanzees are not like termites. Their large and complex brains are better able to understand concepts such as death, and there is evidence that they experience an emotion similar to grief.
Several species of non-human primates will gather around a recently deceased member of the community and in many cases gently touch the lifeless body. The population usually disperses slowly and regularly: those who were closest to the dead animal stay longer. Jane Goodall observed that an eight-year-old chimpanzee stayed with its mother’s corpse so long that it died.
Other mammals also usually gather around their dead. While doing this, the giraffes shake their necks at the scavengers to keep them away. In India, the bodies of five young elephants were found covered in twigs and leaves, leading some scientists to believe they were buried by other members of the group.
Andre Gonsalvez, a comparative morologist at Kyoto University, cautions against paying too much attention to this story. According to him, the elephants were found in the pit; This means that they could have fallen inside them, and leaves and dirt could have accidentally piled up on the bodies as their families tried to pull them out.
Monceau reminds his readers that animals live in a violent and bloody world where predators attack in the dark of night or appear from unseen heights with sharp claws.
The violent environment of animal life provides rich conditions for understanding death. Monceau gives the example of a young stag watching a battle between two older stags for power. After their antlers clash several times and the weaker rival fails to rise, the young deer begins to understand the basics of death. If he does not remember this lesson, he will probably have many opportunities to learn it again.
Even if chimpanzees understand the concept of death, it is not as complicated for them as it is for us
Gonsalves isn’t sure if animals learn the meaning of death in their communities and says many animals eat other animals while they’re still alive. It is not clear if they are trying to cause their death or if they perceive it as a separate state of existence. They might just be trying to get a moving food source into their mouths, like frogs, who stick out their sticky tongues at anything that looks like a moth simply as an instinctive reaction.
Among chimpanzees, acts of brutal violence, including murder, indicate a deeper understanding of death. Chimpanzees, like wolves and lions (and humans), sometimes cooperate to kill rival group members. These attacks may be planned in advance. Two or three males enter an area occupied by another group. They move quickly and cautiously, and even when they pass food sources, they don’t stop to eat. They choose single targets and coordinate their attacks so that they don’t get hurt themselves. In some cases, the attacking chimpanzees will continue their attacks even after the victim has surrendered, only stopping when the victim stops breathing.
Obviously, even if chimpanzees understand the concept of death, it is not as complex for them as it is for us. Humans know what death is and they know that one day it will come to them.
James Anderson, professor emeritus of Kyoto University and known as the father of comparative mortology, says chimpanzees feel about their own death in a different way than we humans do. Despite thousands of hours of observation, he says, no one has ever seen a chimpanzee attempt suicide. According to Anderson, only an animal that knows it can die tries to bring about its own death. He says that the lack of reliable reports of suicidal behavior in chimpanzees or any other animal suggests that the existential burden of death is uniquely ours.
Of course, Anderson, as well as other scientists specializing in the field of comparative mortality, still cannot provide the final answer. They can tell us that chimpanzees understand death better than termites, but the rest is unknown and may never be revealed. We can only hope that as we continue to study chimpanzees, we will see new behaviors from them that will reveal more of their inner world.
The story of Muni and her baby may be one of these cases. After the zookeepers left Toshi alone, they decided to calm things down. They kept him away from others until the next day. Meanwhile, everything had changed for Mooney.
Muni used to have trouble interacting with other chimps and used to pull the hair of other female chimps tightly during grooming. He often sat too close to them and stared at them inappropriately. The day Toshi returned to the group, Mooney was surrounded by other chimpanzees. When he saw Toshi, he quickly got up and slapped him.
Toshi did not react, and over the next 30 days, she and the other chimps interacted more with Moony. No other chimpanzee experienced such an increase in attention, and almost all chimpanzees participated in this display of attention. They hugged Moony and petted her more, but they didn’t share the attention equally. Some took care of Muni more than others and Toshi took care of him most of all. It seemed that an important topic had been exchanged between these two chimpanzees. A few months later, things in the compound were largely back to normal. Muni was no longer being petted and the males started harassing her again. But Toshi and Muni often sat together and this close relationship continues to this day.
