In The Works, #veshaceleste #authored By #sciencefictionfantasy #writer #matthewopdyke And #narrator

Pathway to the Stars: Part 9, Allure & Spacecraft "We cannot engage in human progression as solo artists, alone, and expect long-term and optimal results. While we can inspire momentum for a time, while working diligently, ultimately the laws of chaos will prevail unless we work together to preserve our world, our solar system, and our Universe." ~ Eliza Williams Vesha has completed her Virtual Universe training, and now she becomes immersed in missions and callings as never before! Enjoy as she tackles issues where society seems muddled in the chains of self-bondage, rather than moving forward with a bright and beautiful future for all. Joanne revisits a problem that can affect Eliza Williams' hopes for the future. Among Eliza's many goals within the Solar System to that end, related to space travel, is the construction of spacecraft being built just above Pluto! Enjoy this Space Opera as Eliza continues her quest to nurture humanity into a space-faring, world-preserving, and Universe-exploring civilization! She believes that the most significant step toward moving forward is kindness, and that kindness is the greatest strength we have! ISBN: 978-1951321093 LCCN: 2019918425eBook: https://smile.amazon.com/dp/B081XLG9JV Paperback: https://smile.amazon.com/dp/195132109X For more info: https://www.mjopublications.com https://smile.amazon.com/author/matthewopdyke Tags: #sciencefiction #scifi #spaceopera #fantasy #stem #astronomy #sentience #spacecraft #spaceelevator #wellbeing #author #matthewjopdyke #ebook #paperback #amazon

Largest Batch of Earth-size, Habitable Zone Planets

Our Spitzer Space Telescope has revealed the first known system of seven Earth-size planets around a single star. Three of these planets are firmly located in an area called the habitable zone, where liquid water is most likely to exist on a rocky planet.

This exoplanet system is called TRAPPIST-1, named for The Transiting Planets and Planetesimals Small Telescope (TRAPPIST) in Chile. In May 2016, researchers using TRAPPIST announced they had discovered three planets in the system.

Assisted by several ground-based telescopes, Spitzer confirmed the existence of two of these planets and discovered five additional ones, increasing the number of known planets in the system to seven.

This is the FIRST time three terrestrial planets have been found in the habitable zone of a star, and this is the FIRST time we have been able to measure both the masses and the radius for habitable zone Earth-sized planets.

All of these seven planets could have liquid water, key to life as we know it, under the right atmospheric conditions, but the chances are highest with the three in the habitable zone.

At about 40 light-years (235 trillion miles) from Earth, the system of planets is relatively close to us, in the constellation Aquarius. Because they are located outside of our solar system, these planets are scientifically known as exoplanets. To clarify, exoplanets are planets outside our solar system that orbit a sun-like star.

In this animation, you can see the planets orbiting the star, with the green area representing the famous habitable zone, defined as the range of distance to the star for which an Earth-like planet is the most likely to harbor abundant liquid water on its surface. Planets e, f and g fall in the habitable zone of the star.

Using Spitzer data, the team precisely measured the sizes of the seven planets and developed first estimates of the masses of six of them. The mass of the seventh and farthest exoplanet has not yet been estimated.

For comparison…if our sun was the size of a basketball, the TRAPPIST-1 star would be the size of a golf ball.

Based on their densities, all of the TRAPPIST-1 planets are likely to be rocky. Further observations will not only help determine whether they are rich in water, but also possibly reveal whether any could have liquid water on their surfaces.

The sun at the center of this system is classified as an ultra-cool dwarf and is so cool that liquid water could survive on planets orbiting very close to it, closer than is possible on planets in our solar system. All seven of the TRAPPIST-1 planetary orbits are closer to their host star than Mercury is to our sun.

 The planets also are very close to each other. How close? Well, if a person was standing on one of the planet’s surface, they could gaze up and potentially see geological features or clouds of neighboring worlds, which would sometimes appear larger than the moon in Earth’s sky.

The planets may also be tidally-locked to their star, which means the same side of the planet is always facing the star, therefore each side is either perpetual day or night. This could mean they have weather patterns totally unlike those on Earth, such as strong wind blowing from the day side to the night side, and extreme temperature changes.

Because most TRAPPIST-1 planets are likely to be rocky, and they are very close to one another, scientists view the Galilean moons of Jupiter – lo, Europa, Callisto, Ganymede – as good comparisons in our solar system. All of these moons are also tidally locked to Jupiter. The TRAPPIST-1 star is only slightly wider than Jupiter, yet much warmer. 

How Did the Spitzer Space Telescope Detect this System?

Spitzer, an infrared telescope that trails Earth as it orbits the sun, was well-suited for studying TRAPPIST-1 because the star glows brightest in infrared light, whose wavelengths are longer than the eye can see. Spitzer is uniquely positioned in its orbit to observe enough crossing (aka transits) of the planets in front of the host star to reveal the complex architecture of the system. 

