Category Zoology

WHEN DID THE EARTH BEGIN TO LOOK AS IT DOES TODAY?

          The surface of the Earth is changing all the time. When living things first began to evolve on Earth, there was just one huge continent. Over millions of years, this continent broke up and moved to become the land masses we recognize today. This is why similar dinosaur fossils have been found in very different parts of the world, although dinosaurs were land creatures and could not cross the oceans.

          The history of Earth concerns the development of planet Earth from its formation to the present day. Nearly all branches of natural science have contributed to understanding of the main events of Earth’s past, characterized by constant geological change and biological evolution.

          The geological time scale (GTS), as defined by international convention, depicts the large spans of time from the beginning of the Earth to the present, and its divisions chronicle some definitive events of Earth history. (In the graphic: Ga means “billion years ago”; Ma, “million years ago”.) Earth formed around 4.54 billion years ago, approximately one-third the age of the universe, by accretion from the solar nebula. Volcanic outgassing probably created the primordial atmosphere and then the ocean, but the early atmosphere contained almost no oxygen. Much of the Earth was molten because of frequent collisions with other bodies which led to extreme volcanism. While the Earth was in its earliest stage (Early Earth), a giant impact collision with a planet-sized body named Theia is thought to have formed the Moon. Over time, the Earth cooled, causing the formation of a solid crust, and allowing liquid water on the surface.

          The Hadean eon represents the time before a reliable (fossil) record of life; it began with the formation of the planet and ended 4.0 billion years ago. The following Archean and Proterozoic eons produced the beginning of life on Earth and its earliest evolution. The succeeding eon is the Phanerozoic, divided into three eras: the Palaeozoic, an era of arthropods, fishes, and the first life on land; the Mesozoic, which spanned the rise, reign, and climactic extinction of the non-avian dinosaurs; and the Cenozoic, which saw the rise of mammals. Recognizable humans emerged at most 2 million years ago, a vanishingly small period on the geological scale.

          The earliest undisputed evidence of life on Earth dates at least from 3.5 billion years ago, during the Eoarchean Era, after a geological crust started to solidify following the earlier molten Haden Eon. There are microbial mat fossils such as stromatolites found in 3.48 billion-year-old sandstone discovered in Western Australia. Other early physical evidence of a biogenic substance is graphite in 3.7 billion-year-old metasedimentary rocks discovered in southwestern Greenland as well as “remains of biotic life” found in 4.1 billion-year-old rocks in Western Australia. According to one of the researchers, “If life arose relatively quickly on Earth … then it could be common in the universe.”

          Photosynthetic organisms appeared between 3.2 and 2.4 billion years ago and began enriching the atmosphere with oxygen. Life remained mostly small and microscopic until about 580 million years ago, when complex multicellular life arose, developed over time, and culminated in the Cambrian Explosion about 541 million years ago. This sudden diversification of life forms produced most of the major phyla known today, and divided the Proterozoic Eon from the Cambrian Period of the Paleozoic Era. It is estimated that 99 percent of all species that ever lived on Earth, over five billion, have gone extinct. Estimates on the number of Earth’s current species range from 10 million to 14 million, of which about 1.2 million are documented, but over 86 percent have not been described. However, it was recently claimed that 1 trillion species currently live on Earth, with only one-thousandth of one percent described.

          The Earth’s crust has constantly changed since its formation, as has life since its first appearance. Species continue to evolve, taking on new forms, splitting into daughter species, or going extinct in the face of ever-changing physical environments. The process of plate tectonics continues to shape the Earth’s continents and oceans and the life they harbor. Human activity is now a dominant force affecting global change, harming the biosphere, the Earth’s surface, hydrosphere, and atmosphere with the loss of wild lands, over-exploitation of the oceans, production of greenhouse gases, degradation of the ozone layer, and general degradation of soil, air, and water quality.

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WHAT WERE THE FIRST LIVING THINGS ON EARTH?

          Although viruses are the simplest living things, they need to live and reproduce themselves inside a larger organism, so they are unlikely to have been the first living things on Earth. The earliest evidence of life that has been found is tiny fossils of primitive bacteria in rocks about 3800 million years old. Later, blue-green algae evolved. They could use energy from the Sun and in so doing gave off oxygen. Modern plants and animals share these simple organisms as ancestors.

