Author: cfb1270

From ‘Not My President’ to ‘Fuck Biden’

I remember not long ago when Candidate Trump won the 2016 election and became President. It wasn’t a win by popular vote but by the Electoral College. That is how the United States elections work here, on the principle of the Electoral College established by our Founding Fathers.

I have not agreed with this way of voting for a long time, but it is our system and should be respected. I bring up this point because, in 2016, Hillary Clinton won the popular vote by nearly 2.9 million people. That is not a tiny number, and thinking of all those people, it makes sense that nearly every major city in the United States found itself inundated with peaceful protests.

During the weeks following the election, social media exploded with people ranting that “Trump Is Not My President.” I was not among those; however, my close friends did know my opinion on Trump. My best friend from childhood, nearly a sister because we grew up together, is on the opposite political side as me. I don’t love her any less but have witnessed the radical change in her thinking as I have seen in so many people that only get their news from Fox Opinion Media Network. (I am not sorry for not using the term ‘news’ because they are far from a news network, but that is another story.)

In one of my discussions with, Mary, she turned around and said: “Well, he is your President, Craig!”

“Yes, I know,” I replied calmly. “I never said he wasn’t my President, but that does not mean I have to respect him. Respect is earned, and in my opinion, he is not a respectful person; therefore, does not deserve my respect in return. I have never totally agreed with any president. I agree with some things and disagree with others. I don’t agree just because the person is on my team.” More than anything, I do remember how outraged Trump supporters were. They couldn’t believe people were saying this about a sitting president of the United States. It was disrespectful. It was Hateful. They were sore losers. They wanted people to “Get Over It!” And “Give Trump a Fair Chance!”

Their outrage was only because it was their team was in the crosshairs. Their cries of fairness, respect, and asking for peace evaporated like wispy fog once Trump lost the 2020 election. Almost immediately, signs and bumper stickers and flags materialized with “Fuck Biden” and other derogatory statements that persist two years later. It saddens me every time I see these flags and bumper stickers because what do these messages say to children? I understand they are angry; they lost by almost the same margin Trump called a landslide in 2016. Why can’t they just say “I don’t agree,” or even just “Not My President,” why the vulgarity? Why call a sitting Vice-President a Ho?

I’ve heard supporters say she must have “slept her way to the top, what a whore.” In front of children.

I do not respect these Trump Supporters who change their position as easily as the sand on the beach changes its design. You earn respect, and these people have no respect for the Constitution, political system, justice department, American Values, or the next generation.

I fear for our country if Trump Republicans gain office positions this year and in 2024. America is balancing on a pinhead, and if they win, we may not have an America anymore.

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Ladies, Lay Down and Enjoy It

March 9, 2022, was just another typical day for me. A day most Americans probably share: struggle out of bed, let the dog out, shower to bring life back to consciousness, and pour a cup of coffee into an insulated mug to supply the body with a caffeine boost. Meanwhile, glancing at the clock or my iWatch, and marvel at how fast time moves in the morning!

Now the rush starts to beat the clock. Does anyone else feel that way? Like we are trying to outrace time? But I always seem to win the race. At least to the car, all bets fly out the window. Anyway, I grab everything I need and dash to the car with my hot coffee sloshing in the mug and threatening to splash out of the tiny sip hole. One would think that physics wouldn’t allow erratic motion, opposite sloshing liquid, and a small hole to work harmoniously to splash one’s arm, shirt, or pants. I proudly say it can and does happen all too often.

Once in the car, I generally fumble for the iPhone, jam in the charging cord, and start my morning podcast selection. In my situation, NPR News, the hourly five-minute byte starts my commute. A few minutes into the broadcast, the news anchor reported on a story of Robert Regan, a GOP candidate in Michigan said: “I tell my daughters, ‘Well, if rape is inevitable, you should just lie back and enjoy it.’”

“What The Fuck!” I shouted inside the empty car before my jaw could unhinge, making me look like an open-mouthed fool as cars passed me, going the opposite way. I contemplated what I had just heard. “No,” I Thought. “I wasn’t paying attention and missed something, or my brain was fucking with me.” My car rolled to a gentle stop at the next traffic light. I took my phone, jabbed at the replay icon, and then sat back to listen again with all my attention.

Yes. I heard correctly. My brain, in this situation, was behaving. My fingertips drummed on the top of the steering wheel. “Why do women continue to cast votes for these assholes?” I asked aloud as I waited for the light to turn green. Of course, it was theoretically possible that Robert Regan’s words may be out of context. It wouldn’t be the first time I heard just a soundbite that caused misrepresentation. However, that happens much more on conservative networks, especially on Fox News (or what I call Fox Entertainment News), and I have yet to hear a soundbite from NPR that would deliberately cause a stir.

I decided I needed to know more and made a mental note to investigate further when I arrived at work. It is a foreign concept for me to understand how people can get stuck listening to only one source of information. I cannot exist in a self-served information bubble. How can one come to a reasonable conclusion if one doesn’t listen to both sides of the story?

