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#Post#: 10133--------------------------------------------------
Isaac Newton was a Jesuit Freemason, so was Galileo, Kepler, Cop
ernicus and Ibn al-Shatir
By: sneakydove Date: February 7, 2020, 7:49 am
---------------------------------------------------------
For those who are unaware, Isaac Newton had some occult books in
his library.
HTML https://www.youtube.com/watch?v=nL2NJB6nc94
He is also recorded as having written more on the topic of
theology than physics. I suspect Newton was attempting to craft
his own trinity with his three laws of motion. Since gravity is
false because the world is flat, it's safe to assume that the
three laws of motion are false also as they have a false premise
at their foundation. (Namely the false assumption that the
shape of the world is globular.)
#Post#: 10137--------------------------------------------------
Re: Newton was an Occultist
By: guest8 Date: February 7, 2020, 10:35 am
---------------------------------------------------------
[quote author=sneakydove link=topic=762.msg10133#msg10133
date=1581083391]
For those who are unaware, Isaac Newton had some occult books in
his library.
HTML https://www.youtube.com/watch?v=nL2NJB6nc94
He is also recorded as having written more on the topic of
theology than physics. I suspect Newton was attempting to craft
his own trinity with his three laws of motion. Since gravity is
false because the world is flat, it's safe to assume that the
three laws of motion are false also as they have a false premise
at their foundation. (Namely the false assumption that the
shape of the world is globular.)
[/quote]
Satan touched many lives throughout the centuries and continues
to do so. Our world worlds-view is based on those lies, etc.
#Post#: 11113--------------------------------------------------
Re: Newton was an Occultist
By: patrick jane Date: March 18, 2020, 11:31 pm
---------------------------------------------------------
[quote author=sneakydove link=topic=762.msg10133#msg10133
date=1581083391]
For those who are unaware, Isaac Newton had some occult books in
his library.
HTML https://www.youtube.com/watch?v=nL2NJB6nc94
He is also recorded as having written more on the topic of
theology than physics. I suspect Newton was attempting to craft
his own trinity with his three laws of motion. Since gravity is
false because the world is flat, it's safe to assume that the
three laws of motion are false also as they have a false premise
at their foundation. (Namely the false assumption that the
shape of the world is globular.)
[/quote]There is also a connection with science and the Kabbalah
& Zohar. Science is actually rooted in Alchemy and the occult.
#Post#: 15714--------------------------------------------------
Re: Newton was an Occultist
By: patrick jane Date: July 30, 2020, 11:49 pm
---------------------------------------------------------
Many are unaware
#Post#: 16985--------------------------------------------------
Re: Newton was an Occultist
By: guest73 Date: September 1, 2020, 12:46 pm
---------------------------------------------------------
All of science was founded and created from occult practices and
beliefs
#Post#: 17532--------------------------------------------------
Re: Newton was an Occultist
By: patrick jane Date: September 13, 2020, 12:03 pm
---------------------------------------------------------
[quote author=Jesus Truth link=topic=762.msg16985#msg16985
date=1598982404]
All of science was founded and created from occult practices and
beliefs
[/quote]Indeed.
#Post#: 30823--------------------------------------------------
Re: Isaac Newton was an Occultist Freemason, so was Galileo, Kep
ler, Copernicus and Ibn al-Shatir
By: patrick jane Date: June 2, 2021, 6:48 pm
---------------------------------------------------------
3114 BC
Mayan astronomers discover an 18.7-year cycle in the rising and
setting of the Moon. From this they created the first almanacs –
tables of the movements of the Sun, Moon, and planets for the
use in astrology. In 6th century BC Greece, this knowledge is
used to predict eclipses.
585 BC
Thales of Miletus predicts a solar eclipse.
