A Cosmic Legacy: From Earth To The Stars (Extended Video)
A Cosmic Legacy: From Earth to the Stars (Extended Video)
"Our beautiful mother world ached for a reprieve from the injustices of many, courtesy of cultures and governance systems, that forgot how to love, how to be kind, how to include others, and how to think beyond the scope of greed and power, but within the visions of shared joy and well-being."
“For far too long people have lived for merely one shared goal, due to the daunting nature that life seems to bring. That goal may be a noble one, but it comes short of progression in and of itself and does not recognize the complexity of life and all of its nuances.
“This goal is survival through natural evolution. To merely survive, no matter the means, as noble as it may seem at first, will actually lead to the end of life and the end of humanity, whether through natural events or mankind’s apparent affinity toward death.
“It’s as if far too many people worship the almighty ‘mixed result’ rather than raise the quality of and joy in life through logic, study, innovation, and common sense, by enjoying what it can bring to the table, which will ultimately result in desired results.
“Finding cures for disease, both physiological and neurological, and possessing the ingenuity to innovate technologies as well as a pathway for humanity to quicken their pace for developing them will lead to preserving our Earth, our solar system, perhaps our Universe, and with it, each individual and humanity itself, as we travel to and push the limits of the Universe and its sustainability, trusting ourselves as we do so.”
Enjoy this First-Year-Anniversary compilation of all of my works in one title: A Cosmic Legacy: From Earth to the Stars
This title includes the entire Pathway to the Stars series: Part 1, Vesha Celeste Part 2, Eliza Williams Part 3, James Cooper Part 4, Universal Party Part 5, Amber Blythe Part 6, Erin Carter Part 7, Span of Influence Part 8, Dreamy & Deep Part 9-Allure & Spacecraft Part 10-Sky Taylor Part 11-A New Day Part 12-Alpha Andromedae
Eliza Williams and a host of friendly heroes tackle some of the most significant dilemmas of the day to bring humanity out and into the stars bearing a legacy we would be proud to share with other civilizations--a legacy of kindness, of mind-to-mind communication, of love, and of healing instead of harming. If we are to overcome the great expansion and the death of all life, we must overcome the smaller challenges to progress and focus on even greater ones. Working with her team diligently, Eliza will speed the pace of society in her world with the belief that beauty and untold potential are within every being. If we find ways to bring that out in ourselves and others, a future where we can breed longevity, a collective and high quality of life, augment the clarity of our minds, and innovate to span the Cosmos may be in our grasp.
Together with the organization Eliza Williams founded, called Pathway, she and her growing team will take us on a fantastical and Utopian journey to get us out and into the farthest reaches of space. There are dilemmas such as the physiological effects of space on each of us, as well as the need for longevity and a desire to still be able to visit loved ones following long journeys. Eliza and her team develop capabilities, so we can overcome the challenges ahead and are determined to stabilize a rocky economy, wipe away suffering, violence, disease, cartels, terrorism, and trafficking in persons. They work together to tame seismic activity, weather, and fires. She and her friends tackle ways to prevent extinction and provide solutions to quality of life concerns. They even consider the longevity of our Sun and our Earth's capacity to preserve life. Eliza tackles each of these issues to get us out, and into the stars, so we can begin our biggest quest--to help our Universe breathe ever so lightly.
No matter the challenge, there will always be greater pursuits! The saga will continue...
"A Cosmic Legacy" is a science fiction & fantasy novel, with a Space Opera flair to it. It is designed to edify, educate, and entertain young adults and scholars alike. Some of the specific topics covered include physiology, neurology, physics, biotechnology, nanotechnology, astronomy, politics, philosophy, and ethics. Preservation of the life-giving and sustaining capacities of our Earth and creation of environments conducive to life throughout the Solar System once thought to be impossible are primary goals. The ideas of kindness, with innovation rooted in well-being, longevity, where cellular health expresses youth and rejuvenation, optimizing the body to be able to live comfortably in austere space environments without adverse effects, and mind-to-mind communication bearing with it a legacy we'd be proud to share with distant civilizations with mutual goals of preserving our Universe can bring a beautiful future for all living beings.