I know people who will only listen to conservative media and those who only listen to non-conservative press; this makes no sense to me! As a true American, wouldn’t you want to know both sides? Wouldn’t you want to hear opposing positions’ entire conversations and thoughts? How can you tell who is telling the truth and who is misrepresenting the facts if you don’t force yourself into the center position?

Let’s look at it from this perspective. My son and daughter are fighting about something involving two dollars. My daughter is the first to cry out her story. I immediately turned to my son and sentenced him to punishment. Then abruptly turned away from his pleas.

Besides not winning fatherhood of the year, it certainly wasn’t fair. But my daughter is Fox, and my son is CNN. Who the hell would believe CNN?

But let’s rewind this scenario and place me in the center, where parents should be when solving endless disagreements between siblings. Now I learn that my daughter took two dollars off my son’s bed while he was in the bathroom. My son didn’t say she could have it. My daughter informs me that he borrowed two dollars from her last week and said he would pay her back this week. Now, who is wrong and who is right? What does a parent do?

What should a citizen of the United States do? What did our Founding Fathers believe should happen? Find common ground. Find a solution. Right the wrongs honestly and fairly.

So, staying true to my nature and getting back on topic. Here is a part of the article posted by The Washington Post on March 8, 2022, by Mariana Alfaro.

During the discussion, fellow panelist Amber Harris, a Republican strategist, told the group that it is “too late” to continue challenging the results of the 2020 election, suggesting Republicans should instead move on and focus on future races, to which Regan replied: “I tell my daughters, ‘Well, if rape is inevitable, you should just lie back and enjoy it.’ ”

Regan then moved on to other comparisons, drawing a parallel between his recent victory in the Republican primary and the biblical story of David and Goliath.

A shocked Harris, however, tried to cut in as Regan and the discussion’s host, Rescue Michigan Coalition founder Adam de Angeli, moved on.

When de Angeli gave Harris the chance to speak, she said Regan’s comments were “shameful.” “I’ve got advice to give to your daughters: Don’t do that,” Harris said. “Fight all the time.”

One of Regan’s daughters urged voters not to elect him to office in a viral tweet during his 2020 bid for the state House. “If you’re in Michigan and 18+ pls for the love of god do not vote for my dad for state rep. Tell everyone,” Stephanie Regan wrote on Twitter.
The Washington Post on March 8, 2022, by Mariana Alfaro

As a father of three children, my youngest a girl, I simply could not comprehend how any father could say such a thing, regardless of whether he was trying to make an analogy. Fuck! What dad would say something like that?

Seriously, why do women vote for people like this? Even if you are a down-the-ballot Republican voter. Why vote for slime like this instead of abstaining?

Robert Regan (Michigan Republican) does not stand alone in his foul views of rape or incest. Unfortunately, it seems a significant chunk of Republicans holds similar views. A part of me can’t even comprehend these statements, and there are a dozen I have left out to save space and keep the reader from vomiting. These people are sick and sorry, and so are those that vote them into office.

Texas gubernatorial candidate Clayton Williams – Rape is kinda like the weather. If it’s inevitable, relax and enjoy it.”  

Missouri Senate Candidate Todd Akin – “If it’s a legitimate rape, the female body has ways of shutting that whole thing down.”  

Arizona Rep. Trent Franks – “The incidence of rape resulting in pregnancy are very low.”

Presidential Candidate Rep. Ron Paul – “If it’s an honest rape, that individual should go immediately to the emergency room. I would give them a shot of estrogen.”

Presidential Candidate and Former Sen. Rick Santorum – “I think the right approach is to accept this horribly created — in the sense of rape — but nevertheless a gift in a very broken way, the gift of human life, and accept what God has given to you… rape victims should make the best of a bad situation.”

Texas gubernatorial candidate Clayton Williams – “Rape is kind of like the weather. If it’s inevitable, relax and enjoy it.”​  

Idaho Sen. Chuck Winder – “I would hope that when a woman goes into a physician, with a rape issue, that that physician will indeed ask her about perhaps her marriage, was this pregnancy caused by normal relations in a marriage, or was it truly caused by a rape.”

Illinois Rep. Joe Walsh – “There is no such exception [for abortion] as life of the mother, and as far as health of the mother, same thing, with advances in science and technology.”

Indiana Senate candidate Richard Mourdock – “I think even when life begins in that horrible situation of rape, that it is something that God intended to happen.”

Lawrence Lockman, a Republican member of the Maine House of Representatives  – “If a woman has (the right to an abortion), why shouldn’t a man be free to use his superior strength to force himself on a woman? At least the rapist’s pursuit of sexual freedom doesn’t (in most cases) result in anyone’s death.”

Indiana Senate candidate Richard Mourdock, 2012 – “I think even when life begins in that horrible situation of rape, that’s something God intended to happen.”

Ohio state Rep. Jean Schmidt, 2022 – “Rape is a difficult issue and it emotionally scars the individual, all or in part, for the rest of their life — just as child abuse does. But if a baby is created, it is a human life and whether that mother ends that pregnancy or not, the scars will not go away, period. It is a shame that it happens, but there’s an opportunity for that woman, no matter how young or old she is, to make a determination about what she’s going to do to help that life be a productive human being.”

