Are We Close to Finding Extraterrestrial Life?

 The topic of many of my articles involves the search for extraterrestrial life. I look at what conditions are needed to support life on Earth and see if such environments exist elsewhere. For example, we found seasonal variations of methane in the Martian atmosphere. On our planet, methane is almost exclusively associated with life. I’ve written about astronomers’ efforts to find and study planets orbiting other stars to determine if they orbit in the habitable zone where water can exist on the surface. On Earth, virtually wherever we find water, we find living creatures. That may only be microbial life, such as that found in acidic hot springs or water trapped far below the surface, but life nonetheless.

Even if we only find such microbial life, that would be an astounding discovery. It would tell us that life can develop in locations other than Earth which at the moment is the only location in the universe where life is known to exist.

Recently, a newsletter called The Conversation ran an article in which the authors polled astrobiologists and other scientists on their belief in extraterrestrial life. The Conversation is an online source of articles written by researchers and academics across all disciplines. It gives them a platform to present their work to the public. We often read articles that say finding extraterrestrial life is “only a matter of time”, or “we are close to finding alien life.” And yet, we still await that discovery.

Exoplanets in their star's habitable zone. Are we close to discovering exo-life?

In 2024, three researchers – Peter Vickers, a Professor in Philosophy of Science at Durham University, Henry Taylor an Associate Professor in the Department of Philosophy at the University of Birmingham, and Sean McMahon, of the University of Edinburgh – did surveys, polling a number of astrobiologists, those scientists who study and look for the chances of life elsewhere, and scientists in other fields on their beliefs of the existence of alien life. They asked about their beliefs, based on all the research to date, of the existence of basic lifeforms, i.e. microbial life, complex forms, i.e. multicellular life, and intelligent extraterrestrial life.

Altogether, they received responses from 521 astrobiologists and 534 non-astrobiologists. Of the astrobiologists, 86.6% said they “agree” or “strongly agree” that extraterrestrial life, at least at the basic level, exists elsewhere. Less than 2% disagreed with the sentiment and 12% claimed to be neutral on the possibility. Of the non-astrobiologists, 88.4% also marked “agree” or “strongly agree” with the question. Scientists who don’t study the possibility of extraterrestrial life are not more skeptical than those who do. The authors of the survey felt that to be a rather significant result.

The survey asked about each level of life – basic, complex, and intelligent – separately. The results when asked specifically about whether “intelligent” aliens exist were not quite as optimistic. Only 67.4% of astrobiologists and 58.2% of other scientists agreed, still more than half. Only 10.2% of astrobiologists disagreed with that statement.

This survey cannot in any way offer proof of life elsewhere, but the preponderance of scientific research and evidence leads most scientists, at least in these fields, to accept the likelihood. Astronomers estimate that in our galaxy alone a trillion extrasolar planets, those orbiting other stars, exist. They further estimate that billions of Earth-like planets orbit in the habitable zone of their parent star.

Life on Earth is proving to be far more robust than we previously thought. Microbes called extremophiles can survive in all kinds of environments once thought unable to support any kind of life. Creatures called tardigrades, or water bears, have even been shown to survive in airless, radiation-filled outer space beyond our planet. I suspect that the existence of such extremophiles that survive in these hazardous or toxic locations is a large part of the thought processes of these scientists.

Perhaps it really is only a “matter of time” before we discover alien life forms. And. Some scientists say we may not even recognize alien creatures as living at first. We have no idea if “life as we know it” is all that there can be.

 

Each month, I write an astronomy-related column piece for the Oklahoman newspaper. After it is published there, I post that same column to my blog page.

This is reprinted with permission from the Oklahoman and www.Oklahoman.com.

Did Planets from the Inner Disk of the Milky Way Become Rogue Planets?

 We think of a planet as a non-luminous body that orbits a star, like the planets of our solar system. But that’s not always the case.

All stars form from clouds of gas and dust that collapse inward due to the pull of gravity. The pressure caused by the gravitational crunch squeezes gas in the center of each cloud so tightly that it heated the gas to extreme temperatures, generating thermonuclear reactions, and a new star is born. Our sun flared into existence four and a half billion years ago, far younger than the oldest stars, which are born in other parts of the galaxy.

But there was still quite a bit of leftover gas and dust surrounding the young sun which formed a disk around the new star. This leftover bit eventually becomes all of the planets, moons, comets, and asteroids that orbit our sun.

Our solar system lives in the spiral arms of the Milky Way galaxy. Most of the galaxy’s younger stars like our sun are in the spiral arms. Astronomers estimate that virtually all of these stars have planets, an average of two and a half planets per star.

The older stars of our galaxy mostly reside in a bulge surrounding the center of the Milky Way. Stars there have on average barely one planet per star.  MIT astrophysicist Tim Hallatt thinks he knows why. “The puzzle is, these planets (in the spiral arms) are very common,” Hallatt says. “And yet when we look at this other dominant population of stars in the Milky Way, they’re less common. So what’s going on?”