467 BC
Anaxagoras produced a correct explanation for eclipses and then
described the Sun as a fiery mass larger than the Peloponnese ,
as well as attempting to explain rainbows and meteors . He was
the first to explain that the Moon shines due to reflected light
from the Sun.[1][2][3]
400 BC
Around this date, Babylonians use the zodiac to divide the
heavens into twelve equal segments of thirty degrees each, the
better to record and communicate information about the position
of celestial bodies.[4]
387 BC
Plato, a Greek philosopher, founds a school (the Platonic
Academy) that will influence the next 2000 years. It promotes
the idea that everything in the universe moves in harmony and
that the Sun, Moon, and planets move around Earth in perfect
circles.
270 BC
Aristarchus of Samos proposes heliocentrism as an alternative to
the Earth-centered universe. His heliocentric model places the
Sun at its center, with Earth as just one planet orbiting it.
However, there were only a few people who took the theory
seriously.
240 BC
The earliest recorded sighting of Halley's Comet is made by
Chinese astronomers. Their records of the comet's movement allow
astronomers today to predict accurately how the comet's orbit
changes over the centuries.
150 BC
Hipparchus of Nicaea calculates the first model of the solar
system based on trigonometry and determines the precession of
the equinoxes.
6 BC
The Magi - probably Persian astronomers/astrologers (Astrology)
- observed a planetary conjunction on Saturday (Sabbath) April
17, 6 BC that signified the birth of a great Hebrew king:
Jesus.[5]
4 BC
The astronomer Shi Shen is believed to have cataloged 809 stars
in 122 constellations, and he also made the earliest known
observation of sunspots.
140
Ptolemy publishes his star catalogue, listing 48 constellations
and endorses the geocentric (Earth-centered) view of the
universe. His views go unquestioned for nearly 1500 years in
Europe and are passed down to Arabic and medieval European
astronomers in his book the Almagest.
400
The Hindu cosmological time cycles explained in the Surya
Siddhanta, give the average length of the sidereal year (the
length of the Earth's revolution around the Sun) as 365.2563627
days, which is only 1.4 seconds longer than the modern value of
365.256363004 days.[6] This remains the most accurate estimate
for the length of the sidereal year anywhere in the world for
over a thousand years.
499
Indian mathematician-astronomer Aryabhata, in his Aryabhatiya
first identifies the force gravity to explain why objects do not
fall when the Earth rotates,[7] propounds a geocentric Solar
System of gravitation, and an eccentric elliptical model of the
planets, where the planets spin on their axis and follow
elliptical orbits, the Sun and the Moon revolve around the Earth
in epicycles. He also writes that the planets and the Moon do
not have their own light but reflect the light of the Sun and
that the Earth rotates on its axis causing day and night and
also that the Sun rotates around the Earth causing years.
628
Indian mathematician-astronomer Brahmagupta, in his
Brahma-Sphuta-Siddhanta, first recognizes gravity as a force of
attraction, and briefly describes the second law of Newton's law
of universal gravitation. He gives methods for calculations of
the motions and places of various planets, their rising and
setting, conjunctions, and calculations of the solar and lunar
eclipses.
773
The Sanskrit works of Aryabhata and Brahmagupta, along with the
Sanskrit text Surya Siddhanta, are translated into Arabic,
introducing Arabic astronomers to Indian astronomy.