June 23, 2013, Jodie Laubenberg – “In the emergency room they have what’s called rape kits, where a woman can get cleaned out.”

Former Arkansas Governor Mike Huckabee – “Ethel Waters, for example, was the result of a forcible rape. …And so I know it happens, and yet even from those horrible, horrible tragedies of rape, which are inexcusable and indefensible, life has come and sometimes, you know, those people are able to do extraordinary things.”

Washington State Congressional Candidate John Koster on Abortion – “I know a woman who was raped and kept the child, gave it up for adoption and doesn’t regret it. In fact, she’s a big pro-life proponent. But, on the rape thing it’s like, how does putting more violence onto a woman’s body and taking the life of an innocent child that’s a consequence of this crime, how does that make it better?”

West Virginia state delegate Brian Kurcaba, 2015 – “Obviously rape is one of the most egregious acts anyone can ever do to someone … but what is beautiful is the child that could come as a production of that.”  

Washington Rep. John Koster, 2012 – “On the rape thing, it’s like, how does putting more violence onto a woman’s body and taking the life of an innocent child that’s the consequence of this crime, how does that make it better? You know what I mean?”

I am glad for one thing. Robert Regan lost his race against Democrat Carol Glanville. Still, a sad fact remains here. Carol Glanville topped 52% of the votes cast; Regan earned 40%, and 8% went to write-ins. I wonder how many women voted for him? 40% is still a significant number of votes. Think about it. What do you feel about such demeaning and horrible comments directed at women and rape victims?

The Republican Party doesn’t represent American Values. Not anymore.

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New Year’s Resolution

So, it is that time of year again when people look ahead and make a resolution for the new year. Now, be honest with yourself. How many times have you set a goal and failed?

Yeah, that’s what I thought. Did you know almost everyone fails to keep their resolution? It’s true. Most likely you have fallen into picking one of the following resolutions:

  • Exercise more
  • Lose weight
  • Eat more healthily
  • Take a more active approach to health
  • Learn new skill or hobby
  • Spend more time on personal wellbeing
  • Spend more time with family and friends
  • Drink less alcohol
  • Stop smoking

For the past several years I have made the same resolution and for the most part I’ve kept up with it. I will be honest; my resolution has become second nature to me, so I hardly realize I’m doing it. Not only is this resolution easy, but it makes me feel good. That is the key here. When you do something that feels good your body releases a chemical called dopamine which is a highly addictive “feel good” natural chemical reaction.

What is Dopamine? Dopamine is a neurotransmitter that helps control the brain’s reward and pleasure centers. Dopamine also helps regulate movement and emotional responses, and it enables us not only to see rewards, but to take action to move toward them.

See dopamine is good for us, and it is why my New Year Resolution is so easy to do.

Side Effects: There have been some side effects I must disclose. My Resolution has caused me to: Lose weight, exercise more, eat better, made it easier to enjoy people. I never expected those results, all I wanted to do is make a resolution and stick with it. I like these side effects!

The Resolution: Now are you ready to know what this Resolution is? Okay, so at least once a day I must accomplish one or more of the following things:

  • Open a door for a stranger and smile at them
  • Compliment someone on their hair, clothes or smell (meaning if they have perfume on)
  • Smile at people when I’m in the store
  • Park at the back of a parking lot and walk to the store
  • Ask people about their day and listen to them
  • Send family or friends a nice text message “Just thinking of you and wishing you a happy day”
  • Write uplifting social media posts “start your day with a smile and brighten the world”
  • Be positive, it takes just as much work to be happy as it is to be sad

That’s it: Do nice things for others and you will see how great it makes you feel. As a bonus you are spreading a positive attitude to others and in a small way making the world a better place. Just give it a try, all it takes is *one* deed a day. Before you know it, you’ll be doing it all the time and reaping in the pleasant intoxicating feeling of dopamine. You will also notice that when you are feeling down or depressed, it is much easier to come out of the gloom.

 

I hope you have a successful and productive year. Let me know if you try this and how it goes for you.

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New Research May Explain the Origin of Complex Life on Earth

Researchers from the Wits University in South Africa have discovered an important step in the evolution of complex life on Earth. Their study shows how small non-living RNA molecules combined to form larger, self-replicating molecules.

 

Life remains one of the greatest and most beautiful mysteries of the universe. For one, it continues to baffle scientists that we only seem to have found life here on Earth and nowhere else in the vast expanse of space. For the time being, at least. The origins of life itself, from the simple to the complex, is a story of scientific wonder — one that is still being written today.

In a recent study published in the journal Royal Society Open Science, researchers from the Evolutionary Studies Institute at the University of the Witwaterstrand (Wits University), Johannesburg in South Africa discussed a discovery regarding how complex life evolved on Earth. “Life was a chance event, there is no doubt about that,” researcher Pierre Durand from the Evolution of Complexity Laboratory said in a press release.

