In 96 richly illustrated half-hour lectures you will survey the main concepts, methods, and discoveries in astronomy&;amp;-from the constellations drawn by the ancients, to the latest reports from planetary probes in our Solar System and the most recent images offered by telescopes probing the farthest frontiers of space and time. While updating this course, Professor Alex Filippenko added hundreds of images, including nearly 300 short movies and computer animations.
Understanding the Universe: An Introduction to Astronomy, 2nd Edition
Get a comprehensive overview of the grandest of all subjects-the universe-in this brilliant and fascinating course taught by one of America's foremost astronomers.
Rated 5 out of
5
by
Docrpaul from
A grand overview of astronomy for the non-scientis
While the 96 lectures were daunting, the time really flew by over the past month or so that I've been watching them. Dr. Filippenko manages to take an admittedly huge field and break it into manageable and logical chunks. While his style is sometimes a little goofy and he occasionally lapses into bad dad jokes, his enthusiasm is infectious and more than offsets any minor quibbles about that style. While many of the ideas he presents are challenging, he clearly understands his audience, and keeps his focus on the ideas themselves and not the complex math needed to understand them at the deepest level. Time and again, he advises the listener to not worry too much about the details, but to try and grasp the overall shape of the concepts.
My only wish for this course is that it could be updated, since at this point, it's 18 years old. It speaks for the power of the course that I've been inspired to look up many of the subjects discussed to see what advances have been made since the course was first published, but I'd love to see a current version.
Date published: 2024-01-25
Rated 5 out of
5
by
Nerdle from
Nerd humor but space is pretty cool
I am a nerd. I like to watch science shows. I like to learn something when going to bed. Astrophysics relaxes me even though I have to trust them on the math. This is one of my favorites! The enthusiasm for space phenomena comes through the lectures. The various digressions about personal trips and science shirts give some levity to a very complex topic.
Date published: 2024-01-12
Rated 5 out of
5
by
Gharmjo from
Astronomy Starts Here
This is a course where the Transcript is valuable. I have about 30 “cornered” edges in each of its four 400-page Books. Part of the reason is that Filippenko frequently uses a lengthy historical approach where logic builds and then suddenly shifts as unexpected observations change conclusions. For example, in VIDEO Lecture 3 (=L3), he tells us about “the green flash" since "not many people have seen the green flash". I have since seen it twice but became disconcerted with a third sighting that unexpectedly lasted for many seconds. A review of the TRANSCRIPT p. 39 described this “enhanced green flash"! This example also shows how Filippenko enhances awareness of what’s going on around you. Example 2: Filippenko frequently reminds that he first mentioned subject “x” in lecture “y". Locating "y" via transcript is faster than skipping through a video!
Part 2 (L25-70/Book 2&3) discusses the universe’s known structural elements. It contains piquing tidbits: L28 notes the necessity for the “greenhouse effect" to avoid a frozen earth AND the term “greenhouse” is misleading since greenhouses warm from ground radiation. He states, “that there is a scientific consensus BUT NOT UNANIMITY” (emphasis added) that global warming exists and “even (it’s) more controversial-that human activity is responsible". He points out Venus’ problem stems not from CO2 but UV breakdown of high altitude water, destroying rainfall and that on earth the carbonate cycle ends up sequestering CO2. His open-mindedness beats hysteria; especially when given 66 million years of International Oceanic Discovery Platform data (their CENOGRID Internet graph drawn without rescaling) shows, a progressively cooling earth (presently labeled “Icehouse"!). Given that the earth IS cooling, maybe we should “pay attention”: could petroleum be saving us from the icehouse earth predicted in the 1980s? L28 of this 2007 course ends with “...we really don't trust our computer models" yet cautions that changes of a few degrees would bring devastating agricultural changes. L38 discusses why “…our assumption that other planetary systems are just like our own was wrong." This leads to his L42 discussion of the Drake Equation's one-in-a-trillion chance of intelligent life per galaxy. He adds that the Drake equation doesn’t include Jupiter's clearing out of solar system debris or that without earth's unusual moon our rotational axis “would undergo chaotic variations”. L42 is a marvelous discussion of the effects of relativity on space travel and is the start of conceptually "heavier" material. The graph at 26:13 is helpful regarding star spectral lines. L46 contains a useful fact for the remainder of the course: a main sequence star's lifetime is “proportional to one over the cube of its mass”. L47 notes the important difference between open (young) and globular (old) star clusters. L48 well details star nuclear reactors and ends with a marvelously simple analogy explaining binding energies. L49: If solar fusion stopped right now, “we wouldn't know it for 100K years”…yet ghostly neutrinos could tell us in 8 minutes. L50: A recurring topic: "Electron degeneracy pressure" is defined; L52: an excellent Main Star sequence review; L53, 54: Why 1.4 solar mass White Dwarfs provide heavy elements; L63: Black hole myths; L69: Many in the 1920 “The Scale of the Universe debate" felt the Milky Way was the universe UNTIL Hubble described distant Cepheid variables in the mid-20s leading to classes of galaxies; L70: Black holes don’t confine galaxy rotation but galaxy (early universe WIMP) dark matter halos seem to.