          The earliest evidence for life on Earth arises among the oldest rocks still preserved on the planet. Earth is about 4.5 billion years old, but the oldest rocks still in existence date back to just 4 billion years ago. Not long after that rock record begins, tantalizing evidence of life emerges: A set of filament-like fossils from Australia, reported in the journal Astrobiology in 2013, may be the remains of a microbial mat that might have been extracting energy from sunlight some 3.5 billion years ago. Another contender for world’s oldest life is a set of rocks in Greenland that may hold the fossils of 3.7-billion-yer-old colonies of cyanobacteria, which form layered structures called stromatolites.

          Some scientists have claimed to see evidence of life in 3.8-billion-year-old rocks from Akilia Island, Greenland. The researchers first reported in 1996 in the journal Nature that isotopes (forms of an element with different numbers of neutrons) in those rocks might indicate ancient metabolic activity by some mystery microbe. Those findings have been hotly debated ever since — as, in fact, have all claims of early life.

          Most recently, scientists reported in the journal Nature that they had discovered microfossils in Canada that might be between 3.77 billion and 4.29 billion years old, a claim that would push the origins of life to very shortly after Earth first formed oceans. The filament-like fossils contained chemical signals that could herald life, but it’s hard to prove that they do, researchers not involved in the study told Live Science. It’s also hard to prove that fossils found in ancient rocks are necessarily ancient themselves; fluids have penetrated cracks in the rock and might have allowed newer microbes in to older rock. The researchers used samarium-neodymium dating to arrive at the 4.29 billion maximum age for the fossils. This method, which uses the decay of one rare-earth element into another, may measure the age of the magma that formed the rocks rather than the rocks themselves, an issue that has also dogged claims of the Earth’s oldest rocks.   

          Still, the fact that suggestive evidence of life arises right as the rock record begins raises a question, said University of California, Los Angeles, geochemist Elizabeth Bell in a SETI Talk in February 2016: Is the timing a coincidence, or were there earlier forms of life whose remnants disappeared with the planet’s most ancient rocks?

          The period that occurred before the rock record begins is known as the Hadean. It was an extreme time, when asteroids and meteorites pummeled the planet. Bell and her colleagues said they might have evidence that life arose during this very unpleasant time. In 2015, the research team reported discovering graphite, a form of carbon, in 4.1-billion-year-old crystals of zircon. The ratio of isotopes in the graphite suggested a biological origin, Bell and her colleagues wrote in the journal Proceedings of the National Academy of Sciences.

          “There is some skepticism, which is warranted,” Bell told Live Science. Meteorites or chemical processes might have caused the odd carbon ratios, she said, so the isotopes alone aren’t proof of life. Since the publication of the 2015 paper, Bell said, the researchers have found several more of the rare-carbon inclusions, which the scientists hope to analyze soon.

          From what is known of this period, there would have been liquid water on the planet, Bell told Live Science in an interview. There might have been granite, continental-like crust, though that’s controversial, she said. Any life that could have existed would have been a prokaryote (a single-celled organism without membrane-bound nuclei or cell organelles), Bell added. If there was continental crust on Earth at the time, she said, prokaryotes might have had mineral sources of nutrients like phosphorus.

          A different approach to the hunt for Earth’s early life suggests that oceanic hydrothermal vents may have hosted the first living things. In a paper published in July 2016 in the journal Nature Microbiology, researchers analyzed prokaryotes to find the proteins and genes common to all of these organisms, presumably the final remnants of the Last Universal Common Ancestor (LUCA) — the first shared relative from which all life today descends.

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What is the mosquitoes job in the food chain?

Scientists are not sure. Mosquitoes are not known for eating waste. They don’t improve the soil like earthworms do. Yes, frogs prey on mosquitoes, but it is not their major food source. Mosquitoes pollinate plants since the males drink nectar, but they don’t do a lot of it.

Winegard thinks that may be mosquitoes have evolved to check the uncontrolled human population growth. But no one will accept that theory. Others say they have been put on earth to tell us that we are not as mighty as we think we are. We can be brought down by a tiny insect army. Do you agree?

So do we eradicate all mosquitoes? Biologists say they are part of the ecological cycle, so we cannot. They are there for a purpose, for balance in the eco-system. Who knows, maybe if we kill off all the mosquitoes, we may upset this balance and the natural selection of species. Winegard also points out: “Since there are 3,500 mosquito species and very few transmit diseases, perhaps the eradication of those that transmit diseases is extreme.”