This chance event Durand was referring to was that small strands of molecules linked up to form larger molecules capable of self-replication. Through a chemical reaction called ligation, simple RNA molecules join with other RNA molecules thanks to an enzyme they possessed. Supposedly, RNAs randomly connected with each other and replicated, thereby jump starting the process of life. “Molecular trade-offs in RNA ligases affected the modular emergence of complex ribozymes at the origin of life,” Durrand explained.

origin of life rna ligation complex life evolution
Image credit: Wits University

In their research, Durrand and his colleagues successfully demonstrated how it’s possible for small, non-living molecules to become larger molecules capable of reproducing themselves. This is a crucial step in a series of many that made it possible for life to evolve over a long period of time. “Something needed to happen for these small molecules to interact and form longer, more complex molecules and that happened completely by chance,” Durand added.

Even more surprising was how the smallest of these simple molecules (a 40-nucleotide RNA) was smaller than what the researchers expected. Nucleotides are the building blocks of nucleic acids, which in turn make up RNA and DNA. “The small molecules are very promiscuous and can join other pieces to themselves,” Durrand explained. “What was interesting was that these smaller molecules were smaller than we had originally thought.”

As our understanding of how complex life came to be continues to evolve, we learn more about what makes life possible. Furthermore, now that we know how complex life came to be on Earth, perhaps we’ll be better equipped to find life elsewhere. Whether complex life started on the oceans — as is widely accepted — or on land, what’s clear is that it started at a particular moment in Earth’s history.

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What Was the First Life on Earth?

By Stephanie Pappas, Live Science Contributor | February 19, 2017 08:33am ET

#Stromatolites, like those found in the World Heritage Area of Shark Bay, Western Australia, may contain #cyanobacteria, which were most likely Earth’s first photosynthetic organisms.

Credit: Rob Bayer/Shutterstock

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-year-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.

Prehistoric Van Goghs: Artists Used Pointillism 38,000 Years Ago

Nineteenth-century artists, such as Georges Seurat and Vincent van Gogh, weren’t the first to use pointillism, according to a discovery of 38,000-year-old decorated limestone tablets in France.

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.

The research team found 355 proteins shared by all archaeal and bacterial lineages. Based on those proteins, the researchers reconstructed a view of LUCA’s genome, hinting that it lived in an anaerobic (oxygen-free), hydrothermal environment. If that’s the case, Earth’s first life (or at least the first life that left descendants) would have resembled the microbes that cluster around deep-sea vents today, the researchers said.

Original article on Live Science

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An Expedition Is Heading to Antarctica to Uncover How Life Started on Our Planet

Scientists and researchers should be honored. The dedication these people have for finding the truth is simply humbling. Our reporters also play a major role in expressing those facts to the public and should also be honored. I thank all of them for what they do. The world does not need #alternatefacts. With that said, I do not edit or change the articles here. This site is meant only to place articles in one location.

 

The Origins of Life

A UK-led team from the University of Manchester is headed to Antartica in hopes of finding ‘lost’ meteorites that could provide clues to how life started on Earth. Meteorites give researchers an opportunity to study and understand how the solar system was formed. Iron meteorites, formed from the cores of planetesimals (small planets destroyed by planetary impact), could even give insight into how plants are created.

NASA

Because it is sheathed in snow and ice, the region provides a stark contrast for dark meteorites that end up on Earth. But to date, very few of these iron-based meteorites have been found. The team leading the expedition believes that more iron meteorites are somewhere just beneath the Antarctic surface –because of its composition, the ice melts faster around iron-rich rocks versus non-metallic meteorites, causing them to sink and get trapped under the ice.

This theory was enough to grant a team of researchers funding to develop some kind of advanced metal-detecting technology to be used in the first ever UK-led Antarctic meteorite expedition for 2020.

“[…] The continent constantly reveals so many secrets about our Earth such as our past climate from ice and sediment cores so it’s great to work with UK researchers to help them solve another puzzle about Earth’s, and our Solar System’s, formation,” said Professor David Vaughan, Director of Science at British Antarctic Survey, who will be working with the team.

Challenges Abound

The expedition will cover three different sites across the continent. What makes it particularly difficult is the distance of each site from the nearest research stations—meaning the team will have to conduct work amid freezing temperatures, and gale-force winds on a difficult terrain.

The team however, is looking forward to the challenge. Proposals for such an expedition premised on this hypothesis has been in discussion as far back as 2012.

“We now have the opportunity to commence on a truly exciting scientific adventure. If successful, our expeditions will help scientists to decode the origins of the Solar System and cement the UK as a leader in meteoritics and planetary science,” said Dr. Geoffrey Evatt who heads the team of multidisciplinary researchers preparing for the trek.

A preliminary visit to Antarctica is scheduled for 2019 where the team can study the terrain for their 2020 main expedition. Prior to this, a smaller, test mission will be conducted on the Arctic island of Svalbard, hopefully by 2018.

 Original Article: https://futurism.com/an-expedition-is-heading-to-antarctica-to-uncover-how-life-started-on-our-planet/

References: ScienceAlert – Latest, University of Manchester, Nature

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How Did the Solar System Form?