Part 3 (L71-96 / Book 4) Cosmology. Here 3 themes stand out: 1.) Math increases and 2.) “...some conclusions made through the scientific process are not testable…and hence...remove themselves from the realm of science” (L71). I have so many “bookmarks" in these chapters that a review would be futile. BUY THE COURSE! I end with two thoughts. L96: Richard Feynman standing by the ocean, observed, “This great ocean was sitting there for…billions of years, just with all the trillions of atoms interacting. Why were they doing this? … Us, out of this…They produced us, atoms with consciousness, in a sense.” L72: “It was a hot birth…a hot Big Bang, where for some reason that we’re still trying to understand, the Universe came into existence.” 3.) Our understanding that the universe started with a Big Bang in an absolutely empty void began with 1920s Hubble observations was finally confirmed in the early 21st century [see L71, 72, and the brilliant Great Course “Origin and Evolution of Earth” (L2) by Hazen]. 4000 years ago, an inspired Moses pre-empted this 21st century universe-out-of-nothing debate with a short synopsis: Genesis 1:2,3.
Date published: 2024-01-09
Rated 5 out of
5
by
Michael1156 from
Great introduction
This course is very long, but I never lost interest in the lectures. The instructor is engaging and the subject matter is well worth the time.
Date published: 2023-12-22
Rated 5 out of
5
by
RJPDO from
I learned so much!
This is a fantastic course. Lots of easy-to-understand information with great visuals. Does need to be updated.
Date published: 2023-09-02
Rated 5 out of
5
by
bobswim from
incredible experience - worth the time
this course one of the best I've taken, along with ones on the oceans (“oceanography” and “life in the world's oceans”) - the instructor, Alex, has done an incredible job of deciphering the universe and astronomy in depth for the layman – his presentation is superb – when a lecture was overwhelming I'd resort to his outline material for clarification – many of the talks are not easy sledding but if you stick with it you'll come away with a solid appreciation for the vast cosmos of which most of us have little knowledge (he does intersperse his commentary with some humor and simple examples from time to time to lighten the subject matter) - the final lectures are extremely interesting where he incorporates some philosophy into our place in all this magnificent “stuff” - quite frankly, the subject boggles the mind at trying to grasp how amazing and complex the universe is – I've passed on many facts he reveals about black holes and dark energy to friends who also had no idea about the “space” we inhabit all around us – highly recommend this course – while it's a large investment of time and focus to stick with all 96 lectures the payback is immense – I congratulate Dr. Filippenko in making the commitment to produce this course for the general public – it must have taken a huge chunk of his time and expertise to put this together – I thank him for doing it and making this subject manageable for the rest of us
Date published: 2023-08-13
Rated 5 out of
5
by
JYE56 from
One of the best courses in Wondrium
The first edition of this course was the very first course from the Great Courses that I took close to 20 years ago. It was a great one. Because of the great experience I had with the first edition, I proceeded to take more than 50 courses from the Great Courses. To refresh my knowledge on astronomy, I just finished viewing the latter 2/3 of the second edition. It is equally good or even better!!