Noun: A mastodon.
Noun: Something very large of its kind.
Noun: A kind of large donkey.
Adjective: Comparable to a mammoth in its size; very large, huge, gigantic.
Noun: Any species of the extinct genus , of large, usually hairy, elephant-like mammals with long curved tusks and an inclined back, which became extinct with the last retreat of ice age glaciers during the late Pleistocene period, and are known from fossils, frozen carcasses, and Paleolithic cave paintings found in North America and Eurasia.
Noun: A mastodon.
Noun: Something very large of its kind.
Noun: A kind of large donkey.
Adjective: Comparable to a mammoth in its size; very large, huge, gigantic.
Mammoth and dodo return to nature: will de-extinction save the environment?
Summary of the article:
- In 2003, scientists were able to bring an extinct species back to life for the first time. The experiment resulted in the successful cloning of a Pyrenean ibex, but the clone died minutes after birth. The project ultimately failed, but this achievement became the foundation of a new field called “de-extinction”, which has made significant progress in the last two decades.
- Companies such as Classel Biosciences are advancing projects to recover iconic extinct species such as the woolly mammoth, the dodo, and the Tasmanian wolf. The aim of such projects is to increase biodiversity and restore the vital roles of these species in the environment. However, some experts are skeptical about the possible consequences of species recovery.
- The most important challenges include genetic limitations, the possibility of disease in restored species, and unforeseen effects on natural ecosystems. Critics say that it is better to invest in the protection of existing and endangered species.
- In contrast, proponents of de-extinction believe that such new technologies can also lead to the conservation of existing species and scientific innovation. But the question remains, will the de-extinction of extinct species be an effective solution to the environmental crises of today?
In 2003, scientists managed to bring an extinct creature back to this world for about seven minutes. The restored species was the Pyrenean ibex ( Capra pyrenaica pyrenaica ) and the last known member of the subspecies was a female named Celia. Celia had died three years before recovery.
Before Celia’s death, scientists took a DNA sample from her ear and injected her genetic material into an egg with the nucleus removed from a domestic goat. The result of this effort was the birth of a clone. The born clone became the first and only creature to return from extinction but died soon after his birth due to a lung defect.
Although the efforts of scientists to create a healthy animal were not successful in the end, it became the foundation of the science of ” de-extinction “, which has experienced a lot of progress in the last two decades. Technology no longer stands in the way of reviving recently extinct species and, in many cases, provides access to enough DNA to create efficient genomes and clones. The question is not whether we can restore lost species, but whether we need to.
The disastrous results of recovering extinct species should not be ignored
Some companies have not waited to answer such questions. For example, Classel Biosciences, a biotechnology and genetic engineering company based in Texas, plans to revive three iconic extinct species: the dodo ( Raphus cucullatus ), the Tasmanian wolf or Tasmanian tiger ( Thylacinus cynocephalus ), and the woolly mammoth ( Mammuthus primigenius ). According to Classel’s website, the ultimate goal of de-extinction efforts for such species is to “enrich biodiversity, restore vital ecological roles, and strengthen ecosystems’ resilience.”
However, according to some experts, the disastrous results of recovering extinct species cannot be ignored. Oswald Schmitz, a professor of population and community ecology at Yale University, told LiveScience: “Our pride as humans makes us think we have the ability to control our technology. But I’m not so sure.”
Even at best, environmentalists face skepticism; Is reviving organisms that have been extinct for centuries or thousands of years as beneficial as preserving those that are still alive? “What’s gone is gone,” says Schmitz.
The last Dodo died out in the 1600s. But Klaasel is planning to bring the flightless bird back and reintroduce it to the island of Mauritius.
Recovery of extinct species, is closer than we imagine
Ben Lam, co-founder and CEO of Classel, says recent advances have brought scientists closer to recovering extinct species than people realize. Referring to other de-extinction projects of the Klaasel company, he added: “The company plans to produce the first mammoth-like calves by 2028, and it is very likely that we will see the recovery of another species before then.”