777
Muhammad al-Fazari and Yaʿqūb ibn Ṭāriq
translate the Surya Siddhanta and Brahmasphutasiddhanta, and
compile them as the Zij al-Sindhind, the first Zij treatise.[8]
830
The first major Arabic work of astronomy is the Zij al-Sindh by
al-Khwarizimi. The work contains tables for the movements of the
Sun, the Moon, and the five planets known at the time. The work
is significant as it introduced Ptolemaic concepts into Islamic
sciences. This work also marks the turning point in Arabic
astronomy. Hitherto, Arabic astronomers had adopted a primarily
research approach to the field, translating works of others and
learning already discovered knowledge. Al-Khwarizmi's work
marked the beginning of nontraditional methods of study and
calculations.[9]
850
al-Farghani wrote Kitab fi Jawani ("A compendium of the science
of stars"). The book primarily gave a summary of Ptolemic
cosmography. However, it also corrected Ptolemy based on
findings of earlier Arab astronomers. Al-Farghani gave revised
values for the obliquity of the ecliptic, the precessional
movement of the apogees of the Sun and the Moon, and the
circumference of the Earth. The books were widely circulated
through the Muslim world and even translated into Latin.[10]
928
The earliest surviving astrolabe is constructed by Islamic
mathematician–astronomer Mohammad al-Fazari. Astrolabes are the
most advanced instruments of their time. The precise measurement
of the positions of stars and planets allows Islamic astronomers
to compile the most detailed almanacs and star atlases yet.
1030
Abū Rayḥān al-Bīrūnī discussed
the Indian heliocentric theories of Aryabhata, Brahmagupta and
Varāhamihira in his Ta'rikh al-Hind (Indica in Latin).
Biruni stated that the followers of Aryabhata consider the Earth
to be at the center. In fact, Biruni casually stated that this
does not create any mathematical problems.[11]
1031
Abu Sa'id al-Sijzi, a contemporary of Abu Rayhan Biruni,
defended the theory that Earth revolves around its axis.
1054
Chinese astronomers record the sudden appearance of a bright
star. Native-American rock carvings also show the brilliant star
close to the Moon. This star is the Crab supernova exploding.
1070
Abu Ubayd al-Juzjani published the Tarik al-Aflak. In his work,
he indicated the so-called "equant" problem of the Ptolemic
model. Al-Juzjani even proposed a solution to the problem. In
al-Andalus, the anonymous work al-Istidrak ala Batlamyus
(meaning "Recapitulation regarding Ptolemy"), included a list of
objections to the Ptolemic astronomy.
One of the most important works in the period was Al-Shuku ala
Batlamyus ("Doubts on Ptolemy"). In this, the author summed up
the inconsistencies of the Ptolemic models. Many astronomers
took up the challenge posed in this work, namely to develop
alternate models that evaded such errors.
1126
Islamic and Indian astronomical works (including Aryabhatiya and
Brahma-Sphuta-Siddhanta) are translated into Latin in Córdoba,
Spain in 1126, introducing European astronomers to Islamic and
Indian astronomy.
1150
Indian mathematician-astronomer Bhāskara II, in his
Siddhanta Shiromani, calculates the longitudes and latitudes of
the planets, lunar and solar eclipses, risings and settings, the
Moon's lunar crescent, syzygies, and conjunctions of the planets
with each other and with the fixed stars, and explains the three
problems of diurnal rotation. He also calculates the planetary
mean motion, ellipses, first visibilities of the planets, the
lunar crescent, the seasons, and the length of the Earth's
revolution around the Sun to 9 decimal places.
1190
Al-Bitruji proposed an alternative geocentric system to
Ptolemy's. He also declared the Ptolemaic system as
mathematical, and not physical. His alternative system spread
through most of Europe during the 13th century, with debates and
refutations of his ideas continued to the 16th century.[12][13]
1250
Mo'ayyeduddin Urdi develops the Urdi lemma, which is later used
in the Copernican heliocentric model.
Nasir al-Din al-Tusi resolved significant problems in the
Ptolemaic system by developing the Tusi-couple as an alternative
to the physically problematic equant introduced by Ptolemy.[14]
His Tusi-couple is later used in the Copernican model.
Tusi's student Qutb al-Din al-Shirazi, in his The Limit of
Accomplishment concerning Knowledge of the Heavens, discusses
the possibility of heliocentrism.