Every time a planet passes by, or transits, a star, it blocks out some light. Spitzer measured the dips in light and based on how big the dip, you can determine the size of the planet. The timing of the transits tells you how long it takes for the planet to orbit the star.

The TRAPPIST-1 system provides one of the best opportunities in the next decade to study the atmospheres around Earth-size planets. Spitzer, Hubble and Kepler will help astronomers plan for follow-up studies using our upcoming James Webb Space Telescope, launching in 2018. With much greater sensitivity, Webb will be able to detect the chemical fingerprints of water, methane, oxygen, ozone and other components of a planet’s atmosphere.

At 40 light-years away, humans won’t be visiting this system in person anytime soon…that said…this poster can help us imagine what it would be like: 

Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com

I love this kind of news!

“Voyager Spacecraft Fires Up Thrusters for First Time Since 1980”

 NASA scientists have recently fired up the thrusters on the Voyager 1 Spacecraft - the farthest spacecraft from Earth - in an effort to reorient its antenna towards Earth.  Originally, scientists would have used the attitude control thrusters aboard the spacecraft to make the adjustments, however these have been wearing out during the voyage. Instead, NASA scientists tried using Voyager’s ‘trajectory correction maneuver’ thrusters, located on the back side of the spacecraft.  Since these hadn’t been fired in 27 years, engineers were thrilled when they received an answer 19 hours and 35 minutes later that the four thrusters had worked perfectly.  "The Voyager team got more excited each time with each milestone in the thruster test. The mood was one of relief, joy and incredulity after witnessing these well-rested thrusters pick up the baton as if no time had passed at all,“ said Todd Barber, a propulsion engineer at NASA’s Jet Propulsion Laboratory in Pasadena, California.

Read more about this fascinating story at: http://www.cnn.com/2017/12/01/us/voyager-1-thrusters-fired-first-time-since-1980/index.html

Image Credit: NASA, ESA, and G. Bacon (STScl)

What are white dwarfs?

Some curiosities about white dwarfs, a stellar corpse and the future of the sun.

Where a star ends up at the end of its life depends on the mass it was born with. Stars that have a lot of mass may end their lives as black holes or neutron stars.

A white dwarf is what stars like the Sun become after they have exhausted their nuclear fuel. Near the end of its nuclear burning stage, this type of star expels most of its outer material, creating a planetary nebula.

In 5.4 billion years from now, the Sun will enter what is known as the Red Giant phase of its evolution. This will begin once all hydrogen is exhausted in the core and the inert helium ash that has built up there becomes unstable and collapses under its own weight. This will cause the core to heat up and get denser, causing the Sun to grow in size.

It is calculated that the expanding Sun will grow large enough to encompass the orbit’s of Mercury, Venus, and maybe even Earth.

A typical white dwarf is about as massive as the Sun, yet only slightly bigger than the Earth. This makes white dwarfs one of the densest forms of matter, surpassed only by neutron stars and black holes.

The gravity on the surface of a white dwarf is 350,000 times that of gravity on Earth. 

White dwarfs reach this incredible density because they are so collapsed that their electrons are smashed together, forming what is called “degenerate matter.” This means that a more massive white dwarf has a smaller radius than its less massive counterpart. Burning stars balance the inward push of gravity with the outward push from fusion, but in a white dwarf, electrons must squeeze tightly together to create that outward-pressing force. As such, having shed much of its mass during the red giant phase, no white dwarf can exceed 1.4 times the mass of the sun.

While many white dwarfs fade away into relative obscurity, eventually radiating away all of their energy and becoming a black dwarf, those that have companions may suffer a different fate.

If the white dwarf is part of a binary system, it may be able to pull material from its companion onto its surface. Increasing the mass can have some interesting results.

One possibility is that adding more mass to the white dwarf could cause it to collapse into a much denser neutron star.

A far more explosive result is the Type 1a supernova. As the white dwarf pulls material from a companion star, the temperature increases, eventually triggering a runaway reaction that detonates in a violent supernova that destroys the white dwarf. This process is known as a single-degenerate model of a Type 1a supernova. 

If the companion is another white dwarf instead of an active star, the two stellar corpses merge together to kick off the fireworks. This process is known as a double-degenerate model of a Type 1a supernova.

At other times, the white dwarf may pull just enough material from its companion to briefly ignite in a nova, a far smaller explosion. Because the white dwarf remains intact, it can repeat the process several times when it reaches the critical point, briefly breathing life back into the dying star over and over again. 

Image credit: www.aoi.com.au/ NASA/ ESA/ Hubble/  Wikimedia Commons/ Fsgregs/ quora.com/ quora.com/ NASA’s Goddard Space Flight Center/S. Wiessinger/ ESO/ ESO/ Chandra X-ray Observatory

Source: NASA/ NASA/ space.com

Wow, quite a career!

