Q.E. Reviewer - AST01-AST15-part-1.pdf

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AST01 - Introduction to Astronomy

Major Historical Events in Astronomy
1054 Chinese astronomers observed the supernova that formed into Crab Nebula

1570 Tycho Brahe detailed survey of the night sky

1609 Johannes Kepler developed Laws of Planetary Motion

1687 Isaac Newton developed the Universal Law of Gravitation

1781 Discovery of Uranus by William Herschel

1801 Discovery of Ceres by Giuseppe Piazzi

1846 Discovery of Neptune by Urbein Le Verrier

1930 Discovery of Pluto by Clyde Tombaugh

1957 Launch of Sputnik 1

1961 Yuri Gagarin becomes the first man in space

1965 Discovery of Cosmic Microwave Background

1975 Venera 9 becomes the first probe to land on Venus

1976 Viking 1 becomes the first probe to land on Mars

1977 Voyager 1 and 2 launch

2015 New Horizons Pluto Flyby

Astronomy in the Philippines
In 1865, Astronomy in the Philippines started upon the establishment of the Manila Observatory
(Meteorologica De Manila) in Intramuros by Jesuit Scientists and founded by Fr. Federico Faura.

In 1993, former President Fidel V. Ramos signed the Proclamation Decree No. 130 declaring
the celebration of the National Astronomy Week every third week of February.

In 2000, the Philippines were registered as an Associate Member of the International
Astronomical Union (IAU).

In 2019, through R.A. 11363 the Philippine Space Agency was established.
Branches of Astronomy

Cosmology - is always regarded as part of astrophysics. It is focused on the largest structure of
the universe, and the universe itself by studying its origin and evolution since the Big Bang.

Astrochemistry - focuses on the chemical abundance, reactions and interactions inside the
stars, interstellar medium, solar system, galaxies, and of the Universe.

Astrobiology - covers the life origin, evolution, and its future in the universe. It investigates the
possible migration of the Human race to other worlds in the universe.

Ethnoastronomy/Archaeoastronomy/Historical Astronomy - describes the unique practices,
beliefs, and traditions of a certain group of people in relation to astronomy, while
archaeoastronomy illustrates the recovery of cultural and analysis of astronomical material.

Astronomy Education - is the branch of astronomy that deals with the transmission of
astronomical learning, concepts and knowledge for formal education or community outreach.

Planetology - is the study of comparative analysis of the chemical, physical, environmental,
astrophysical, biological, and atmospheric inquiry of different planets in the solar system and
exoplanets.

Conversions in Astronomy

Light Year - the distance
traveled by light in one year

Astronomical Unit (AU) - the
average distance between the
Earth and the Sun (149 million
kilometers or 93 million miles)

Parsec - 3.26 light years
Models and Theories of the Solar System

Laplace's Nebula Theory (1796):
The theory states that it all began from a huge cloud of gas which was spinning slowly. This
cloud collapsed under gravity. As it collapsed, it started spinning more quickly and began to
flatten to conserve angular momentum. Laplace also proposed that planets were formed by the
condensation of annular rings around the Sun which was one of the major drawbacks of this
theory.

Schmidt-Lyttleton Accretion Theory (1944):
Schmidt proposed that the Sun passed through a huge cloud of gas and acquired matter to form
planets. However, for his theory to be consistent, he postulated the presence of a third body in
the vicinity when the Sun passed through this cloud.

However, the need for the third body's presence was removed when Lyttleton gave his
modification of the theory involving line accretion. In this form of accretion, mathematically
described by Bondi and Hoyle. The material from the cloud gets focused gravitationally. The
velocities of the material perpendicular to its orbital axis around the central object get destroyed
and it is left with less than escape speed.

Proto-planet Theory (1960):
McCrea explained that the Solar System started with a cloud of dust and gas in a state of
hypersonic turbulence. Thus, rapid internal collisions took place. This resulted in aggregation of
masses at various places. He experimented with parameters like mass and radius of cloud to
explain the current state of the
solar system. He gave a revised theory in 1988.

Capture Theory (1964):
The theory is given by Woolfson and it considers an interaction between a condensed solar
mass star and a protostar of lesser mass. The protostar entered the Roche limit and
disintegrated to form bodies like planets. This gives a planar structure but highly elliptical orbits.

The Solar Nebula Theory (1973):
This theory is given by Cameron and it begins with a slowly rotating nebula very similar to the
Laplacian theory. The planet formation starts with a disc of 0.01 to 0.1 solar masses.

The Modern Laplacian Theory (1974): This theory is also derived from the Laplacian theory
and was given by Prentice. He started with a cool gas cloud which condensed in such a way
that the angular momentum of the central body was only 1 percent of the system. His
contribution was mainly giving a mathematical explanation of the process of formation and the
formation of planets in concentric rings.
Interplanetary Bodies of the Solar System
Asteroid Belt
- the gap between Mars and Jupiter
where hundreds of thousands of
known asteroids orbit the Sun

Dwarf Planets in this region:
Ceres

Kuiper Belt
- a very distant version of the Asteroid
Belt that extends from the orbit of
Neptune out to a distance of well
beyond 50 AU from the Sun.