Date published: 2023-04-05
Rated 5 out of
5
by
AF Vet from
Wow! Just Wow!
Incredible teacher for a subject as wide-ranging as the universe.
Date published: 2023-03-19
Overview
About
Dr. Alex Filippenko is Professor of Astronomy and the Richard and Rhoda Goldman Distinguished Professor in the Physical Sciences at the University of California, Berkeley. He earned his B.A. in Physics from the University of California, Santa Barbara, and his Ph.D. in Astronomy from the California Institute of Technology. Dr. Filippenko's research accomplishments, documented in more than 500 scientific publications and 600 abstracts and astronomical circulars, are among the most highly cited in the world. Science magazine credited two international teams of astronomers (on which he was the only coauthor contributing to both teams) with the top "Science Breakthrough of 1998" for research on exploding stars (supernovae), which shows that the universe is expanding at an accelerating rate, propelled by mysterious "dark energy." Professor Filippenko received a share of the 2007 Gruber Cosmology Prize for this discovery, work that went on to receive the 2011 Nobel Prize in Physics. Professor Filippenko also leads the world's most successful robotic search for exploding stars. Dr. Filippenko was elected in 2009 to the National Academy of Sciences, one of the highest honors accorded to a U.S. scientist. He has also been recognized with several major awards, including the 2010 Richard H. Emmons Award for excellence in the teaching of college-level introductory astronomy for non-science majors from the Astronomical Society of the Pacific, the 2007 Richtmyer Memorial Award of the American Association of Physics Teachers, the 1997 Robert M. Petrie Prize of the Canadian Astronomical Society, and the 1992 Newton Lacy Pierce Prize of the American Astronomical Society. He was a Guggenheim Fellow in 2001 and a Phi Beta Kappa Visiting Scholar in 2002. In 2006, he was honored nationally as the "Outstanding Doctoral and Research Universities Professor of the Year" by the Carnegie Foundation for the Advancement of Teaching and the Council for Advancement and Support of Education. At UC Berkeley, Dr. Filippenko's teaching awards include the Donald S. Noyce Prize for Excellence in Undergraduate Teaching in the Physical Sciences and the Distinguished Teaching Award. Dr. Filippenko is coauthor of The Cosmos: Astronomy in the New Millennium, now in its 4th edition (2013), and winner of the 2001 Texty Excellence Award for best new textbook in the physical sciences. He has played a prominent role in numerous television documentaries, including about 40 episodes spanning six seasons of The Universe on The History Channel.
Trailer
01: A Grand Tour of the Cosmos
You embark on a fantastic voyage throughout the Universe, starting in this lecture with a whirlwind tour of the course, which extends from phenomena in Earth's atmosphere to events at the farthest reaches of space and time....
34 min
02: The Rainbow Connection
The daytime sky contains intriguing natural sights that offer a colorful introduction to astronomy. One such phenomenon is the rainbow. This lecture examines how a rainbow is created and how it appears under different circumstances....
30 min
03: Sunrise, Sunset
Continuing the study of the daytime sky, this lecture examines phenomena associated with sunrise and sunset, including the elusive green flash, Buddha's rays, and Earth's own shadow at sunset....
32 min
04: Bright Objects in the Night Sky
Many objects in the night sky can be enjoyed with the naked eye, even from the city. These include several famous constellations, bright stars, planets, and satellites such as the International Space Station....
31 min
05: Fainter Phenomena in the Night Sky
Far from city lights, the night sky becomes spectacular and includes such sights as the Milky Way, the Magellanic Clouds, zodiacal light, and comets. Though not technically "celestial," auroras are also wondrous spectacles....
31 min
06: Our Sky through Binoculars and Telescopes
A relatively inexpensive telescope and even a simple pair of binoculars greatly increase the number of celestial objects you can study, such as the craters on the Moon, the Orion Nebula, and the Andromeda Galaxy....