Ever want to ask a real life astronaut a question? Here’s your chance!

Astronaut Jeanette Epps will be taking your questions in an Answer Time session on Friday, May 5 from 10am - 11am ET here on NASA’s Tumblr. See the questions she’s answered by visiting nasa.tumblr.com/tagged/answertime!

NASA astronaut Jeanette J. Epps (Ph.D.) was selected as an astronaut in 2009. She has been assigned to her first spaceflight, which is scheduled to launch in May 2018. Her training included scientific and technical briefings, intensive instruction in International Space Station systems, spacewalk training, robotics, T‐38 flight training and wilderness survival training.

Before becoming an astronaut, Epps worked as a Technical Intelligence Officer at the Central Intelligence Agency (CIA).

Born in Syracuse, New York. Enjoys traveling, reading, running, mentoring, scuba diving and family.

She has a Bachelor of Science in Physics from LeMoyne College, as well as a Master of Science and Doctorate of Philosophy in Aerospace Engineering from the University of Maryland. 

Follow Jeanette on Twitter at @Astro_Jeanette and follow NASA on Tumblr for your regular dose of space.

Pathway to the Stars: Part 11, A New Day

"If we can love ourselves, we can then truly understand what it means to love others and be kind. There is potential that lies within you and everyone else. It is a potential that has always been meant to exist, to bring something greater to this reality of life."

~ Sky Taylor

This story is the eleventh of the Pathway to the Stars space opera series. Sky journeys with Erin Carter and Joanne Gallant, who are now Pathway's president and vice president. On their adventure, she shows them ways to heal the Earth as well as ourselves so we can promote a healthier form of longevity.

To Sky, there is much we can do to prevent future disasters, but sometimes solutions can involve something as simple as a nice walk. In this case, unfortunately, to help Joanne figure out a mystery weighing upon her.

Meanwhile, Eliza Williams and Yesha Alevtina work for the success of the Universal Party with efforts that will affect the United States, the World, and the mission to span the Cosmos!

LCCN: 2019919255

ISBN: 978-1-951321-15-4

eBook: https://smile.amazon.com/dp/B081XNYSL4

Paperback: https://smile.amazon.com/dp/1951321154

#ScienceFiction #Scifi #SpaceOpera #Fantasy #Author #MatthewJOpdyke #EarthFirst #Preservation #ConsiderationForAllLiving #Biology #Neuroscience #Biotechnology #AI #HBCI

No matter what people tell you, words and ideas can change the world.

http://www.brainyquote.com/quotes/authors/r/robin_williams.html

Jupiter and Saturn appear to the naked eye as a single star, dubbed the "Christmas Star," last seen 800 years ago. Viewed from my deck. 🤩 #christmasstar #jupitersaturnconjunction https://www.instagram.com/p/CJFbSF2rMPv/?igshid=tz61xuv73023

Interesting facts about stars

Stars are giant, luminous spheres of plasma. There are billions of them — including our own sun — in the Milky Way Galaxy. And there are billions of galaxies in the universe. So far, we have learned that hundreds also have planets orbiting them.

1. Stars are made of the same stuff

All stars begin from clouds of cold molecular hydrogen that gravitationally collapse. As they cloud collapses, it fragments into many pieces that will go on to form individual stars. The material collects into a ball that continues to collapse under its own gravity until it can ignite nuclear fusion at its core. This initial gas was formed during the Big Bang, and is always about 74% hydrogen and 25% helium. Over time, stars convert some of their hydrogen into helium. That’s why our Sun’s ratio is more like 70% hydrogen and 29% helium. But all stars start out with ¾ hydrogen and ¼ helium, with other trace elements.

2. Most stars are red dwarfs

If you could collect all the stars together and put them in piles, the biggest pile, by far, would be the red dwarfs. These are stars with less than 50% the mass of the Sun. Red dwarfs can even be as small as 7.5% the mass of the Sun. Below that point, the star doesn’t have the gravitational pressure to raise the temperature inside its core to begin nuclear fusion. Those are called brown dwarfs, or failed stars. Red dwarfs burn with less than 1/10,000th the energy of the Sun, and can sip away at their fuel for 10 trillion years before running out of hydrogen.

3. Mass = temperature = color

The color of stars can range from red to white to blue. Red is the coolest color; that’s a star with less than 3,500 Kelvin. Stars like our Sun are yellowish white and average around 6,000 Kelvin. The hottest stars are blue, which corresponds to surface temperatures above 12,000 Kelvin. So the temperature and color of a star are connected. Mass defines the temperature of a star. The more mass you have, the larger the star’s core is going to be, and the more nuclear fusion can be done at its core. This means that more energy reaches the surface of the star and increases its temperature. There’s a tricky exception to this: red giants. A typical red giant star can have the mass of our Sun, and would have been a white star all of its life. But as it nears the end of its life it increases in luminosity by a factor of 1000, and so it seems abnormally bright. But a blue giant star is just big, massive and hot.

