Curved Space: Theory of Everything

Different Dimensions ◽

Main Asteroid Belt ◽

Matter and energy are both made from curved space, the flow of space creates gravitation, and the increase of space causes the expansion of the universe. Matter curves in two different directions of one dimension creates two types of electric charges: positive and negative. Matter curves in three different dimensions creates three values or charges of quark's color: red, green, and blue. The equivalent equation of space: S=Ec²=mc⁴ . The main asteroid belt is at the gravitation limit distance of the Sun. When the Sun moves forward in the Milky Way, the inner planets are affected by the gravitation and moves directly with it. The space which released by the Sun flows backwards on its path and guiding the outer planets to follow it. The gravitation of hollow sphere space: S=(4/3)π((r+a)³-r³) .

Curved Space: Theory of Everything

10.31219/osf.io/ydwt4 ◽

2020 ◽

Author(s):

S. Chen

Keyword(s):

Electric Charge ◽

Space Theory ◽

Curved Space ◽

Space Curves ◽

Theory Of Everything ◽

Equivalent Equation ◽

Different Dimensions ◽

Negative Space ◽

Matter and energy are made from curved space, the flow of space creates gravity, and the increase of the space causes the expansion of the universe. Space curves in two different directions of another dimension create two types of electric charge: positive and negative. Space curves in three different dimensions creates three values or charges of quark's color: red, green, and blue. The equivalent equation of space: S=Ec²=mc⁴.

Curved Space: Theory of Everything

10.31219/osf.io/ze4jc ◽

2021 ◽

Author(s):

S. Chen

Keyword(s):

Hollow Sphere ◽

One Dimension ◽

Space Theory ◽

Curved Space ◽

Theory Of Everything ◽

Equivalent Equation ◽

Different Dimensions ◽

Recurrent Activity from Active Asteroid (248370) 2005 QN173: A Main-belt Comet

The Astrophysical Journal ◽

10.3847/2041-8213/ac365b ◽

2021 ◽

Vol 922 (1) ◽

pp. L8 ◽

Cited By ~ 1

Author(s):

Colin Orion Chandler ◽

Chadwick A. Trujillo ◽

Henry H. Hsieh

Keyword(s):

Solar System ◽

Detection Technique ◽

Asteroid Belt ◽

The Sun ◽

Activity Detection ◽

Main Belt ◽

Solar System Objects ◽

Recurrent Activity ◽

Main Asteroid Belt

Abstract We present archival observations of main-belt asteroid (248370) 2005 QN173 (also designated 433P) that demonstrate this recently discovered active asteroid (a body with a dynamically asteroidal orbit displaying a tail or coma) has had at least one additional apparition of activity near perihelion during a prior orbit. We discovered evidence of this second activity epoch in an image captured 2016 July 22 with the DECam on the 4 m Blanco telescope at the Cerro Tololo Inter-American Observatory in Chile. As of this writing, (248370) 2005 QN173 is just the eighth active asteroid demonstrated to undergo recurrent activity near perihelion. Our analyses demonstrate (248370) 2005 QN173 is likely a member of the active asteroid subset known as main-belt comets, a group of objects that orbit in the main asteroid belt that exhibit activity that is specifically driven by sublimation. We implement an activity detection technique, wedge photometry, that has the potential to detect tails in images of solar system objects and quantify their agreement with computed antisolar and antimotion vectors normally associated with observed tail directions. We present a catalog and an image gallery of archival observations. The object will soon become unobservable as it passes behind the Sun as seen from Earth, and when it again becomes visible (late 2022) it will be farther than 3 au from the Sun. Our findings suggest (248370) 2005 QN173 is most active interior to 2.7 au (0.3 au from perihelion), so we encourage the community to observe and study this special object before 2021 December.