30 min
07: The Celestial Sphere
As Earth rotates on its axis and orbits the Sun, the night sky changes over a 24-hour period, as well as throughout the year. This lecture explains how to locate celestial bodies and why the sky appears different from place to place....
33 min
08: The Reason for the Seasons
Contrary to popular belief, the seasons are not caused by changes in the distance between Earth and the Sun over the course of a year. Instead, the tilt of Earth's axis of spin relative to the axis of its orbital plane produces seasons....
31 min
09: Lunar Phases and Eerie Lunar Eclipses
Lunar phases occur as the Moon orbits Earth, changing the viewing perspective of the Moon's illuminated hemisphere. Lunar eclipses take place when Earth, the Sun, and Moon are almost exactly aligned....
30 min
10: Glorious Total Solar Eclipses
Total solar eclipses are stunning celestial sights, which occur when the Moon comes between Earth and the Sun, totally blocking the Sun for a small portion of the Earth. These rare events reveal beautiful and thrilling phenomena....
31 min
11: More Eclipse Tales
Solar eclipses also come in annular and hybrid varieties, reflecting the varying distance of the Moon from Earth. A famous total solar eclipse in 1919 provided observational evidence for Einstein's general theory of relativity....
31 min
12: Early Studies of the Solar System
Astronomy has its roots in the ancient civilizations of Mesopotamia, Babylon, India, Egypt, and China. The Greeks in particular developed sophisticated and sometimes surprisingly accurate theories of the nature of the heavens....
29 min
13: The Geocentric Universe
The Greek philosopher Aristotle concluded that Earth is stationary at the center of the Universe, surrounded by 55 nested spheres. Ptolemy elaborated this geocentric model into a system that held sway for nearly 1,500 years....
30 min
14: Galileo and the Copernican Revolution
In 1543, Copernicus proposed a heliocentric system, in which Earth and other planets orbit the Sun, which is at the center of the Universe. In the early 1600s Galileo provided strong evidence for this model with the newly invented telescope....
31 min
15: Refinements to the Heliocentric Model
This lecture explores the refinements in the Copernican model made possible by Tycho's extremely accurate measurements of planetary positions, which were analyzed by Kepler to produce his laws of planetary motion....
31 min
16: On the Shoulders of Giants
According to legend, Newton saw a falling apple and realized that the force that pulled it toward Earth also pulled on the Moon, keeping it in its orbit. Building on the work of Kepler and Galileo, he revolutionized astronomy with his law of universal gravitation and laws of motion....
32 min
17: Surveying Space and Time
Observations of the transit of Venus across the face of the Sun in the 18th century helped determine the scale of the Solar System. In the wider Universe, distances are so vast that the finite speed of light means we are literally looking back in time....
31 min
18: Scale Models of the Universe
The best way to understand the size of the Universe is to investigate it in a series of steps, each 10 times larger or smaller than the one preceding. In this way, you explore the cosmos from the smallest to the largest scale....
31 min
19: Light-The Supreme Informant
Astronomers obtain most of their information through the analysis of light. This lecture introduces the electromagnetic spectrum and the technique of spectroscopy, in which light is dispersed into its component colors, as in a rainbow....
31 min
20: The Wave-Particle Duality of Light
Delving deeper into the nature of light, you explore the strange duality between electromagnetic waves (light waves) and particles (photons), which is a fundamental feature of quantum theory....
30 min
21: The Colors of Stars
The surface temperature of a star determines its apparent color. The hottest stars are bluish in color, and the coldest stars are reddish; stars at intermediate temperatures appear white. The Sun is a white star....
31 min
22: The Fingerprints of Atoms
Electrons jumping between different energy levels in atoms emit and absorb photons in a characteristic way for each element. Thus, astronomers can use the light from distant objects to deduce their chemical compositions....
31 min
23: Modern Telescopes
Today's telescopes are designed to provide huge light-gathering mirrors at relatively low cost. The mirrors focus light from distant objects onto sensitive electronic detectors that are far more efficient than traditional photographic film....