While this article does not specifically explain how “life” began on Earth, it does explain scientifically how our little solar system formed. No magic was involved. Only matter and gravity. Like everything in the universe, everything we see was made from star-stuff.
By Nola Taylor Redd, Space.com Contributor | January 31, 2017 10:16pm ET
How Did the Solar System Form?
Artist’s conception of Earth’s solar system (not to scale).

Credit: NASA/JPL

Approximately 4.5 billion years ago, gravity pulled a cloud of dust and gas together to form our solar system. While scientists aren’t certain of the exact nature of the process, observations of young stellar systems combined with computer simulations have allowed them to develop three models of what could have happened so many years ago.

Birth of the sun

A massive concentration of interstellar gas and dust created a molecular cloud that would form the sun’s birthplace. Cold temperatures caused the gas to clump together, growing steadily denser. The densest parts of the cloud began to collapse under its own gravity, forming a wealth of young stellar objects known as protostars. Gravity continued to collapse the material onto the infant object, creating a star and a disk of material from which the planets would form. When fusion kicked in, the star began to blast a stellar wind that helped clear out the debris and stopped it from falling inward.

Although gas and dust shroud young stars in visible wavelengths, infrared telescopes have probed many of the Milky Way Galaxy’s clouds to reveal the natal environment of other stars. Scientists have applied what they’ve seen in other systems to our own star.

After the sun formed, a massive disk of material surrounded it for around 100 million years. That may sound like more than enough time for the planets to form, but in astronomical terms, it’s an eye blink. As the newborn sun heated the disk, gas evaporated quickly, giving the newborn planets and moons only a short amount of time to scoop it up.

Formation models

Scientists have developed three different models to explain how planets in and out of the solar system may have formed. The first and most widely accepted model, core accretion, works well with the formation of the rocky terrestrial planets but has problems with giant planets. The second, pebble accretion, could allow planets to quickly form from the tiniest materials. The third, the disk instability method, may account for the creation of giant planets.

The core accretion model

Approximately 4.6 billion years ago, the solar system was a cloud of dust and gas known as a solar nebula. Gravity collapsed the material in on itself as it began to spin, forming the sun in the center of the nebula.

With the rise of the sun, the remaining material began to clump together. Small particles drew together, bound by the force of gravity, into larger particles. The solar wind swept away lighter elements, such as hydrogen and helium, from the closer regions, leaving only heavy, rocky materials to create terrestrial worlds. But farther away, the solar winds had less impact on lighter elements, allowing them to coalesce into gas giants. In this way, asteroids, comets, planets and moons were created.

Some exoplanet observations seem to confirm core accretion as the dominant formation process. Stars with more “metals” — a term astronomers use for elements other than hydrogen and helium — in their cores have more giant planets than their metal-poor cousins. According to NASA, core accretion suggests that small, rocky worlds should be more common than the more massive gas giants.

The 2005 discovery of a giant planet with a massive core orbiting the sun-like star HD 149026 is an example of an exoplanet that helped strengthen the case for core accretion.

“This is a confirmation of the core accretion theory for planet formation and evidence that planets of this kind should exist in abundance,” said Greg Henry in a press release. Henry, an astronomer at Tennessee State University, Nashville, detected the dimming of the star.

In 2017, the European Space Agency plans to launch the CHaracterising ExOPlanet Satellite (CHEOPS), which will study exoplanets ranging in sizes from super-Earths to Neptune. Studying these distant worlds may help determine how planets in the solar system formed.

“In the core accretion scenario, the core of a planet must reach a critical mass before it is able to accrete gas in a runaway fashion,” said the CHEOPS team. “This critical mass depends upon many physical variables, among the most important of which is the rate of planetesimals accretion.”

By studying how growing planets accrete material, CHEOPS will provide insight into how worlds grow.

The disk instability model

But the need for a rapid formation for the giant gas planets is one of the problems of core accretion. According to models, the process takes several million years, longer than the light gases were available in the early solar system. At the same time, the core accretion model faces a migration issue, as the baby planets are likely to spiral into the sun in a short amount of time.

“Giant planets form really fast, in a few million years,” Kevin Walsh, a researcher at the Southwest Research Institute (SwRI) in Boulder, Colorado, told Space.com. “That creates a time limit because the gas disk around the sun only lasts 4 to 5 million years.”

According to a relatively new theory, disk instability, clumps of dust and gas are bound together early in the life of the solar system. Over time, these clumps slowly compact into a giant planet. These planets can form faster than their core accretion rivals, sometimes in as little as 1,000 years, allowing them to trap the rapidly vanishing lighter gases. They also quickly reach an orbit-stabilizing mass that keeps them from death-marching into the sun.

As scientists continue to study planets inside of the solar system, as well as around other stars, they will better understand how gas giants formed.

Pebble accretion

The biggest challenge to core accretion is time — building massive gas giants fast enough to grab the lighter components of their atmosphere. Recent research probed how smaller, pebble-sized objects fused together to build giant planets up to 1,000 times faster than earlier studies.

“This is the first model that we know about that you start out with a pretty simple structure for the solar nebula from which planets form, and end up with the giant-planet system that we see,” study lead author Harold Levison, an astronomer at SwRI, told Space.com in 2015.

