Universe Topic Pictures Part 2 PDF

Summary

This document explores various topics in cosmology and ancient astronomy, including planetary nebulae, white dwarfs, and the work of astronomers like Edwin Hubble and Vesto Slipher. It discusses the life cycle of stars, Hubble's Law, and the Hertzsprung-Russell Diagram, offering insights into the structure and evolution of the universe.

Full Transcript

# Cosmology and Ancient Astronomy ## Planetary Nebulae - The planetary Nebulae phase is the final stage in the life of a low-mass star, where the star sheds its outer layers, creating an expanding, glowing shell. - This occurs towards the end of the red giant phase. - When the star becomes unstable...

# Cosmology and Ancient Astronomy ## Planetary Nebulae - The planetary Nebulae phase is the final stage in the life of a low-mass star, where the star sheds its outer layers, creating an expanding, glowing shell. - This occurs towards the end of the red giant phase. - When the star becomes unstable and pulsates, producing strong stellar winds that expel the outer layer. - The remaining core, called a white dwarf, emits ultraviolet radiation that illuminates the surrounding gas. - Over time, the material from the planetary nebula disperses into space, contributing to the formation of new stars. - This phase lasts for tens of thousands of years, a brief period compared to the star's overall lifespan. ## White Dwarfs - About 61% of stars in our part of the Milky Way are white dwarfs. - When a small star runs out of fuel, it sheds its outer layers, forming a planetary nebula and leaving behind a white dwarf. - White dwarfs are bright, hot and compact, about the size of the Earth but with the mass of the Sun. - They shine faintly with only 0.1 - 70% of the Sun's brightness and have surface temperatures over 10,000 K. - White dwarfs cool very slowly, taking billions of years to reach around 100,000°C. - They are extremely dense, with a density of about 1 million tonnes per cubic meter. - Inside, the material is in a state called neutron degeneracy, where normal physical laws don't apply. - As a white dwarf's mass increases, its radius decreases. - If it exceeds the Chandrasekhar Limit (1.44 Solar masses), it becomes unstable and can collapse into a black hole. ## Edwin Hubble - From 1919, Hubble worked as an astronomer at Mount Wilson Observatory in California. - His discoveries revolutionized ideas on the structure of the universe. - In 1924, while examining the Andromeda nebula, thought to be part of the Milky Way galaxy, Hubble discovered a pulsating star - a Cepheid variable whose brightness varied in a regular pattern. - He calculated the distance from Earth and found it to be 800,000 light years - much further than most distant stars. - He then showed that Andromeda was a separate galaxy and went on to discover 20 more galaxies. - He was the first to find that the Milky Way galaxy was a small part of the universe. ## Vesto Slipher - In 1912, Vesto Slipher, an astronomer working at Lowell Observatory in Arizona, examined the spectrum of light produced by spiral nebulae. - He found that the frequencies of light received from the nebulae were lower than a normal spectrum - each spectrum of line was closer to the red end of the spectrum than usual - they had been red-shifted. - Slipher had discovered what we now call the Doppler Effect. - He concluded that the nebulae producing the light must be moving away from us. - By measuring the amount of red-shift, he was able to calculate their speeds. ## Hubble's Law - In 1927, Hubble discovered that all the galaxies were moving away from us. - This was a prediction made by Hubble. - Then in 1932, Friedmann proved Hubble's prediction correct by calculating based on Einstein's corrected equations. - Hubble's expanding universe model implied that the matter of the universe was concentrated in one position originally and then exploded outwards. - Evidence for this event is gained by reversing the velocities of the galaxies - imagining to move backward. - This can be expressed as $v = H_0 d$, where: - $v$ is the velocity of the galaxy, - $H_0$ is Hubble's constant, - $d$ is the distance to the galaxy. - Hubble's constant has a value of approximately 70 km/s/Mpc. - Using this equation, the age of the universe can be estimated as $1/H_0$, which is approximately 13.8 billion years. ## Hertzsprung-Russell Diagram - The Hertzsprung-Russell Diagram shows the relationship between a star's temperature and its luminosity. - This diagram can be used to chart the lifecycle of a star. - If all stars were alike, all those with the same luminosity would have the same temperature. - However, we expect the hottest stars to be the brightest. - Red giant and red supergiant stars fall in the top right of the chart. - This tells us that they are brighter than the main sequence stars but also redder and cooler. - This is because they expand and cool as they reach the final stages of their lives. - However, because they are large, they remain bright. - In the bottom left corner of the chart, we find hot stars that are dimmer than the main sequence stars. - This is because they have small radii but contain a lot of mass. - These are white dwarf stars. - Stars tend to spend 90% of their lives in the main-sequence stage. - After this, they become giant stars for 10% of their remaining lives. - Finally, they either explode as a supernova or become white dwarfs. - The color of a star can be used to estimate its temperature. - As a star's temperature increases, it becomes hotter and gradually changes its color. - We can see this change from orange, through yellow, to white. - The hottest stars stay blue with temperatures of up to 40,000°C. - The coolest stars are red with surface temperatures of about 3,000°C. ## Stellar Classification - Astronomers began to categorize stars based on their mass and temperature. - Stars are grouped into 7 main categories (also called classes): O, B, A, F, G, K, and M. - Stars in the 'O' class are the most massive and hottest. - Stars in the 'M' class are the smallest and coolest. - The hotter stars are usually much less common than the cooler, redder ones. - For example, 'O' type stars make up only 1 in every 3 million stars we see. - The next hottest 'B' stars are more common, making up 1 in 800. - Then each cooler subtype gets more and more common. - The coolest 'M' type stars make up 75% of all stars we see. - We can be more accurate when we categorize stars, by splitting each class into 10 smaller sub-classes. - These sun-classes are numbered 0-9, with 0 being hotter than 1. - For example, the sun is a G2 star. - This is hotter than a G7 star, but cooler than a G0 star. - Similarly, a B2 star is cooler than a B1 star.

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