Microbes may already be in contact with alien species, which is something similar to what we tried to do with the SETI project since 1959.
Are we alone in the universe? The famous program he sat (I am looking for an intelligent extraterrestrialHe has been trying to answer this question since 1959.
American astronomer Carl Sagan, and many others, believe that other human-like civilizations should exist and that we can communicate with them. But skeptics are not convinced, arguing that the lack of evidence for such civilizations suggests so Extremely rare.
But if other human-like civilizations are unlikely to exist, could there be other forms of life – perhaps more suited for us to spread into the universe? Is it possible for these life forms to communicate with each other?
New study Published In the magazine Vital systems, It is suggested. Microbes, like bacteria, can be the rulers of cosmic life – and they are smarter than we think. In fact, the researchers explain how Microbes can mimic the SETI program without human intervention.
To understand microbes, we need to challenge our human biases. Although many of us see microbes as single-celled organisms that cause disease, the reality is different.
Microbes Multicellular entities freely organized. Bacteria, for example, live as societies of several billion – colonies capable of “thinking” and making decisions.
A typical bacterial colony is a cyber entity – the “superbrain” that solves environmental problems. Most importantly, all of the bacterial colonies on Earth are interconnected in a universal super-bacterial system called the germinology.
he is World wide web Genetic information has orchestrated the flow of organic elements on Earth over the past three billion years, in a way that will forever be outside human capabilities. They are, for example, Able to recycle important nutrients such as carbon, nitrogen and sulfur.
Even today, bacteria are the most widespread living organism on Earth. A recent study found that terrestrial bacteria can survive in space for at least three years, and possibly longer. Bacteria can exist in a dormant state for millions of years and it is clear that Microbes are highly resistant.
In fact, there are many versions of Panspermia – which claims that microbial life exists and travels through the universe – supports this idea. Recent mathematical models have supported this, showing that microbial travel may be possible not only in our solar system, but throughout the galaxy.
How do microbes work? Scientists think microbial envelope could be a possibility Repeat all known human tracing steps.
The first step in human SETI is the ability to read information on a cosmological scale. The second step is to develop the techniques and knowledge to assess whether habitable planets are the home of life. The third step is to announce our presence on Earth to extraterrestrial intelligence and try to contact them if they respond to the initial signals.
The second step was crucial to the development of life on Earth. Cyanobacteria have developed biotechnology in the form of photosynthesis. Transform this dead planet into a living planet, or germinology, over a long evolutionary period.
Then microbial life became more complex, creating plants and animals in the last 600 million years. However, bacteria remain the most widespread form of life on the planet. Photosynthesis, as a form of bacterial technology, has always fueled life on Earth.
The third step is about attracting and communicating between microbes with similar chemicals. Extraterrestrial microbes should be able to seamlessly integrate into Earth’s microbiota if they engage in carbon-based chemistry and metabolism, including DNA, proteins, and other biomolecules.
The opposite process is also possible. Earth’s microbes can travel to space on asteroids and grow life elsewhere in the universe. Alternatively, humans, as future cosmic travelers, could function as microbial vectors thanks to the human microbiome.
To appreciate the microorganism microorganism, we need to understand the concept of intelligence in an evolutionary sense. This will make it possible to better assess bacterial intelligence and its capabilities in the context of both human and microbial microorganisms. Some biologists argue that Human intelligence is just a part of a broad spectrum From natural intelligence that includes microbes and plants.
We also need to re-evaluate technology signatures as markers of smart civilizations. According to physicist Freeman Dyson, technologically advanced civilizations should have high energy requirements.
These demands can be fulfilled by building gigantic cosmic structures, called Dyson spheres, around their planets that can capture the energy of their host star. Look for these areas, and check if the starlight is blocked, It might be a way to find them.
But if human-like civilizations are really rare, then there is no point in looking for such structures. Alternatively, it may be more appropriate to search for vital signatures as signs of microbial life on habitable planets.
The way forward in the search for extraterrestrial life might be to look for gases in the atmosphere of planets that signify life, such as Oxygen, methane, or phosphine, Produced by microbes.
The discovery of phosphine in Venus’ atmosphere was promising evidence, but now appears doubtful, as a new study suggests that the signal may have been sulfur dioxide rather than phosphine.
However, We have no choice but to keep trying. Fortunately, the James Webb Space Telescope should be able to track the atmospheres of planets orbiting stars other than our own sun when it launches later this year.
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