Dwarf Planets in this region:
Pluto, Haumea, Makemake, Eris

Oort Cloud
- surrounds the entire solar system
with a shell of frozen bits of ice and
rock that stretches out to about a
quarter of the way to the nearest star.

Both the Kuiper Belt and the Oort Cloud are the origin of most of the comets we see.

Stellar Formation
Hertzsprung-Russell Diagram
- Also called as HR-Diagram is one of the
most important tools in the study of stellar
evolution. It plots the temperature of stars
against their luminosity (the theoretical HR
diagram), or the color of stars (or spectral
type) against their absolute magnitude (the
observational HR diagram, also known as a
color-magnitude diagram). We can know a
star's internal structure and evolutionary
stage simply by determining its position in
the diagram.
 Main sequence stars which 90% of the stars spend their lives in. The MS stars account
for 80%-90% of the stellar population.

Red giant or super red giant have high luminosities, lower surface temperature, and
larger radius. Helium-burning stars.

White Dwarf Stars (for mid mass stars) is the shed-off core of the red giant stars. In a
spectrum, hot objects emit mostly short-wavelength radiation, while cool objects emit
mostly long-wavelength radiation-hot stars are blue and cool stars are red.

Nebulas, Star Clusters, Galaxies

Galaxies
- huge grouping of stars, planets, star clusters, nebulae, black holes, dust, dark matter,
and everything else. These billions of stars are bound together by the mutual pull of
gravity.

Types:

Lenticular Galaxies (S0 class)
- with galactic disk, don't have spiral arms. Little sign of star-forming activity in their disk,
dominated by old red and yellow stars.
Elliptical Galaxies (E0 circular - E7 elongated)
- simple ball shape. old stars and globular star clusters which imply that any star formation
in these galaxies has long since ended.

Spiral Galaxies (Sa - Sd (loose))
- have vast, rotating discs of stars, dust, and gas. It has a ball-shaped nucleus inside a
disc with spiral arms. It is said that 25-30% of galaxies are spirals. Sa Sd (loose)

Barred-Spiral Galaxies (SBa - SBd)
- are spiral galaxies in which the spiral arms don't seem to emerge from the galaxy center
but from the ends of a linear or football-shaped cloud of stars that straddle the center.

Peculiar Galaxies
- are due to galactic collisions, making a distorted shape of both
galaxies. Some smaller galaxies went straight to the heart of the
bigger one.

Dwarf Galaxies
- a few thousands light-years across, or even less. Most abundant
type of galaxy in the universe. Low luminosity, and low mass.

Low Surface Brightness Galaxies
- They can be as large as most other galaxies, they haven't many
stars, which make them not appear as bright. Although they have a
full tank of gas.
Galaxy Clusters
- a large-scale structure in the universe consisting of hundreds to thousands of galaxies
bound together by gravity. These clusters are the largest known gravitationally bound
structures in the universe and can contain masses equivalent to hundreds of trillions of
solar masses.

- Rich galaxy clusters contain over thousand galaxies, most elliptical and more
concentrated towards the center. Rich clusters often contain one or more giant elliptical
galaxies at their center. Poor galaxy cluster contains fewer than a thousand (and only a
few) galaxies spread through a region that can be as large as a rich cluster

Milky Way Galaxy (barred spiral galaxy)

Main Parts:
- Bulge - Contains older, Population II stars
- Disk: Contains stars, gas, and dust, with a mix of Population I
(younger) and Population II (older) stars
- Halo - Contains old stars, globular clusters, and a significant
amount of dark matter.
Star Clusters

Gas and Dust
- Empty spaces are not really empty but contain gas and dust particles that compose the
interstellar medium (ISM). 90% by mass is composed of hydrogen, and others are traces
mostly of helium.
- Cold clouds or molecular hydrogen. The clouds of cold molecular and atomic
hydrogen embody the raw material from which stars can be formed in the disk of the
galaxy.
- Hot ionized hydrogen. This is created when the ultraviolet radiation emitted abundantly
by hot newly- formed stars ionizes surrounding clouds of gas.

Types of Nebulae
Planetary Nebula
○ are the atmosphere of old stars that started out resembling the Sun but then
expelled their outer atmospheric layers. These nebulae are expanding into space
and fading as they grow larger.
Emission Nebula
○ a hot interstellar cloud and emitting visible light results in a glowing cloud. The
young stars of type O and B produce ultraviolet radiation that can ionize the
hydrogen and other atoms in these clouds
Reflection Nebula
○ The cloud is not hot enough to emit visible light, dust particles reflect light from
nearby stars. A human hair is 100 times wider than these tiny grains.
Dark Nebula
○ a cloud of dust and cold gas, which does not emit visible light, it hides the stars it
contains.