Woolly mammoths lived in the Arctic between 300,000 and 10,000 years ago. To produce mammoth calves, Klassel scientists will first identify the genes encoding the woolly mammoth’s iconic physical characteristics, such as woolly hair, curved tusks, fat deposits and a dome-shaped skull. Then, they will insert these genes into the genome of Asian elephants ( Elephas maximus ), which are genetically more similar to mammoths than other species.
The first mammoth-like calves will be produced by 2028
Love Dalen, a paleontologist and professor of evolutionary genomics at Stockholm University, says that de-extinction can have many different meanings, and our ability to do so depends on how we define it. De-extinction, which means “creating a hybrid species that resembles an extinct species by replacing a limited number of key genes,” is only possible if the DNA of the extinct species is available, adds Dahlen, who is on Klaasel’s advisory board. For example, dinosaur DNA doesn’t exist, so making Jurassic Park is just a dream right now.
Creating an animal that is genetically identical to an extinct species is more complicated and depends on the species. Recovery is likely to be possible for recently extinct species for which higher-quality DNA samples are available, such as Celia, Dahlen says. But this does not apply to mammoths.
Dahlen and his colleagues are close to sequencing the entire woolly mammoth genome, but a few regions of the DNA, such as some strands of the repetitive code, remain challenging.
So far, Klaasel has obtained more than 60 incomplete woolly mammoth genomes, which he will use to edit elephant genomes in the lab. Once the scientists have the final DNA sequence, Lam says, they will place the elephant-mammoth hybrid embryo in the womb of an Asian or African elephant ( Loxodonta ).
Classel also has plans to restore the Tasmanian dodo and wolf. “For Project Dodo, we have a genome that is almost complete,” says Lam. “But for Tasmania, which became extinct in the last century, we had much better genetic data from the beginning.”
Klassel plans to transplant the genetic material to domestic chickens ( Gallus domesticus ) to restore the dodo and to small mouse-like marsupials called Sminthopsis crassicaudata to restore the Tasmanian wolf.
Using DNA extracted from the tusks and skin of woolly mammoths preserved in the frozen soil of the Arctic, scientists succeeded in reconstructing the genome of the woolly mammoth.
Filling the empty space of ecosystems
Ronald Gaudry, an ecologist and director of the Tauros Foundation, an offshoot of the Restoring Europe Wilderness project, which is looking for a replacement for the extinct ago ( Bos primigenius ), says de-extinction aims to fill ecological niches left empty since the original species disappeared. . Niagaos were wild ancestors of domestic cattle ( Bos taurus ) that once lived in North Africa, Asia, and almost all of Europe. They probably played a vital role in maintaining the animal and plant biodiversity of ecosystems by grazing and trampling the soil.
Gaudry and his colleagues are now restoring the Niagaos through a method called reintroduction. This practice does not require genetic engineering. Niagaos were exterminated by humans in 1627, but their DNA is still present in the ancient cattle breeds of southern Europe. By selecting and breeding cows with physical, behavioral, and genetic characteristics similar to Niagaos, ecologists are moving towards the revival of this extinct species. “In every generation, we see rapid and dramatic improvements,” Gaudry says.
The Pleistocene era was the heyday of woolly mammoths. They maintained arctic grasslands by trampling snow, preventing the growth of trees and shrubs, and dispersing nutrients over long distances through feces. Without mammoths and other giant herbivores that are now extinct, such as the Mammoth Steppe, the area has become a waterlogged landscape of tundra, bogs, scrub, and forests. Research shows that the new landscape stores less carbon than grasslands.
Permafrost also melts faster, releasing large amounts of carbon into the atmosphere. Some scientists suggest that reintroducing herbivores to the Arctic will help restore ecosystems, increase carbon storage capacity, and mitigate climate change.
Bringing the giants back to the North helps to reduce climate change
The dodo was one of the largest land animals in the ecosystem of the island of Mauritius. The evidence indicates that beetles spread the seeds of plants and as a result, they have affected the growth of vegetation in the area; However, some experts are skeptical about the role of birds in ecosystem formation. Klaasel’s dodo recovery plans will rid Mauritius of invasive species so the birds can thrive, says Lam. The company argues that dodo recovery will benefit other species as well, as a “halo effect”. The company plans to partner with the Mauritius government in collaboration with the Mauritius Wildlife Foundation.