Hardcover (Regular price $45) LCCN: 2019911854 | ISBN: 978-1-7333131-2-4 https://smile.amazon.com/dp/1733313125
Paperback (Regular price $35) LCCN: 2019909638 | ISBN: 978-1-7333131-1-7 https://smile.amazon.com/dp/1733313117
eBook (Regular price $10) LCCN: 2019909630 | ISBN: 978-1-7333131-0-0 | ASIN: B07V4W3MW9 https://smile.amazon.com/dp/B07V4W3MW9
#scifi #fantasy #spaceopera #newideology #wellbeing #longevity #neuroscience #neurotech #physiology #biology #biotech #physics #theoreticalphysics #nanotech #CRISPR #stemcellresearch #innovation #positivity #clarityofmind #author #matthewjopdyke #books #novels #ebooks #space #stars #astronomy #stem #science #ethicalrolemodels #universalethics
More Posts from Matthewjopdyke and Others
30 years after the detection of SN1987A neutrinos
On February 23, 1987, just before 30 years from today, the neutrinos emitted from the supernova explosion SN1987A in the Large Magellanic Cloud, approximately 160,000 light-years away, reached the earth. Kamiokande, the predecessor detector of Super-Kamiokande, detected the 11 emitted neutrinos. Worldwide, it was the first instance of the detection of the emitted neutrinos from the supernova burst, and it served a big step toward resolving the supernova explosion system. In 2002, Dr. Masatoshi Koshiba, a Special University Professor Emeriuts of the University of Tokyo, was awarded a Nobel Prize in Physics for this achievement.
Before the explosion of supernova SN1987A (right) and after the explosion (left) Anglo-Australian Observatory/David Malin
Kamiokande, the pioneer of neutrino research
Kamiokande detector was a cylindrical water tank (16 m in diameter and height) with 1000 of the world’s largest photomultiplier tubes inside it, and it was laid 1000 m underground in Kamioka-town, Yoshiki-gun, (currently Hida-city) Gifu Prefecture, Japan. (Currently the site of Kamiokande is used for KamLAND experiment.) Kamiokande was devised by Prof. Koshiba who started the observation in 1983. Originally, it was constructed for detecting the proton decay phenomenon, but it was modified for the solar neutirno observation. By the end of 1986, the detector modification was completed and the observation began.
Inside of Kamiokande detector
Overview of Kamiokande detector
Prof. Koshiba working in the tank
Prof. Kajita and Prof. Nakahata (then PhD students) tuning up the data aquision system in the mine
The day of detection of the supernova neutrinos
On February 25, 1987, two days after the observation of supernova SN1987A through naked eyes, a fax was sent from Pennsylvania University to the University of Tokyo to inform them about the supernova explosion. Soon after receiving the fax, Prof. Yoji Totsuka asked the researcher in Kamioka to send the magnetic tapes that recorded the Kamiokande data. (At that time, the information network was not developed, so the data was delivered physically).
The fax sent from Pennsylvania University to inform about the supernova explosion.
On February 27, when the magnetic tapes arrived at the laboratory in Tokyo, Prof. Masayuki Nakahata (currently the spokesperson of Super-Kamiokande experiment), who was then a PhD student immediately started the analysis. On the morning of February 28, while Prof. Nakahata printed out the analysis plot between the detection time and number of photo-sensors that detect the light, Ms. Keiko Hirata, a Master’s student found a peak, obviously different from the noise in the distribution. It was the exact trace to detect the neutrinos from SN1987A. (A two minutes blank period due to a regular system maintenance is recorded in the plot, at a few minutes before the explosion. If the explosion occurred during this period, Kamiokande could not have detected the SN1987A neutrinos.) After a detailed analysis, it was clear that Kamiokande detected 11 neutrinos for 13 seconds after 16:35:35 on February 23, 1987.
THe magnetic tape recorded SN1987A data
The printout of Kamiokande data and the envelope which stores the printout in. “Keep carefully Y.T.” written by Prof. Youji Totsuka.
The printout of the data. Horizontal axis shows time (from right to left and one line as 10 seconds) and the vertical axis shows the number of hit photo-sensors of each event (approximately proportional to the energy of the event). The obvious peak is the signal of neutrinos from SN1987A. The blank period due to the detector maintainance was recorded a few minutes before the signal.
When Prof. Nakahata finished the analysis and reported to Prof. Koshiba on the morning of March 2, Prof. Koshiba instructed him to investigate the entire data for the presence of similar signals. Under a gag rule, researchers analyzed the 43 days data of Kamiokande on March 2 to March 6, and obtained conclusive evidence that the occurrence of the peak was only from the signal of the supernova SN1987A; further, they published these findings as an article. Here are the the signatures of researchers who wrote the article.