Najm al-Din al-Qazwini al-Katibi, who also worked at the
Maraghah observatory, in his Hikmat al-'Ain, wrote an argument
for a heliocentric model, though he later abandoned the
idea.[citation needed]
1350
[size=14pt][b]Ibn al-Shatir[/b] (1304–1375), in his A Final
Inquiry Concerning the Rectification of Planetary Theory,
eliminated the need for an equant by introducing an extra
epicycle, departing from the Ptolemaic system in a way very
similar to what Copernicus later also did. Ibn al-Shatir
[size=24pt]proposed a system that was only approximately
geocentric, rather than exactly so, having demonstrated
trigonometrically that the Earth was not the exact center of the
universe. His rectification is later used in the Copernican
model.[/size]
1543
Nicolaus Copernicus publishes De revolutionibus orbium
coelestium containing his theory that Earth travels around the
Sun. However, he complicates his theory by retaining Plato's
perfect circular orbits of the planets.
1572
A brilliant supernova (SN 1572 - thought, at the time, to be a
comet) is observed by Tycho Brahe, who proves that it is
traveling beyond Earth's atmosphere and therefore provides the
first evidence that the heavens can change.
1608
Dutch eyeglass maker Hans Lippershey tries to patent a
refracting telescope (the first historical record of one). The
invention spreads rapidly across Europe, as scientists make
their own instruments. Their discoveries begin a revolution in
astronomy.
1609
Johannes Kepler publishes his New Astronomy. In this and later
works, he announces his three laws of planetary motion,
replacing the circular orbits of Plato with elliptical ones.
Almanacs based on his laws prove to be highly accurate.
1610
Galileo Galilei publishes Sidereus Nuncius describing the
findings of his observations with the telescope he built. These
include spots on the Sun, craters on the Moon, and four
satellites of Jupiter. Proving that not everything orbits Earth,
he promotes the Copernican view of a Sun-centered universe.
1655
As the power and the quality of the telescopes increase,
Christiaan Huygens studies Saturn and discovers its largest
satellite, Titan. He also explains Saturn's appearance,
suggesting the planet is surrounded by a thin ring.
1663
Scottish astronomer James Gregory describes his "gregorian"
reflecting telescope, using parabolic mirrors instead of lenses
to reduce chromatic aberration and spherical aberration, but is
unable to build one.
1668
Isaac Newton builds the first reflecting telescope, his
Newtonian telescope.
1687
Isaac Newton publishes his first copy of the book Philosophiae
Naturalis Principia Mathematica, establishing the theory of
gravitation and laws of motion. The Principia explains Kepler's
laws of planetary motion and allows astronomers to understand
the forces acting between the Sun, the planets, and their moons.
1705
Edmond Halley calculates that the comets recorded at 76-year
intervals from 1456 to 1682 are one and the same. He predicts
that the comet will return again in 1758. When it reappears as
expected, the comet is named in his honor.
1750
French astronomer Nicolas de Lacaille sails to southern oceans
and begins work compiling a catalog of more than 10000 stars in
the southern sky. Although Halley and others have observed from
the Southern Hemisphere before, Lacaille's star catalog is the
first comprehensive one of the southern sky.
1781
Amateur astronomer William Herschel discovers the planet Uranus,
although he at first mistakes it for a comet. Uranus is the
first planet to be discovered beyond Saturn, which was thought
to be the most distant planet in ancient times.
1784
Charles Messier publishes his catalog of star clusters and
nebulas. Messier draws up the list to prevent these objects from
being identified as comets. However, it soon becomes a standard
reference for the study of star clusters and nebulas and is
still in use today.
1800
William Herschel splits sunlight through a prism and with a
thermometer, measures the energy given out by different colours.
He notices a sudden increase in energy beyond the red end of the
spectrum, discovering invisible infrared and laying the
foundations of spectroscopy.
1801
Italian astronomer Giuseppe Piazzi discovers what appears to be
a new planet orbiting between Mars and Jupiter, and names it
Ceres. William Herschel proves it is a very small object,
calculating it to be only 320 km in diameter, and not a planet.
He proposes the name asteroid, and soon other similar bodies are
being found. We now know that Ceres is 932 km in diameter, and
is now considered to be a dwarf planet.