 

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How can we prevent mosquito bites?

Why mosquitoes bite and what to do:

  • According to studies, mosquitoes prefer blood type O over A, B or a mix of any of them. So if your blood type is O, you find more of the insects buzzing around you.
  • Mosquitoes are attracted to bright colours.
  • Mosquitoes like the smell of beer in beer drinkers.
  • When you exercise, you let out a lot of carbon dioxide. Mosquitoes thrive on CO2.
  • Our skin usually keeps us safe from mosquitoes, but you know they attack your legs. That is because of the bacteria on your feet.
  • All this information about what is good for them is genetically coded into the mosquito brain. So the insect knows where to find food.

What you can do:

  • Sleep under a net if your area is mosquito-prone.
  • Keep surroundings clean to prevent them from breeding.
  • Keep your feet covered in places like the park, bus stands, railway stations, movie halls.
  • Wash your feet well when you reach home after school, before sitting down at the table to study.

 

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How to determine if mosquitoes are ready to feed?

Mosquitoes buzzed around even when dinosaurs roamed the earth. By sucking blood and carrying parasites of crippling diseases, these creatures have ravaged human populations, especially in Africa. Mosquito bites have caused the death and disability of millions of people, ruining the economy of some countries:

Weaponized

Mosquitoes have been used as a biological weapon during wars. According to Winegard, the Nazis purposely re-flooded the Pontine Marshes around Rome and Naples in Italy to reintroduce mosquitoes, and they spread malaria in that part of Italy during World War II. The soldiers fighting the Nazis got malaria and had to be sent back.

With all the science and technology we have now, why are we not eradicating mosquitoes?

Here is why:

They’re everywhere

Mosquitoes are everywhere – in swamps, forests, fields and homes – 110 trillion of them. They are global, and have been around for 100 million years. They are great survivors, “masters of evolutionary adaptation.” They are resilient, which means they can adapt to different weather conditions and terrains. They withstood “global showers” of DDT spray, and five types of mosquitoes are now immune to this pesticide. We all have defences in our body against disease. In the same way, mosquitoes have developed immunity to survive our attempts to kill them off.

Untiring work

Still, a lot of work has been done to tackle this relentless insect. Funding is available for research on mosquito-borne disease. Mosquito nets are given out in large numbers to people. Insecticides and malaria drugs are distributed in counties that cannot afford them. Doctors say death from malaria, the major disease caused by mosquitoes, has decreased across the world. However, there is an increase in the incidence of Zika, West Nile, and dengue.

Governments are low trying biological control of mosquitoes. This is to avoid use of pesticides. In this method, fish are bred in ponds where mosquitoes lay eggs. The fish eat the larvae. There are also plants that kill mosquito larvae. But these have had only limited success in keeping down mosquito numbers.

Climate crisis

Mosquitoes thrive when we create the right environment for them – by rearing animals and plants close to our homes, cutting down trees, letting water stagnate and keeping sewage channels open. Climate change, which is now a serious crisis, also helps breed mosquitoes. “Increased temperatures mean a longer breeding season for mosquitoes,” said Winegard in an interview.

“Canada has seen a 10% increase in mosquito-borne disease in the last 20 years. In the southern US, we’ve seen domestic cases of Zika, chikungunya, and even dengue in the last 10 years. So if temperatures rise around the planet, which increases the risk of spreading disease.”

 

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Why is the mosquito deadly?

The mosquito transmits or carries more diseases than any other insect. The six major ones spread by it are: malaria, dengue fever, chikungunya, zika fever, lymphatic filariasis and Japanese encephalitis.

Different species of the mosquito cause different illnesses. Research into human civilisation shows that mosquito-borne diseases throughout history have killed more people than man-made weapons.

In the book: The Mosquito: A Human History of Our Deadliest Predator, historian Timothy Winegard gives us this startling fact: over the course of 200,000 years, 108 billion people have lived on Earth. Of these, 52 billion have been killed by mosquitoes. Since 2000, an average of 2 million people have died due to diseases caused by mosquitoes. And so, it is safe to sat, the insect has had a disastrous effect on our civilisation.

 

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