In 2012, researchers Michiel Lambrechts and Anders Johansen of Lund University in Sweden proposed that tiny pebbles, once written off, held the key to rapidly building giant planets.

“They showed that the leftover pebbles from this formation process, which previously were thought to be unimportant, could actually be a huge solution to the planet-forming problem,” Levison said.

Levison and his team built on that research to model more precisely how the tiny pebbles could form planets seen in the galaxy today. While previous simulations, both large and medium-sized objects consumed their pebble-sized cousins at a relatively constant rate, Levison’s simulations suggest that the larger objects acted more like bullies, snatching away pebbles from the mid-sized masses to grow at a far faster rate.

“The larger objects now tend to scatter the smaller ones more than the smaller ones scatter them back, so the smaller ones end up getting scattered out of the pebble disk,” study co-author Katherine Kretke, also from SwRI, told Space.com. “The bigger guy basically bullies the smaller one so they can eat all the pebbles themselves, and they can continue to grow up to form the cores of the giant planets.”

A Nice model

Originally, scientists thought that planets formed in the same part of the solar system they reside in today. The discovery of exoplanets shook things up, revealing that at least some of the most massive objects could migrate.

In 2005, a trio of papers published in the journal Nature proposed that the giant planets were bound in near-circular orbits much more compact than they are today. A large disk of rocks and ices surrounded them, stretching out to about 35 times the Earth-sun distance, just beyond Neptune’s present orbit. They called this the Nice model, after the city in France where they first discussed it.

As the planets interacted with the smaller bodies, they scattered most of them toward the sun. The process caused them to trade energy with the objects, sending the Saturn, Neptune, and Uranus farther out into the solar system. Eventually the small objects reached Jupiter, which sent them flying to the edge of the solar system or completely out of it.

Movement between Jupiter and Saturn drove Uranus and Neptune into even more eccentric orbits, sending the pair through the remaining disk of ices. Some of the material was flung inward, where it crashed into the terrestrial planets during the Late Heavy Bombardment. Other material was hurled outward, creating the Kuiper Belt.

As they moved slowly outward, Neptune and Uranus traded places. Eventually, interactions with the remaining debris caused the pair to settle into more circular paths as they reached their current distance from the sun.

Along the way, it’s possible that one or even two other giant planets were kicked out of the system. Astronomer David Nesvorny of SwRI has modeled the early solar system in search of clues that could lead toward understanding its early history.

“In the early days, the solar system was very different, with many more planets, perhaps as massive as Neptune, forming and being scattered to different places,” Nesvorny told Space.com

Water gatherers

The solar system didn’t wrap up its formation process after the planets formed. Earth stands out from the planets because of its high water content, which many scientists suspect contributed to the evolution of life. But the planet’s current location was too warm for it to collect water in the early solar system, suggesting that the life-giving liquid may have been delivered after it was grown.

But scientists still don’t know the source of that water. Originally, they suspected comets, but several missions, including six that flew by Halley’s comet in the 1980s and the more recent European Space Agency’s Rosetta satellite, revealed that the composition of the icy material from the outskirts of the solar system didn’t quite match Earth’s.

The asteroid belt makes another potential source of water. Several meteorites have shown evidence of alteration, changes made early in their lifetimes that hint that water in some form interacted with their surface. Impacts from meteorites could be another source of water for the planet.

Recently, some scientists have challenged the notion that the early Earth was too hot to collect water. They argue that, if the planet formed fast enough, it could have collected the necessary water from the icy grains before they evaporated.

While Earth held onto its water, Venus and Mars would have likely been exposed to the important liquid in much the same way. Rising temperatures on Venus and an evaporating atmosphere on Mars kept them from retaining their water, however, resulting in the dry planets we know today.

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Black Holes Regurgitate ‘Spitballs’ After Devouring Stars

After a black hole devours a star, it shoots out planet-size "spitballs" that can approach within a few hundred light-years of Earth.

After a black hole devours a star, it shoots out planet-size “spitballs” that can approach within a few hundred light-years of Earth.

I’ve put this under the category of “Something from Nothing”, which I know may get some blow-back from people, so let me explain. The beginning of the Theory began in 1687 when Sir Isaac Newton described gravity in his publication, “Principia.” The religious minds of the day scoffed at this. How can something be nothing? How can something come from nothing?

Well, because of science we know that a black hole is something but for the longest time we couldn’t see anything. For years I would speak to religious folks and they have always demanded from me that something cannot come from nothing. I would ask if they could see a black hole. No, they would say. So they agreed that there was nothing there. My long standing opinion was black holes could cough up material which constitutes as something from nothing.

For the last several years I have been proven correct. Black holes do regurgitate material. A black hole certainly is something, its not nothing, but to the human eye it is nothing from which something emerges.

On with the article:

 

When a black hole devours a star, it spews planet-size “spitballs” of regurgitated gas tumbling through the galaxy — and some of these globs can come within a few hundred light-years of Earth, new research shows.

Supermassive black holes lie at the center of almost every galaxy, including the Milky Way. The massive cosmic bodies have a powerful gravitational force that pulls in nearby wandering stars, tears them to shreds and, as a result, spews out a stream of hot gas that can clump together to form planet-size objects, according to a statement from the Harvard-Smithsonian Center for Astrophysics (CfA).