The subsequent development of neutrino research
The Kamiokande’s detection of the supernova neutrinos became a trigger to recognize the importance of neutrino research, and the construction of Super-Kamiokande, whose volume is about 20 times larger than that of Kamiokande, was approved. Super-Kamiokande started observation from 1996 and discovered the neutrino oscillation in 1998. In 2015, Prof. Takaaki Kajita was awarded the Nobel Prize in Physics for this achievement. SN1987A made a worldwide breakthrough in neutrino research, including the K2K experiment, T2K experiment and KamLAND experiment.
If a supernova explosion in our galaxy occurs now, Super-Kamiokande will detect approximately 8,000 neutrinos, almost 1000 times greater than those detected 30 years ago. Further, it is expected that the detailed mechanism of supernova explosion will be revealed and we will understand the stars or our universe in depth. In our galaxy, the supernova explosion is expected to occur once in every 30-50 years. It may occur at this very moment. The neutrinos from the supernova will be detected in mere 10 seconds. Super-Kamiokande continues the observation and will not miss any explosion moment.
Source
Nine facts about neutrinos
Images: Kamioka Observatory,
“Why is there a blue bridge of stars across the center of this galaxy cluster? First and foremost the cluster, designated SDSS J1531+3414, contains many large yellow elliptical galaxies. The cluster’s center, as pictured above by the Hubble Space Telescope, is surrounded by many unusual, thin, and curving blue filaments that are actually galaxies far in the distance whose images have become magnified and elongated by the gravitational lens effect of the massive cluster. More unusual, however, is a squiggly blue filament near the two large elliptical galaxies at the cluster center. Close inspection of the filament indicates that it is most likely a bridge created by tidal effects between the two merging central elliptical galaxies rather than a background galaxy with an image distorted by gravitational lensing. The knots in the bridge are condensation regions that glow blue from the light of massive young stars. The central cluster region will likely undergo continued study as its uniqueness makes it an interesting laboratory of star formation.”
via APOD/NASA; Image Credit: NASA, ESA, G. Tremblay (ESO) et al.; Acknowledgment: Hubble Heritage Team (STScI/AURA) - ESA/Hubble Collaboration
"Your dreams are yours to pursue, they are beautiful, and you can't let anyone slow you down." ~ Sky Taylor to Vesha Celeste Pathway to the Stars: Part 1, Vesha Celeste #scifiauthor #spaceopera #authorsofinstagram #scifi #sciencefictionnovels #biotechnology #neuroscience #nanotechnology #longevity #theoreticalphysics #astronomy #virtualuniverse https://www.instagram.com/p/Bunk5e_ARbJ/?utm_source=ig_tumblr_share&igshid=fezlj30jxc0z
Pathway to the Stars: Part 1, Vesha Celeste Posted on October 6, 2018 by Matthew Opdyke (FTB) Soon to be released (eBook-Kindle, Oct 9, 2018), is the first in a latched-on (or related) series, Pathway to the Stars: Part 1, Vesha Celeste. This will be a slightly more descriptive portion that goes into more detail of the first character introduced, Vesha Celeste. Please pre-order, read, review, comment, and enjoy! Thank you! Vesha Celeste journeys with Yesha Alevtina and her dream-angel, Sky, following a long life of high hopes, dreams, and professional achievements in astronomy and astrophysics. Yesha shows and teaches Vesha about biopods, spaceports, tech cities that are hidden, cloaked with invisibility, and located solar-system-wide. She introduces Vesha to the Virtual Universe and teaches her how Eliza Williams worked with Yesha and James Cooper to develop all of her advances and designs. There is a lot for her to learn, in this more-detailed prequel to a giant space opera awaiting humanity, in their quest to save the Universe, one very important step at a time. Enjoy Vesha’s beginning journey, in the first of a multi-story series, called Pathway to the Stars! https://matthew-opdyke-ftb.com/2018/10/06/pathway-to-the-stars-part-1-vesha-celeste/ #scifi #strongfemalelead #fantasy #spaceopera #biotechnology #nanotechnology #politicalscifi #physics #theoreticalphysics #darkmatter #utopian #hope #edifying #entertainment https://www.instagram.com/p/BomBkaNHxWv/?utm_source=ig_tumblr_share&igshid=19fgl64n8927t
An un-released remix of "Into the Light." 2004 7 additional remixes of C+E's Billboard Club Hit, including mixes by Dave Aude, Black Light Odyssey (Floria & DeGraff,) and Andres Oscuro are available on the: "Into the Light" - (Remixes) single at iTunes, Amazon and the C+E Shop.
What are the Universe’s Most Powerful Particle Accelerators?