As is the case with all large galaxies like ours, when the Milky Way first formed some 12 billion years ago, star formation was fast and furious, a time Hallatt describes as galactic chaos, what astronomers generally refer to as “cosmic noon.” Also, the stars there were more closely bunched together than the stars in our neighborhood. The greater levels of energetic radiation from the process of rapid star formation plus the relative proximity of stars meant that the stars during cosmic noon experienced ten million times greater levels of radiation. This intense radiation would have heated the gas surrounding all these rapidly forming stars. The greater levels of radiation and heat blew away much of the remaining gas, leaving less raw material for planets.

When astronomers search for planets beyond our own solar system, they look at other stars. We currently know of more than 5000 such exoplanets, and the more we look, the more we find. Astronomers also find lots of rogue planets, planets that don’t orbit any star. They may have formed around a star but were ejected from their home stellar system, perhaps due to close passage of another star. The gravity of the passing star can rip a planet away from its home. Astronomers estimate that perhaps as many as four trillion rogue planets exist in our galaxy alone. That’s a huge number.

Artist's conception of a Rogue Planet

It’s likely that some of those rogue planets formed on their own, not as part of a stellar system. Perhaps some of the gas and dust blown out by the stars formed during the crowded cosmic noon eventually coalesced into rogue planets. Many of these rogue planets could have orbited a star but for the early period of rapid star growth.

Rogue planets may easily outnumber the stars in our galaxy. And some of those rogue stars may be causalities of the cosmic noon timeframe of our Milky Way galaxy.

Each month, I write an astronomy-related column for the Oklahoman newspaper. After it is published there, I post that same column to my blog page.

This is reprinted with permission from the Oklahoman and Oklahoman.com.

The New Space Race

 NASA has plans to return to the Moon, first with a space station orbiting it and soon after that a permanently manned lunar research facility. China also plans to establish a permanent research station on the Moon. India is preparing for a second lunar landing with the eventual goal of a manned presence in the near future.

Our natural satellite is a treasure trove of valuable minerals. Nations that develop lunar mining capabilities will gain access to important resources. One such lunar resource you might not immediately think of is Helium 3. Normal helium contains two protons and two neutrons in its nucleus. Helium 3 has only one neutron. Why would this be important? That isotope of helium is extremely significant in the production of non-polluting energy.

Currently, our primary source of non-renewable energy on Earth comes from burning fossil fuels which releases copious amounts of carbon dioxide, a major cause of global warming. The process also releases a lot of sulfur which combines with water to create sulfuric acid, acidifying our lakes and oceans and leading to the possible extinction of numerous species. The acid rain leaches minerals from the soil that trees and other plants need for proper growth. The particulates that fossil fuel burning puts in the air are a major health risk for all animals, including us humans.

Many countries also rely on nuclear power plants for energy production. These plants rely on nuclear fission, the splitting of uranium and plutonium atoms to generate energy, but also generate tons of radioactive waste materials for which we currently have no safe disposal methods.

So what does the Moon have to do with all of this? Helium 3. With no atmosphere or magnetic field to protect it from the harsh solar wind, the Moon’s surface is bombarded with charged particles, and helium 3 is one product of this. The surface of our Moon has an abundance of it. Helium 3 can be used in fusion reactors to make clean, pollution-free energy, the same process that powers our sun. Scientists have recently figured out how to create fusion reactors that deliver more energy than it takes to power them, giving us the promise of almost unlimited energy production that won’t destroy our forests or threaten extinction.

Artists conception of Lunar Helium-3 mining. Credit ESA

We’ve found a lot of water in the form of ice at the south pole of the Moon. Water can be used for drinking, oxygen for breathing, and rocket fuel. It is much easier to blast off from the Moon than it is from Earth due to the Moon’s weaker gravity. That gives us an easier stepping stone to explore the solar system. Easier and cheaper access to space allows us greater opportunity to explore the asteroid belt.

One goal of space exploration is to mine asteroids for rare minerals, such as lithium, cobalt, manganese, and nickel, all important for creating electronic devices like smartphones, computers, and batteries that can store electrical energy and power vehicles that don’t burn fossil fuels. Asteroids also contain copious amounts of iron, silver, gold, and platinum, all valuable in modern society.

There are, of course, a tremendous number of scientific reasons for having a lunar base. The Moon itself still holds many secrets for us to discover. The relative ease of access to space from the Moon provides scientists the opportunity to study our solar system in great detail. Telescopes located on the Moon’s far side give us the chance to study the cosmos without interference from Earthly sources of radio noise and light pollution, not to mention the huge and growing number of satellites in orbit around Earth that interfere with astronomical studies.

Our Moon holds many riches, both economic and scientific, making it a goal to create a permanently manned scientific colony there. That is the new space race.

 

Each month, I write an astronomy-related column piece for the Oklahoman newspaper. After it is published there, I post that same column to my blog page.

This is reprinted with permission from the Oklahoman and www.Oklahoman.com.