Dynamical evolution of near-Earth objects

10.5194/epsc2020-1104 ◽

2020 ◽

Author(s):

Athanasia Toliou ◽

Mikael Granvik

Keyword(s):

Semimajor Axis ◽

Dynamical Evolution ◽

Orbital Evolution ◽

Derived Categories ◽

Asteroid Belt ◽

The Sun ◽

Escape Route ◽

Perihelion Distance ◽

Main Asteroid Belt ◽

Near Earth Objects

An apparent discrepancy between the number of observed near-Earth objects (NEOs) with small perihelion distances (q) and the number of objects that models predict, has led to the conclusion that asteroids get destroyed at non-trivial distances from the Sun. Consequently, there must be a, possibly thermal, mechanism at play, responsible for breaking up asteroids asteroids in such orbits. We studied the dynamical evolution of ficticious NEOs whose perihelion distance reaches below the average disruption distance q_dis=0.076 au, as suggested by Granvik et al. (2016). To that end, we used the orbital integrations of objects that escaped from the main asteroid belt (Granvik et al. 2017), and entered the near-Earth region (Granvik et al. 2018). First, we investigated a variety of mechanisms that can lower the perihelion distance of an object to a small-enough value. In particular, we considered mean-motion resonances with Jupiter, secular resonances with Jupiter and Saturn (v_5 and v_6) and also the Kozai resonance. We developed a code that calculates the evolution of the critical argument of all the relevant resonances and identifies librations during the last stages of an object's orbital evolution, namely, just before q=q_dis. Any subsequent evolution of the object was disregarded, since we considered it disrupted. The accuracy of our model is ~96%. In addition, we measured the dynamical 'lifetimes' of NEOs when they orbit the innermost parts of the inner Solar System. More precisely, we calculated the total time it takes for the q of each object to go from 0.4 au to q_dis (&#964;_lq). The outer limit of this range was chosen such because it is a) the approximate semimajor axis of Mercury, and b) an absence of sub-meter-sized boulders with q smaller than this distance has been proposed by Wiegert et al (2020). Combining this measure with the recorded resonances, we can get a sense of the timescale of each q-lowering mechanism. Next, for a more rigorous study of the evolution of the NEOs with q<0.4 au, we divided this region in bins and measured the relevant time they spend at different distances from the Sun. Together with the total time spent in each bin, we kept track of the number of times that q entered one of the bins. Finally, we computed the actual time each object spends in each bin during its evolution, i.e., the total time it spends in a specific range in radial heliocentric distance. By following this approach, we derived categories of typical evolutions of NEOs that reach the average disruption distance. In addition, since we have the information concerning the escape route from the main asteroid belt followed by each NEO, we linked the q-lowering mechanism and the associated orbital evolutions in the range below the orbit of Mercury, to their source regions and thus were able to draw conclusions abour their physical properties.

Cosmic Spherules, Asteroid Collisions and the Solar Constant

International Astronomical Union Colloquium ◽

10.1017/s0252921100084608 ◽

1985 ◽

Vol 85 ◽

pp. 183-183

Author(s):

D.W. Parkin

Keyword(s):

Effect Size ◽

Asteroid Belt ◽

Current Work ◽

Oxide Surface ◽

The Sun ◽

Solar Constant ◽

Circular Orbits ◽

Cosmic Spherules ◽

Main Asteroid Belt

AbstractIn 1980 (Phil. Trans. Roy. Soc. 297, 495) and in 1983 (Geophys. Jour. Roy. Astr. Soc. 75, 473) it was proposed that cosmic spherules are formed as splash ejecta in asteroidal collisions. The Poynting-Robertson effect size-sorts the spherules as they spiral to Earth in circular orbits. The time taken in My is given byΔt = 3.5 × 10−7 Dδ (a2 − 1)where a (in AU) is the collision distance from the Sun, D (in um) is the diameter of the spherules and δ (in kg/m−3) its density. In the 1983 paper, we tested the hypothesis by plotting the size of all the iron spherules (≥ 43 μm diam.) against time for two dated N. Pacific cores. Sloping lines, giving a ~ 2.1 AU, could be discerned; but their existence could be disputed - see figure 6.In current work, all the spherules from core V21-65 have been cracked open to find δ. Out of 220 spherules, 65 have rusted metal globules and these (Dδ) points give a confused plot, because of inaccurate δ-values. However, 66 spherules have their metal globules well preserved. Since globule diameter and %Ni can be accurately measured, δ can be calculated. These (Dδ) points show two sloping lines with some clarity, giving a ~ 3.4 AU; also, there are vague lines, giving a-values well within the main asteroid belt.To establish the hypothesis, wide cores are needed, giving an abundance of undamaged spherules. To obtain accurate a-values, the Robertson formula requires correction because of the spherule’s “hummocky” oxide surface. Also, any waviness in the sloping lines could be a measure of a variable solar constant.A new kind of iron spherule was found because of the cracking; 13 enclose opaque beads of true glass (rich in Fe, Ni and Si, no Mg) instead of metal globules. Crushed bits are deep ruby-red and nonmagnetic.