1814
Joseph von Fraunhofer builds the first accurate spectrometer and
uses it to study the spectrum of the Sun's light. He discovers
and maps hundreds of fine dark lines crossing the solar
spectrum. In 1859 these lines are linked to chemical elements in
the Sun's atmosphere. Spectroscopy becomes a method for studying
what stars are made of.
1838
Friedrich Bessel successfully uses the method of stellar
parallax, the effect of Earth's annual movement around the Sun,
to calculate the distance to 61 Cygni, the first star other than
the Sun to have its distance from Earth measured. Bessel's is a
truly accurate measurement of stellar positions, and the
parallax technique establishes a framework for measuring the
scale of the universe.
1843
German amateur astronomer Heinrich Schwabe, who has been
studying the Sun for the past 17 years, announces his discovery
of a regular cycle in sunspot numbers - the first clue to the
Sun's internal structure.
1845
Irish astronomer William Parsons, 3rd Earl of Rosse completes
the first of the world's great telescopes, with a 180-cm mirror.
He uses it to study and draw the structure of nebulas, and
within a few months discovers the spiral structure of the
Whirlpool Galaxy.
French physicists Jean Foucault and Armand Fizeau take the first
detailed photographs of the Sun's surface through a telescope -
the birth of scientific astrophotography. Within five years,
astronomers produce the first detailed photographs of the Moon.
Early film is not sensitive enough to image stars.
1846
A new planet, Neptune, is identified by German astronomer Johann
Gottfried Galle while searching in the position suggested by
Urbain Le Verrier. Le Verrier has calculated the position and
size of the planet from the effects of its gravitational pull on
the orbit of Uranus. An English mathematician, John Couch Adams,
also made a similar calculation a year earlier.
1868
Astronomers notice a new bright emission line in the spectrum of
the Sun's atmosphere during an eclipse. The emission line is
caused by an element's giving out light, and British astronomer
Norman Lockyer concludes that it is an element unknown on Earth.
He calls it helium, from the Greek word for the Sun. Nearly 30
years later, helium is found on Earth.
1872
An American astronomer Henry Draper takes the first photograph
of the spectrum of a star (Vega), showing absorption lines that
reveal its chemical makeup. Astronomers begin to see that
spectroscopy is the key to understanding how stars evolve.
William Huggins uses absorption lines to measure the redshifts
of stars, which give the first indication of how fast stars are
moving.
1901
A comprehensive survey of stars, the Henry Draper Catalogue, is
published. In the catalog, Annie Jump Cannon proposes a sequence
of classifying stars by the absorption lines in their spectra,
which is still in use today.
1906
Ejnar Hertzsprung establishes the standard for measuring the
true brightness of a star. He shows that there is a relationship
between color and absolute magnitude for 90% of the stars in the
Milky Way Galaxy. In 1913, Henry Norris Russell published a
diagram that shows this relationship. Although astronomers agree
that the diagram shows the sequence in which stars evolve, they
argue about which way the sequence progresses. Arthur Eddington
finally settles the controversy in 1924.
1910
Williamina Fleming publishes her discovery of white dwarf stars.
1912
Henrietta Swan Leavitt discovers the period-luminosity relation
for Cepheid variables, whereas the brightness of a star is
proportional to its luminosity oscillation period. It opened a
whole new branch of possibilities of measuring distances on the
universe, and this discovery was the basis for the work done by
Edwin Hubble on extragalactic astronomy.
1916
German physicist Karl Schwarzschild uses Albert Einstein's
theory of general relativity to lay the groundwork for black
hole theory. He suggests that if any star collapse to a certain
size or smaller, its gravity will be so strong that no form of
radiation will escape from it.
1923
Edwin Hubble discovers a Cepheid variable star in the "Andromeda
Nebula" and proves that Andromeda and other nebulas are galaxies
far beyond our own. By 1925, he produces a classification system
for galaxies.