4. Most stars come in multiples

It might look like all the stars are out there, all by themselves, but many come in pairs. These are binary stars, where two stars orbit a common center of gravity. And there are other systems out there with 3, 4 and even more stars. Just think of the beautiful sunrises you’d experience waking up on a world with 4 stars around it.

5. The biggest stars would engulf Saturn

Speaking of red giants, or in this case, red supergiants, there are some monster stars out there that really make our Sun look small. A familiar red supergiant is the star Betelgeuse in the constellation Orion. It has about 20 times the mass of the Sun, but it’s 1,000 times larger. But that’s nothing. The largest known star is the monster UY Scuti.  It is a current and leading candidate for being the largest known star by radius and is also one of the most luminous of its kind. It has an estimated radius of 1,708 solar radii (1.188×109 kilometres; 7.94 astronomical units); thus a volume nearly 5 billion times that of the Sun.

6. There are many, many stars

Quick, how many stars are there in the Milky Way. You might be surprised to know that there are 200-400 billion stars in our galaxy. Each one is a separate island in space, perhaps with planets, and some may even have life.

7. The Sun is the closest star

Okay, this one you should know, but it’s pretty amazing to think that our own Sun, located a mere 150 million km away is average example of all the stars in the Universe. Our own Sun is classified as a G2 yellow dwarf star in the main sequence phase of its life. The Sun has been happily converting hydrogen into helium at its core for 4.5 billion years, and will likely continue doing so for another 7+ billion years. When the Sun runs out of fuel, it will become a red giant, bloating up many times its current size. As it expands, the Sun will consume Mercury, Venus and probably even Earth. 

8. The biggest stars die early

Small stars like red dwarfs can live for trillions of years. But hypergiant stars, die early, because they burn their fuel quickly and become supernovae. On average, they live only a few tens of millions of years or less.

9. Failed stars

Brown dwarfs are substellar objects that occupy the mass range between the heaviest gas giant planets and the lightest stars, of approximately 13 to 75–80 Jupiter masses (MJ). Below this range are the sub-brown dwarfs, and above it are the lightest red dwarfs (M9 V). Unlike the stars in the main-sequence, brown dwarfs are not massive enough to sustain nuclear fusion of ordinary hydrogen (1H) to helium in their cores.

10. Sirius: The Brightest Star in the Night Sky

Sirius is a star system and the brightest star in the Earth’s night sky. With a visual apparent magnitude of −1.46, it is almost twice as bright as Canopus, the next brightest star. The system has the Bayer designation Alpha Canis Majoris (α CMa). What the naked eye perceives as a single star is a binary star system, consisting of a white main-sequence star of spectral type A0 or A1, termed Sirius A, and a faint white dwarf companion of spectral type DA2, called Sirius B. 

To know more click the links: white dwarf, supernova, +stars, pulsars

sources: wikipedia and universetoday.com

image credits: NASA/JPL, Morgan Keenan, ESO, Philip Park / CC BY-SA 3.0

Great post! #NASA #solarpower #solarsystem #spaceexploration

NASA sending solar power generator developed at Ben-Gurion U to space station

A new solar power generator prototype developed by Ben-Gurion University of the Negev (BGU) and research teams in the United States, will be deployed on the first 2020 NASA flight launch to the International Space Station.

According to research published in Optics Express, the compact, microconcentrator photovoltaic system could provide unprecedented watt per kilogram of power critical to lowering costs for private space flight.

As the total costs of a launch are decreasing, solar power systems now represent a larger fraction than ever of total system cost. Optical concentration can improve the efficiency and reduce photovoltaic power costs, but has traditionally been too bulky, massive and unreliable for space use.

Together with U.S. colleagues, Prof. (Emer.) Jeffrey Gordon of the BGU Alexandre Yersin Department of Solar Energy and Environmental Physics, Jacob Blaustein Institutes for Desert Research, developed this first-generation prototype (1.7 mm wide) that is slightly thicker than a sheet of paper (.10 mm) and slightly larger than a U.S. quarter.

“These results lay the groundwork for future space microconcentrator photovoltaic systems and establish a realistic path to exceed 350 w/kg specific power at more than 33% power conversion efficiency by scaling down to even smaller microcells,” the researchers say. “These could serve as a drop-in replacement for existing space solar cells at a substantially lower cost.”

A second generation of more efficient solar cells now being fabricated at the U.S. Naval Research Labs is only 0.17 mm per side, 1.0 mm thick and will increase specific power even further. If successful, future arrays will be planned for private space initiatives, as well as space agencies pursuing new missions that require high power for electric propulsion and deep space missions, including to Jupiter and Saturn.