31 min
24: A Better Set of Eyes
This lecture looks at radio telescopes, adaptive optics for ground-based infrared telescopes, and NASA's Great Observatories, which include the Hubble Space Telescope, Chandra X-Ray Observatory, and Spitzer Space Telescope....
31 min
25: Our Sun, the Nearest Star
Beginning a sequence of lectures on the Solar System, you start with the Sun, which you explore from the interior to the surface. Sunspots are cooler regions associated with strong magnetic fields, and violent eruptions blast solar material into space....
30 min
26: The Earth, Third Rock from the Sun
Earth is one of the four innermost, or terrestrial, planets; the others are Mercury, Venus, and Mars. All are relatively small, rocky, and dense. This lecture examines Earth's structure, properties, and the forces that affect it....
32 min
27: Our Moon, Earth's Nearest Neighbor
This lecture covers the wealth of knowledge about the Moon, a heavily cratered world with extensive lava-filled basins on the Earth-facing side and yet few such features on the far side-which is not perpetually dark....
31 min
28: Mercury and Venus
Though broadly similar to Earth, Mercury and Venus differ in detail. Mercury has a negligible atmosphere and is heavily cratered. Venus has an incredibly thick atmosphere and suffers from an extreme greenhouse effect that makes it intensely hot....
33 min
29: Of Mars and Martians
Recent missions to Mars provide evidence for an early water-rich era that may have fostered primitive life. Today, Mars is a cold, apparently lifeless world. Evidence for fossil life in a Martian meteorite remains controversial....
31 min
30: Jupiter and Its Amazing Moons
Beyond Mars lie the four gas giants: Jupiter, Saturn, Uranus, and Neptune. Jupiter is the Solar System's largest planet by far. Its moons include Io, which is volcanically active, and Europa, which may have an ocean of liquid water below its frozen surface....
31 min
31: Magnificent Saturn
Best known for its extensive ring system, Saturn has come into focus recently thanks to the Cassini spacecraft, which landed a probe on Saturn's largest moon, Titan; and also discovered evidence of liquid water on the moon Enceladus....
30 min
32: Uranus and Neptune, the Small Giants
Though less massive than Jupiter and Saturn, Uranus and Neptune are similar in that they consist mostly of hydrogen and helium. Both have bizarre magnetic fields that are highly tilted relative to the planet's rotation axis and offset from the planet's center....
30 min
33: Pluto and Its Cousins
Discovered in 1930, Pluto was long considered a planet. However, the detection of more and more objects in the same region strongly suggests that it is a member of a reservoir of comet-like bodies in the Kuiper belt....
30 min
34: Asteroids and Dwarf Planets
Under a new definition adopted in 2006, planets are more narrowly defined and a new class called dwarf planets has been created, which includes Pluto, Eris (a Kuiper-belt object larger than Pluto), and Ceres (the largest asteroid)....
33 min
35: Comets-Gorgeous Primordial Snowballs
Comets are "dirty snowballs" from beyond the orbit of Neptune. As they approach the Sun, they begin to evaporate and produce gaseous tails. In 2005, a space probe impacted Comet Tempel 1, revealing the nature of its interior....
31 min
36: Catastrophic Collisions
Comets and asteroids have struck Earth throughout its history. One such collision 65 million years ago probably caused the extinction of the dinosaurs. Astronomers now search for asteroids that could be a potential threat to Earth....
31 min
37: The Formation of Planetary Systems
Planets form inside a rotating cloud of dust and gas, which flattens as it contracts. At the center, the temperature is high enough to create a star; farther from the center, leftover material collects into planets....
32 min
38: The Quest for Other Planetary Systems
In 1995, the first extra-solar planet was discovered around a Sun-like star. Since then, about 200 have been found. The easiest to detect are those with large masses, close to their host stars, and with brief orbital periods....
31 min
39: Extra-Solar Planets Galore!
Because extra-solar planets are too dim to be seen directly, they are detected using a variety of ingenious techniques. Two examples: Minute variations in a star's spectrum and tiny changes in its brightness can signal the presence of planets....