1925
Cecilia Payne-Gaposchkin discovers that hydrogen is the most
abundant element in the Sun's atmosphere, and accordingly, the
most abundant element in the universe by relating the spectral
classes of stars to their actual temperatures and by applying
the ionization theory developed by Indian physicist Meghnad
Saha. This opens the path for the study of stellar atmospheres
and chemical abundances, contributing to understand the chemical
evolution of the universe.
1929
Edwin Hubble discovered that the universe is expanding and that
the farther away a galaxy is, the faster it is moving away from
us. Two years later, Georges Lemaître suggests that the
expansion can be traced to an initial "Big Bang".
1930
By applying new ideas from subatomic physics, Subrahmanyan
Chandrasekhar predicts that the atoms in a white dwarf star of
more than 1.44 solar masses will disintegrate, causing the star
to collapse violently. In 1933, Walter Baade and Fritz Zwicky
describe the neutron star that results from this collapse,
causing a supernova explosion.
Clyde Tombaugh discovers the dwarf planet Pluto at the Lowell
Observatory in Flagstaff, Arizona. The object is so faint and
moving so slowly that he has to compare photos taken several
nights apart.
1932
Karl Jansky detects the first radio waves coming from space. In
1942, radio waves from the Sun are detected. Seven years later
radio astronomers identify the first distant source - the Crab
Nebula, and the galaxies Centaurus A and M87.
1938
German physicist Hans Bethe explains how stars generate energy.
He outlines a series of nuclear fusion reactions that turn
hydrogen into helium and release enormous amounts of energy in a
star's core. These reactions use the star's hydrogen very
slowly, allowing it to burn for billions of years.
1948
The largest telescope in the world, with a 5.08m (200 in)
mirror, is completed at Palomar Mountain in California. At the
time, the telescope pushes single-mirror telescope technology to
its limits - large mirrors tend to bend under their own weight.
1958
July 29 marks the beginning of the NASA (National Aeronautics
and Space Administration), agency newly created by the United
States to catch up with Soviet space technologies. It absorbs
all research centers and staffs of the NACA (National Advisory
Committee for Aeronautics), an organization founded in 1915.
1959
Russia and the US both launch probes to the Moon, but NASA's
Pioneer probes all failed. The Russian Luna program was more
successful. Luna 2 crash-lands on the Moon's surface in
September, and Luna 3 returns the first pictures of the Moon's
farside in October.
1960
Cornell University astronomer Frank Drake performed the first
modern SETI experiment, named "Project Ozma", after the Queen of
Oz in L. Frank Baum's fantasy books.[15]
1962
Mariner 2 becomes the first probe to reach another planet,
flying past Venus in December. NASA follows this with the
successful Mariner 4 mission to Mars in 1965, both the US and
Russia send many more probes to planets through the rest of the
1960s and 1970s.
1963
Dutch-American astronomer Maarten Schmidt measures the spectra
of quasars, the mysterious star-like radio sources discovered in
1960. He establishes that quasars are active galaxies, and among
the most distant objects in the universe.
1965
Arno Penzias and Robert Wilson announce the discovery of a weak
radio signal coming from all parts of the sky. Scientists figure
out that this must be emitted by an object at a temperature of
-270 °C. Soon it is recognized as the remnant of the very hot
radiation from the Big Bang that created the universe 13 billion
years ago, see Cosmic microwave background. This radio signal is
emitted by the electron in hydrogen flipping from pointing up or
down and is approximated to happen once in a million years for
every particle. Hydrogen is present in interstellar space gas
throughout the entire universe and most dense in nebulae which
is where the signals originate. Even though the electron of
hydrogen only flips once every million years the mere quantity
of hydrogen in space gas makes the presence of these radio waves
prominent.
1966
Russian Luna 9 probe makes the first successful soft landing on
the Moon in January, while the US lands the far more complex
Surveyor missions, which follows up to NASA's Ranger series of
crash-landers, scout sites for possible manned landings.