Also, according to the TIGRR laboratory of the University of Melbourne, which is conducting research in the field of de-extinction, the Tasmanian tiger was the only predator at the top of the marsupial pyramid on the island of Tasmania. Thus, the existence of this species is very important for maintaining predator-prey relationships and, as a result, for stabilizing the ecosystem.
The Obsonor Basin is a watershed in Mongolia and the Republic of Tuva (in Russia), also known as Lake Yus. This basin is one of the closest ecosystems today to a suitable habitat for the Steppe Mammoth. Scientists say that the recovery of mammoths will restore this lost ecosystem in the Arctic.
Increase scalability
However the de-extinct species can fulfill their ecological role properly only if they survive in nature and the population grows sufficiently. Gaudry says that achieving this in the recovery of mammoths is a huge and outstanding task.
Researchers recently estimated that the vast area of Alaska’s North Slope could be a good host for 48,000 woolly mammoths.
Vincent Lynch , an evolutionary biologist and assistant professor at the University of Buffalo, says mammoths’ ecological role may also include increasing the albedo effect (the reflection of light by snow into space and cooling the Earth). But for mammoths to do their job properly, they probably need to be restored across the Arctic.
“You can’t just put mammoths in Alaska and solve the permafrost problem,” Lynch adds. You have to spread them everywhere.”
Lynch believes that there would need to be hundreds of thousands of mammoths on Earth to see a significant impact on climate, and this could threaten living and endangered species.
The Asian and African elephants that Klaasel plans to use as hosts for raising mammoth calves are themselves endangered. An elephant carrying a mammoth fetus cannot give birth to its own children. In this way, this issue will reduce the population of elephants.
Another option is to place embryos in artificial wombs. But the technology is still not fully developed, Lynch says: “Imagine having hundreds or thousands of artificial wombs in warehouses producing genetically engineered mammoths; It’s like a horror and anti-utopian story.”
Unintended consequences
In addition to technical challenges, the restoration of extinct species can have serious consequences. One of the problems is that the regenerated animals may be sick because their genetic diversity is very limited.
To maintain a population, a sufficient number of organisms that are genetically different are needed so that the species is resistant to disease and harmful mutations.
Also, if large-scale mammoth recovery goes awry, who will be responsible? “Biomes have adapted to the absence of mammoths since they went extinct,” Lynch says. What happens if something bad happens?”
Other experts also share such concerns. “To see an impact, there needs to be a large number of animals,” says Sophie Monzara, an ecologist and director of the European Nature Restoration Projects.
Species recovery may lead to conflict between humans and animals
The return of species to nature may also lead to conflicts between humans and wildlife. “In Africa, if you look at elephant conservation and reimportation, you see that there are conflicts,” says Monzara. In Kenya alone, conflicts between humans and elephants killed 200 people between 2010 and 2017. If scientists succeed in producing a viable population of mammoths, they will need to implement nationwide education programs for people to learn how to respond to mammoths.
The composition of regenerated populations is also important. “Brown bears ( Ursus arctos ), which were reintroduced from Slovenia to the Italian Alps in the 2000s, are now thriving, but the original population turned out to be very aggressive,” says Schmitz. “The ecologists did not investigate properly and now these bears are attacking livestock and even humans.”
Schmitz also adds that there is no guarantee that the animals will remain in the same release location. For example, in 1995, gray wolves ( Canis lupus ) were reintroduced to Yellowstone National Park, but they crossed the park boundaries. “If you release the creatures into the wild, they will look for places that are more suitable for them, and those places may not be where you thought they would stay,” he says.
Although herbivores helped store carbon during the last ice age, Love Dallen says, “The recovery of megafauna may have a negative impact on climate change.” For example, mammoths may contribute to global warming by breaking down frozen soil and releasing methane in the warm season. Also, like elephants in the African savannas, by eating plants, they may also reduce the amount of carbon stored in woody plants .”