Every second, every square meter of Earth’s atmosphere is pelted by thousands of high-energy particles traveling at nearly the speed of light. These zippy little assailants are called cosmic rays, and they’ve been puzzling scientists since they were first discovered in the early 1900s. One of the Fermi Gamma-ray Space Telescope’s top priority missions has been to figure out where they come from.
“Cosmic ray” is a bit of a misnomer. Makes you think they’re light, right? But they aren’t light at all! They’re particles that mostly come from outside our solar system — which means they’re some of the only interstellar matter we can study — although the Sun also produces some. Cosmic rays hit our atmosphere and break down into secondary cosmic rays, most of which disperse quickly in the atmosphere, although a few do make it to Earth’s surface.
Cosmic rays aren’t dangerous to those of us who spend our lives within Earth’s atmosphere. But if you spend a lot of time in orbit or are thinking about traveling to Mars, you need to plan how to protect yourself from the radiation caused by cosmic rays.
Cosmic rays are subatomic particles — smaller particles that make up atoms. Most of them (99%) are nuclei of atoms like hydrogen and helium stripped of their electrons. The other 1% are lone electrons. When cosmic rays run into molecules in our atmosphere, they produce secondary cosmic rays, which include even lighter subatomic particles.
Most cosmic rays reach the same amount of energy a small particle accelerator could produce. But some zoom through the cosmos at energies 40 million times higher than particles created by the world’s most powerful man-made accelerator, the Large Hadron Collider. (Lightning is also a pretty good particle accelerator).
So where do cosmic rays come from? We should just be able to track them back to their source, right? Not exactly. Any time they run into a strong magnetic field on their way to Earth, they get deflected and bounce around like a game of cosmic pinball. So there’s no straight line to follow back to the source. Most of the cosmic rays from a single source don’t even make it to Earth for us to measure. They shoot off in a different direction while they’re pin balling.
Photo courtesy of Argonne National Laboratory
In 1949 Enrico Fermi — an Italian-American physicist, pioneer of high-energy physics and Fermi satellite namesake — suggested that cosmic rays might accelerate to their incredible speeds by ricocheting around inside the magnetic fields of interstellar gas clouds. And in 2013, the Fermi satellite showed that the expanding clouds of dust and gas produced by supernovas are a source of cosmic rays.
When a star explodes in a supernova, it produces a shock wave and rapidly expanding debris. Particles trapped by the supernova remnant magnetic field bounce around wildly.
Every now and then, they cross the shock wave and their energy ratchets up another notch. Eventually they become energetic enough to break free of the magnetic field and zip across space at nearly the speed of light — some of the fastest-traveling matter in the universe.
How can we track them back to supernovas when they don’t travel in a straight line, you ask? Very good question! We use something that does travel in a straight line — gamma rays (actual rays of light this time, on the more energetic end of the electromagnetic spectrum).
When the particles get across the shock wave, they interact with non-cosmic-ray particles in clouds of interstellar gas. Cosmic ray electrons produce gamma rays when they pass close to an atomic nucleus. Cosmic ray protons, on the other hand, produce gamma rays when they run into normal protons and produce another particle called a pion (Just hold on! We’re almost there!) which breaks down into two gamma rays.
The proton- and electron-produced gamma rays are slightly different. Fermi data taken over four years showed that most of the gamma rays coming from some supernova remnants have the energy signatures of cosmic ray protons knocking into normal protons. That means supernova remnants really are powerful particle accelerators, creating a lot of the cosmic rays that we see!
There are still other cosmic ray sources on the table — like active galactic nuclei — and Fermi continues to look for them. Learn more about what Fermi’s discovered over the last 10 years and how we’re celebrating its accomplishments.
Make sure to follow us on Tumblr for your regular dose of space: http://nasa.tumblr.com.
I am pleased to announce a NEW RELEASE to my Space Opera series. It is now available on Amazon in eBook and paperback formats! Pathway to the Stars: Part 6, Erin Carter Enjoy Erin’s beginning journey, in the sixth of a multi-story series, called Pathway to the Stars! "We can guide you, we can answer questions whenever you have them, but the greatest learning comes from freedom." ~ Eliza Williams, "Pathway to the Stars: Part 6, Erin Carter" #spaceopera #futurism #scifiauthor #sciencefiction #scififantasy #biotech #nanotech #neurotech #spacetravel #solarsystem #politicalscifi #strongfemalelead #entertain #educate https://www.instagram.com/p/BvXufGTg5Lb/?utm_source=ig_tumblr_share&igshid=i0paozefwqiv
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