“A single shredded star can form hundreds of these planet-mass objects,” Eden Girma, an undergraduate student at Harvard University and lead author of the study, said in the statement. “We wondered: Where do they end up? How close do they come to us? We developed a computer code to answer those questions.” [Images: Black Holes of the Universe]

 

The researchers found that these “spitballs,” whose closest emissaries might reach within a few hundred light-years of Earth, weigh as much as several Jupiters. However, the objects are very different from planets, as they are made solely of leftover star material and form much more rapidly.

“It takes only a day for the black hole to shred the star (in a process known as tidal disruption) and only about a year for the resulting fragments to pull themselves back together,” CfA researchers said in the statement. “This is in contrast to the millions of years required to create a planet like Jupiter from scratch.”

The “spitballs” travel at speeds of about 20 million mph (32 million km/h), and would therefore take roughly a million years to reach Earth’s neighborhood after being launched from a black hole, officials said in the release. However, most of them leave our galaxy entirely; the researchers estimated that almost 95 percent of them would be propelled to other galaxies, where similar tidal-disruption processes are thought to exist.

“Other galaxies, like Andromeda, are shooting these ‘spitballs’ at us all the time,” study co-author James Guillochon, an astrophysicist at the CfA, said in the statement.

Scientists plan to survey the “spitballs” in the future using instruments such as the Large Synoptic Survey Telescope (currently under construction in Chile) and the James Webb Space Telescope (set to launch in 2018), which will have a better chance of detecting the faint glow of the objects hurtling through space. However, it will still be difficult to distinguish a cosmic “spitball” from free-floating planets, the researchers noted.

“Only about one out of a thousand free-floating planets will be one of these second-generation oddballs,” Girma said in the statement.

 

Girma presented the study findings at the 229th meeting of the American Astronomical Society, held Jan. 3 to Jan. 7 in Grapevine, Texas.

Follow Samantha Mathewson @Sam_Ashley13. Follow us @Spacedotcom, Facebook and Google+. Original article on Space.com.

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Abiogenesis: Life May Have Evolved From Non-Living Matter With Relative Ease

More evidence that life could have evolved with relative ease: New research supports ancestors of genes self-copying in a mushy puddle

Oct 10, 2016 | Atlanta, GA

The original recipe for gene soup may have been simple — rain, a jumble of common molecules, warm sunshine, and nighttime cooling. Then add a pinch of thickener. That last ingredient may have helped gene-like strands to copy themselves in puddles for the first time ever, billions of years ago when Earth was devoid of life, researchers at the Georgia Institute of Technology have found. Their novel discoveries add to a growing body of evidence that suggests first life may have evolved with relative ease, here and possibly elsewhere in the universe. And they offer a straightforward answer to a gnawing 50-year-old question: How did precursors to the present-day genetic code first duplicate themselves before the existence of enzymes that are indispensable to that process today?

 

The spice of life?

For generations, scientists pursuing an answer performed experiments in water but hit a wall. Georgia Tech researchers Christine He and Isaac Gállego overcame it by adding an off-the-shelf viscous solvent (the thickener). In separate experiments with DNA then RNA, the copying process proceeded. “I think it’s very, very different from anything that’s been done before,” said researcher He. “We can change the physical environment in an easy way, and promote these processes that wouldn’t happen in conditions ordinarily being used.”

 

Easy recipe

Easy is crucial, said Martha Grover, a professor who oversaw the research at Georgia Tech’s School of Chemical and Biomolecular Engineering. Easy reactions are likely to be more productive and more prevalent. “A simple and robust process like this one could have operated in a variety of environments and concentrations making it more realistic in moving evolution forward,” she said. Grover’s lab and that of Nick Hud at Georgia Tech’s School of Chemistry and Biochemistry published the results on Monday, October 10, 2016 in the journal Nature Chemistry. Their research has been funded by the National Science Foundation and the NASA Astrobiology Program under the NASA/NSF Center for Chemical Evolution.

 

Nucleotide noodles

Earliest life was based on RNA, or a similar polymer, according to a hypothesis called the RNA World. In that scenario, on the evolutionary timeline, the self-replication of RNA strands long enough to be potential genes would roughly mark the doorstep to life. Those long nucleotide chains may have been mixed together in puddles with shorter nucleotide chains. Heat from the sun would have made long strands detach from their helix structures, giving short ones a chance to match up with them, and become their copies.

But there’s a problem.

In water alone, when cooling sets in, the long chains snap back into their helix structure so rapidly that there’s no time for the matching process with the shorter chains. That snapping shut, which happens in both RNA and DNA, is called “strand inhibition,” and in living cells, enzymes solve the problem of keeping the long chains apart while gene strands duplicate.