The last known Tasmanian wolf died in 1936 at Hobart Zoo in Tasmania. If this species becomes extinct, it will compete with another animal called the dingo in Australia, which is currently in danger of extinction.
A pet project for billionaires
While proponents of restoring extinct species cite this as a valuable way to protect the environment, critics argue that investing in conservation programs for existing species is far more effective. Classel has raised at least $225 million so far for its endangered species recovery programs, with a portion of that money going toward conservation and genetics research around the world.
“Instead of using this money to bring back three extinct species with unknown environmental impacts, these funds could be used to save about 100 species that currently face an uncertain future,” says Schmitz.
The best way to support and protect the environment is to invest in proven projects
The goal of species restoration in some cases is organisms that have similar living equivalents that play the same role in ecosystems. For example, one of the reasons for the Tasmanian extinction was that people knew them as livestock hunters. “Right now, we have a similar animal called the dingo or the Australian wild dog ( Canis lupus dingo ) that is facing the same problems as Tasmania,” says Schmitz.
Lynch believes that the best way to support and protect the environment is to invest in existing and proven projects. “Reviving many extinct species with significant environmental impact is likely to be impossible, raising questions about the purpose of de-extinction companies like Klaasel,” he says.
Adam Cyril, a researcher in cultural, historical, and environmental geography at the University of Nottingham, believes that species recovery is unlikely to help solve environmental crises. “The purpose of this project is literally to provide a pet for billionaires,” he says.
In response to Cyril’s criticism, Lam says, “Any species recovery goal requires new technology and techniques that will also benefit closely related species.” He also argues that “technological innovations developed and financed by private companies are very important in this regard.”
Still, aside from Classel’s environmental impact, the return on such a huge investment would be huge, Lynch says. He adds: “I have no doubt that this project will succeed, they will make a lot of money if it succeeds.”
But in the end, says Schmitz, the harms and losses of de-extinction to other people and to nature will far outweigh the benefits.
As a result, the revival of extinct species is technically possible, and with recent advances, it is one step closer to becoming a reality. However, there are serious ethical, environmental, and scientific questions that must be addressed before de-extinction. Critical researchers say that instead of focusing on the recovery of lost species, we should focus on preserving and supporting the species that are still alive and their habitats.
Environment
If the dinosaurs did not become extinct, what would our world be like today?
Published
2 months agoon
26/07/2024If the dinosaurs did not become extinct, what would our world be like today?
Sixty-six million years ago, an asteroid with the power of 10 billion atomic bombs hit Earth and changed the course of evolution forever. The sky became dark and the photosynthesis of plants stopped. First, the plants and then the animals that fed on them were destroyed, the food chain collapsed and more than 90% of the species disappeared. As the dust settled in the Earth’s atmosphere, all dinosaurs became extinct except for a group of birds. But this catastrophic event paved the way for human evolution. The surviving mammals, especially the early primates, multiplied, and then humans evolved.
Strangely, Odysseus lived about 66 million years ago and was one of the last dinosaurs on earth.
Now suppose that the said asteroid had not hit the earth and the dinosaurs would have been saved. Imagine evolved raptors flying their flag on the moon. Dinosaur scientists discover relativity or discussing a hypothetical world dominated by mammals.
This hypothesis may seem like a science fiction story, but it contains deep philosophical questions about evolution. Did humans evolve purely by chance, or was the evolution of intelligent tool-using creatures inevitable?
Brains, tools, language, and large social groups have made humans the dominant species on the planet. Eight billion wise humans (homosapiens) live on the seven continents of the earth. According to the same weight, the number of humans is more than all the wild animals in the world. Humans have changed half of the earth’s land to feed themselves. In the 1980s, paleontologist Dale Russell proposed a thought experiment in which a carnivorous dinosaur evolved into an intelligent, tool-using creature. This dinosauroid has a big brain and walks on two legs.
Dinosauroid model
This hypothesis is not impossible but unlikely. The biology of an animal limits its evolutionary path. Your starting point determines your ending point. If you get kicked out of college, you can’t become a brain surgeon, a lawyer, or a NASA rocket scientist; But you may become an artist, actor, or entrepreneur. The paths we take in life open doors and close others. This also applies to evolution.