GRAVITY CAN BE OBSERVED IN THE ABSENCE OF CURVED SPACETIME, THUS CURVED SPACETIME IS NOT RESPONCIBLE FOR GRAVITY

JOURNAL OF ADVANCES IN PHYSICS ◽

10.24297/jap.v8i1.1526 ◽

2015 ◽

Vol 8 (1) ◽

pp. 1976-1981

Author(s):

Casey McMahon

Keyword(s):

General Relativity ◽

Special Relativity ◽

Relative Position ◽

Gravitational Force ◽

Curved Spacetime ◽

Relative Time ◽

Curved Space ◽

Spacetime Curvature ◽

Equivalence Model ◽

The principle postulate of general relativity appears to be that curved space or curved spacetime is gravitational, in that mass curves the spacetime around it, and that this curved spacetime acts on mass in a manner we call gravity. Here, I use the theory of special relativity to show that curved spacetime can be non-gravitational, by showing that curve-linear space or curved spacetime can be observed without exerting a gravitational force on mass to induce motion- as well as showing gravity can be observed without spacetime curvature. This is done using the principles of special relativity in accordance with Einstein to satisfy the reader, using a gravitational equivalence model. Curved spacetime may appear to affect the apparent relative position and dimensions of a mass, as well as the relative time experienced by a mass, but it does not exert gravitational force (gravity) on mass. Thus, this paper explains why there appears to be more gravity in the universe than mass to account for it, because gravity is not the resultant of the curvature of spacetime on mass, thus the â€œdark matterâ€ and â€œdark energyâ€ we are looking for to explain this excess gravity doesnâ€™t exist.

Black Hole Universe: a grand cosmic recycler and Big Bang generator?

10.31219/osf.io/pbdn3 ◽

2019 ◽

Author(s):

Matheus Pereira Lobo

Keyword(s):

Black Hole ◽

Big Bang ◽

Subsequent Increase ◽

We propose the discussion of a highly speculative idea for the scenario where black hole collisions and their subsequent increase in sizes exceed the expansion of the universe.

Expansion of the Universe

SSRN Electronic Journal ◽

10.2139/ssrn.3098578 ◽

2018 ◽

Author(s):

Rossano mname Giandomenico

Keyword(s):

Much Ado about (Practically) Nothing

10.1093/oso/9780195393965.001.0001 ◽

2010 ◽

Author(s):

David Fisher

Keyword(s):

Energy Source ◽

Atomic Nucleus ◽

The Sun ◽

Scientific Journals ◽

Rare Gases ◽

Important Work ◽

The Earth ◽

Wide Range ◽

Life On Mars ◽

There are eight columns in the Periodic Table. The eighth column is comprised of the rare gases, so-called because they are the rarest elements on earth. They are also called the inert or noble gases because, like nobility, they do no work. They are colorless, odorless, invisible gases which do not react with anything, and were thought to be unimportant until the early 1960s. Starting in that era, David Fisher has spent roughly fifty years doing research on these gases, publishing nearly a hundred papers in the scientific journals, applying them to problems in geophysics and cosmochemistry, and learning how other scientists have utilized them to change our ideas about the universe, the sun, and our own planet. Much Ado about (Practically) Nothing will cover this spectrum of ideas, interspersed with the author's own work which will serve to introduce each gas and the important work others have done with them. The rare gases have participated in a wide range of scientific advances-even revolutions-but no book has ever recorded the entire story. Fisher will range from the intricacies of the atomic nucleus and the tiniest of elementary particles, the neutrino, to the energy source of the stars; from the age of the earth to its future energies; from life on Mars to cancer here on earth. A whole panoply that has never before been told as an entity.

Cosmological constant

10.1093/oso/9780198802877.003.0026 ◽

2018 ◽

Author(s):

Michael Kachelriess

Keyword(s):

Dark Energy ◽

Cosmological Constant ◽

Accelerated Expansion ◽

Vacuum Fluctuations ◽

Present Epoch ◽

Modify Gravity ◽

The contribution of vacuum fluctuations to the cosmological constant is reconsidered studying the dependence on the used regularisation scheme. Then alternative explanations for the observed accelerated expansion of the universe in the present epoch are introduced which either modify gravity or add a new component of matter, dubbed dark energy. The chapter closes with some comments on attempts to quantise gravity.