1967
Jocelyn Bell Burnell and Antony Hewish detected the first
pulsar, an object emitting regular pulses of radio waves.
Pulsars are eventually recognized as rapidly spinning neutron
stars with intense magnetic fields - the remains of a supernova
explosion.
1970
The Uhuru satellite, designed to map the sky at X-ray
wavelengths, is launched by NASA. The existence of X-rays from
the Sun and a few other stars has already been found using
rocket-launched experiments, but Uhuru charts more than 300
X-ray sources, including several possible black holes.
1972
Charles Thomas Bolton was the first astronomer to present
irrefutable evidence of the existence of a black hole.
1975
The Russian probe Venera 9 lands on the surface of Venus and
sends back the first picture of its surface. The first probe to
land on another planet, Venera 7 in 1970, had no camera. Both
break down within an hour in the hostile atmosphere.
1976
NASA's Viking 1 and Viking 2 space probes arrive at Mars. Each
Viking mission consists of an orbiter, which photographs the
planet from above, and a lander, which touches down on the
surface, analyzes the rocks, and searches unsuccessfully for
life.
1977
On August 20 the Voyager 2 space probe launched by NASA to study
the Jovian system, Saturnian system, Uranian system, Neptunian
system, the Kuiper belt, the heliosphere and the interstellar
space.
On September 5 The Voyager 1 space probe launched by NASA to
study the Jovian system, Saturnian system and the interstellar
medium.
1983
The first infrared astronomy satellite, IRAS, is launched. It
must be cooled to extremely low temperatures with liquid helium,
and it operates for only 300 days before the supply of helium is
exhausted. During this time it completes an infrared survey of
98% of the sky.
1986
The returning Halley's Comet is met by a fleet of five probes
from Russia, Japan, and Europe. The most ambitious is the
European Space Agency's Giotto spacecraft, which flies through
the comet's coma and photographs the nucleus.
1990
The Magellan probe, launched by NASA, arrives at Venus and
spends three years mapping the planet with radar. Magellan is
the first in a new wave of probes that include Galileo, which
arrives at Jupiter in 1995, and Cassini which arrives at Saturn
in 2004.
The Hubble Space Telescope, the first large optical telescope in
orbit, is launched using the Space Shuttle, but astronomers soon
discovered that it is crippled by a problem with its mirror. A
complex repair mission in 1993 allows the telescope to start
producing spectacular images of distant stars, nebulae, and
galaxies.
1992
The Cosmic Background Explorer satellite produces a detailed map
of the background radiation remaining from the Big Bang. The map
shows "ripples", caused by slight variations in the density of
the early universe – the seeds of galaxies and galaxy clusters.
The 10-meter Keck telescope on Mauna Kea, Hawaii, is completed.
The first revolutionary new wave of telescopes, the Keck's main
mirror is made of 36 six-sided segments, with computers to
control their alignment. New optical telescopes also make use of
interferometry – improving resolution by combining images from
separate telescopes.
1995
The first exoplanet, 51 Pegasi b, is discovered by Michel Mayor
and Didier Queloz.
2005
Mike Brown and his team discovered Eris a large body in the
outer Solar System[16] which was temporarily named as (2003)
UB313. Initially, it appeared larger than Pluto and was called
the tenth planet.[17]
2006
International Astronomical Union (IAU) adopted a new definition
of planet. A new distinct class of objects called dwarf planets
was also decided. Pluto was redefined as a dwarf planet along
with Ceres and Eris, formerly known as (2003) UB313. Eris was
named after the IAU General Assembly in 2006.[18][19]
2008
2008 TC3 becomes the first Earth-impacting meteoroid spotted and
tracked prior to impact.