For example, consider the dimensions of dinosaurs. Sauropod dinosaurs, such as Brontosaurus and its relatives, weighed 30-50 tons and grew up to 30 meters in length during the Jurassic period. Their weight was ten times the weight of current elephants and their length was as long as a blue whale. This evolution has been seen in several groups such as Diplodocidae, Brachiosaurdiea, Turiasaurdiea, Mamenchisaurdiae, and Titanosauria.
Giant dinosaurs and mammals through time
This evolutionary process was also repeated in different continents at different times and in diverse climates from deserts to rainforests, But the other dinosaurs that lived in these environments did not become gigantic giants. The common point of all the above dinosaurs was that they were all sauropods. Anatomical features of sauropods, such as lungs, hollow bones with a high strength-to-weight ratio, metabolism, or all of these, enhanced their evolutionary potential. In this way, these dinosaurs grew in an unprecedented way.
On the other hand, carnivorous dinosaurs evolved into multi-ton hunters with huge ten-meter bodies. During more than 100 million years, megalosaurids, allosaurids, carcharodontosaurids, neovenatorids, and finally tyrannosaurs evolved into giant apex predators.
Brain size relative to body mass in dinosaurs, mammals, and birds
Dinosaurs had huge bodies, But they did not have a big brains. In fact, dinosaur brains rarely grew over time. Jurassic dinosaurs such as Allosaurus, Stegosaurus, and Brachiosaurus had small brains. 80 million years later, in the late Cretaceous period, tyrannosaurus and duck-billed dinosaurs evolved with larger brains; But the weight of the T-Rex brain, despite its gigantic body, was only 400 grams. The brain of Volareceptor was only 15 grams. Meanwhile, the average weight of the human brain reaches 1.3 kg.
Dinosaurs entered a new era over time. Small herbivores became more common and bird biodiversity increased. Later long-legged species evolved. It also seems that dinosaurs had a complex social life. They began a herd life and evolved with heavy horns for fighting. However, dinosaurs seem to have replicated themselves, usually evolving into giant herbivores and small-brained carnivores.
In the span of 100 million years of the history of dinosaurs, no trace of progress can be seen in them. Giant long-necked herbivores and massive tyrannosaur-like predators recurred during this interval. Maybe dinosaurs’ brains got a little bigger over time, but there is little evidence for their evolution into geniuses. It is even unlikely that mammals would have banished them. Dinosaurs were one of the dominant species in their environment until the asteroid hit.
However, mammals had different limitations. They never evolved into giant herbivores and carnivores. Rather, they repeatedly evolved with larger brains. Examples of large brains (human brain size or larger) are seen in orcas, sperm whales, baleen whales, elephants, leopards, and monkeys.
Golden lion tamarin, South American monkey
Today, few descendants of dinosaurs (birds such as crows and parrots) have complex brains. They can use tools, talk, and count; But mammals such as monkeys, elephants, and dolphins evolved with larger brains and more complex behaviors; So can we say that the elimination of dinosaurs ensured the evolution of mammalian intelligence? maybe not
The starting point can determine the ending point, but it cannot guarantee it. Steve Jobs, Bill Gates, and Mark Zuckerberg were all expelled from the university; But not every expulsion from the university leads to this fate. Even if you start at the right point, you need opportunity and luck to continue. The evolutionary history of primates shows that our evolution was not inevitable. African primates evolved in the form of monkeys with big brains in a span of seven million years and ended up with modern humans, But the evolution of primates took a different path in other places.
When monkeys arrived in the Americas about 35 million years ago, they evolved into other monkey species, and primates arrived in North America at least three separate times, 55 million, 50 million, and 20 million years ago. However, they did not become the species that made weapons and smartphones. Rather, they became extinct for reasons we do not know.
Only in Africa did evolution take a unique path. Perhaps something special about the fauna and flora or the geography of Africa caused apes to take a different evolutionary path and become tool-using primates with large bodies and brains. Even with the extinction of the dinosaurs, human evolution required the right combination of opportunity and luck.
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