 

More like a stew

“The problem is a problem in water, which everybody sort of looks at in prebiotic (pre-life) chemistry,” said graduate research assistant He. She felt it was time to rethink that, and her expertise in chemical engineering helped. High viscosity has been known to slow down the movement of long strands of DNA, RNA and other polymers. “It’s a little like making them swim in honey,” Grover said. Applying that to origin-of-life chemistry seemed obvious, because in prebiotic times, there probably were quite a few sticky puddles. “In that solution, it gives the short nucleotides, which move faster, time to jump onto the long strand and piece together a duplicate of the long strand,” researcher He said. In her experiments, it worked.

 

Hairpins in the soup

And it produced an encouraging surprise. The DNA and RNA strands folded onto themselves forming shapes called hairpins. “In the beginning, we didn’t realize the importance of the internal structure,” Christine He said. Then they noticed that the shape was helping keep RNA and DNA available for the pairing process. “Hairpin formation is integral to keeping them open,” Grover said. But it also could have accelerated chemical evolution in another way.  “The solution is selecting here for sequences that fold, and that would have more potential for functional activity – like a ribozyme,” said researcher He.

Ribozymes are enzymes made of RNA, and enzymes catalyze biochemical processes. To have them evolve in the same solution that promotes genetic code replication could have shortened the path to first life. “You really need to amplify functional sequences for evolution to move forward,” Grover said. The folds were an unexpected side-effect, and finding them paves the way for future research.

 

Next ingredient?

The Georgia Tech scientists used real gene strands in their experiments, which may sound mundane, but in the past, some researchers have specially engineered DNA and RNA sequences in attempts to arrive at similar results. He and Gállego’s use of a naturally occurring gene, rather than a specifically engineered sequence, shows that viscosity could have been a very general solution to promote copying of nucleic acids with mixed length and sequences.

To facilitate quick, clear outcomes, the Georgia Tech researchers used purified short nucleotide chains and applied them in ratios that favored productive reactions. But they had started out with messier, less pure ingredients, and the experience was worthwhile. “Considering a pre-biotic soup, it’s probably messy; it’s got a lot of impurities,” Christine He said. “When we first started out with more impure nucleotides, it still worked. Maybe the same reaction really could have happened in a messy puddle billions of years ago.”

The viscous solvent was glycholine, a mixture of glycerol and choline chloride. It was not likely present on pre-biotic Earth, but other viscous solvents likely were. Also, after the short strands matched up to each long one, the researchers did apply an enzyme to join the aligned short pieces into a long chain, in a biochemical process called ligation. The enzymes would not have been present on a prebiotic Earth, and although there are chemical procedure for ligating RNA, “no one has developed a chemistry so robust yet that it could replace the enzyme,” Grover said.

 

Finding one that could have worked on a prebiotic Earth would be a worthy aim for further research.

READ: More about chemical engineering, viscosity and DNA

READ: Possible precusor of RNA forms spontaneously in water

 

Brandon Laughlin from Georgia Tech coauthored the paper. The research was funded by the National Science Foundation and the NASA Astrobiology Program under the NASA/NSF Center for Chemical Evolution (grant number CHE-1504217) and by the NSF Graduate Research Fellowship (grant number DGE-1148903). Any opinions, findings and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the sponsoring agencies.

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Scientists Close to Uncovering RNA Mystery

Moving Backward to Go Forward

DNA, RNA, and protein: these have been the premier scientific buzzwords in our lives since we picked up our first science textbooks in elementary school. However, there was always one thing that the science textbook never really got around to explaining: what came first the chicken or the egg? Or in our case, RNA or protein?

Scientists at The Scripps Research Institute (TSRI) have taken steps to answer the long-standing question to verify the validity of the RNA world hypothesis. The Museum of Science explains that according to the RNA World Hypothesis, “earlier forms of life may have relied solely on RNA to store genetic information and to catalyze chemical reactions. Later life evolved to use DNA and proteins due to RNA’s relative instability and poorer catalytic properties, and gradually, ribozymes became increasingly phased out.”

In short, to test this, the team has decided to build their own biological time machine to take them back 4 billion years—all by synthesizing a primordial RNA-based enzyme, a ribozyme, that has never been seen before.

The team of scientist sought to verify the two major tenets of the RNA world hypothesis:

  1. The ribozyme must be able to replicate RNA.
  2. The ribozyme must be able to transcribe RNA.

Here is a brief video describing both replication and transcription from a DNA perspective:

A Primordial Hunger Games

The scientists employed natural selection in their process to uncover evidence for the RNA world hypothesis. Building upon decades of research, the researchers made over 100 trillion variants of the class I RNA polymerase ribozyme, a molecule that theoretically could replicate and transcribe RNA.

After twenty-four rounds of experiments, the TSRI team stumbled upon polymerase ribozyme 24-3, which was able to replicate and transcribe RNA better than the team had hoped. With the new molecule synthesizing RNA molecules at a rate that is one hundred times quicker than the original start molecule, and replicating at a rate deemed as exponential replication, with forty thousand copies produced in just 24 hours.

The scientists believe that “a  polymerase ribozyme that achieves exponential amplification of itself will meet the criteria for being alive.” Providing support for the RNA world hypothesis.

Now that’s one for both history and science textbooks.

The article was published in the Proceedings of the National Academy of Sciences

Source: Phys.org

 

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