2012
(May 2) First visual proof of the existence of black holes is
published. Suvi Gezari's team in Johns Hopkins University, using
the Hawaiian telescope Pan-STARRS 1, record images of a
supermassive black hole 2.7 million light-years away that is
swallowing a red giant.[20]
2013
In October 2013, the first extrasolar asteroid is detected
around white dwarf star GD 61. It is also the first detected
extrasolar body which contains water in liquid or solid
form.[21][22][23]
2015
On July 14, with the successful encounter of Pluto by NASA's New
Horizons spacecraft, the United States became the first nation
to explore all of the nine major planets recognized in 1981.
Later on September 14, LIGO was the first to directly detect
gravitational waves.[24]
2016
Exoplanet Proxima Centauri b is discovered around Proxima
Centauri by the European Southern Observatory, making it the
closest known exoplanet to the Solar System as of 2016.
2017
In August 2017, a neutron star collision that occurred in the
galaxy NGC 4993 produced the gravitational wave signal GW170817,
which was observed by the LIGO/Virgo collaboration. After 1.7
seconds, it was observed as the gamma-ray burst GRB 170817A by
the Fermi Gamma-ray Space Telescope and INTEGRAL, and its
optical counterpart SSS17a was detected 11 hours later at the
Las Campanas Observatory. Further optical observations e.g. by
the Hubble Space Telescope and the Dark Energy Camera,
ultraviolet observations by the Swift Gamma-Ray Burst Mission,
X-ray observations by the Chandra X-ray Observatory and radio
observations by the Karl G. Jansky Very Large Array complemented
the detection. This was the first instance of a gravitational
wave event that was observed to have a simultaneous
electromagnetic signal, thereby marking a significant
breakthrough for multi-messenger astronomy.[25] Non-observation
of neutrinos is attributed to the jets being strongly
off-axis.[26]
2019
China's Chang'e 4 became the first spacecraft to perform a soft
landing on the lunar far side.
In April 2019, the Event Horizon Telescope Collaboration
obtained the first image of a black hole which was at the center
of galaxy M87, providing more evidence for the existence of
supermassive black holes in accordance with general
relativity.[27]
India launched its second lunar probe called Chandrayaan 2 with
an orbiter that was successful and a lander called Vikram along
with a rover called Pragyan which failed just 2.1 km above the
lunar south pole.
2020
NASA launches Mars 2020 to Mars with a Mars rover that was named
Perseverance by seventh grader Alexander Mather in a naming
contest[/size]
#Post#: 31739--------------------------------------------------
Re: Isaac Newton was an Occultist Freemason, so was Galileo, Kep
ler, Copernicus and Ibn al-Shatir
By: patrick jane Date: June 16, 2021, 12:16 pm
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The People of Other Worlds - ROBERT SEPEHR
Dr. Hermann Oberth was a respected Austro-Hungarian-born German
physicist and engineer, internationally-known rocket pioneer,
and head of the US CALTECH Laboratories until 1955. Considered
one of the founding fathers of rocketry and astronautics, Oberth
eventually came to work for one of his students, former SS
officer Wernher von Braun, who was developing space rockets for
NASA.
1 hour
HTML https://www.youtube.com/watch?v=8qqR5dJOpRo
#Post#: 34565--------------------------------------------------
Re: Isaac Newton was a Jesuit Freemason, so was Galileo, Kepler,
Copernicus and Ibn al-Shatir
By: patrick jane Date: August 14, 2021, 5:40 pm
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Organized Religion Is Destroying The Earth | Prophecy
36 minutes
HTML https://www.youtube.com/watch?v=ueSJUIxfeNA
#Post#: 34572--------------------------------------------------
Re: Isaac Newton was a Jesuit Freemason, so was Galileo, Kepler,
Copernicus and Ibn al-Shatir
By: patrick jane Date: August 14, 2021, 5:44 pm
---------------------------------------------------------
As The World Turns - A Documentary
HTML https://odysee.com/@ShakingMyHead2:8/as-the-world-turns-a-documentary:2?
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