31 min
40: Life Beyond the Earth
The recent discovery of extra-solar planets rekindles the age-old question of whether there is life beyond Earth. This lecture examines the possibility of rudimentary life on other planets and moons in the Solar System....
31 min
41: The Search for Extraterrestrials
Are there intelligent extraterrestrials elsewhere in our Galaxy? One way to search is to scan the radio spectrum for evidence of their electronic signals. The Drake equation suggests ways to estimate their prevalence....
31 min
42: Special Relativity and Interstellar Travel
Are interstellar voyages possible within a single human lifetime? According to Einstein's special theory of relativity, the answer is "yes" in principle but "no" in practice, given current technology. You explore the reasons for both answers....
31 min
43: Stars-Distant Suns
A voyage to another star would require exact information on distances and properties of the stars. This lecture shows how astronomers measure the distance to nearby stars and how they determine their surface temperatures, which are the basis for stellar classification....
32 min
44: The Intrinsic Brightnesses of Stars
Apparent brightness is the observed brightness of a star. Because stars are at different distances, astronomers need a standard reference by which to compare stars in absolute terms, as if they're all at the same distance: This standard is called intrinsic brightness, or luminosity....
30 min
45: The Diverse Sizes of Stars
This lecture discusses the Hertzsprung-Russell diagram, a plot of stellar surface temperature versus luminosity that contains a wealth of information. Stars spend most of their existence on the diagram's well-defined main sequence; outliers include supergiants and white dwarfs....
31 min
46: Binary Stars and Stellar Masses
Many stars are members of binary systems, in which two stars orbit a common center of mass. Our best estimates of how much mass stars have come from observations of binaries. We find that massive stars have far shorter lives than low-mass stars....
31 min
47: Star Clusters, Ages, and Remote Distances
Star clusters are gravitationally bound groups of stars that are all about the same age and the same distance from Earth. Astronomers can determine the approximate ages of clusters. This lecture also explains how the distance of extremely remote stars is found....
31 min
48: How Stars Shine-Nature's Nuclear Reactors
When the central temperature of a contracting cloud of gas grows sufficiently high, it becomes a star-a gigantic, controlled, thermonuclear reactor, fusing hydrogen into helium and maintaining a constant luminosity and size....
30 min
49: Solar Neutrinos-Probes of the Sun's Core
Physicists had long assumed that nuclear fusion occurred in the Sun's core, though without a way to physically measure or observe this. Ghostly particles called neutrinos provide direct evidence of events in the Sun's nuclear furnace....
31 min
50: Brown Dwarfs and Free-Floating Planets
Brown dwarfs are low-mass objects whose dim glow is caused by slow gravitational contraction and the fusion of deuterium, a heavier but far less abundant isotope of hydrogen. Free-floating planets have even less mass than brown dwarfs and are not associated with any star....
31 min
51: Our Sun's Brilliant Future
As it gradually uses up the hydrogen in its core, fusing it to helium, the Sun will expand to form a red giant star. Through a series of relatively nonviolent eruptions, it will expel its outer layers of gas, producing a beautiful, glowing nebula around the dying core....
31 min
52: White Dwarfs and Nova Eruptions
The burned out Sun will eventually contract into a white dwarf. This is the fate of all stars between roughly 0.08 and 8 solar masses. A white dwarf in a binary system may steal matter from its companion star and flare up in an eruption called a nova....
31 min
53: Exploding Stars-Celestial Fireworks!
A few stars end their lives with cataclysmic explosions, expelling gas at huge speeds. At its peak, such a supernova can rival the brightness of an entire galaxy, and its remnants can be seen for centuries. The Crab Nebula is one such remnant....
31 min
54: White Dwarf Supernovae-Stealing to Explode
Supernovae come in several types, based primarily on their spectra. This lecture focuses on the important, hydrogen-deficient subclass called Type Ia, in which a white dwarf robs gas from its companion star and then becomes violently unstable....
31 min
55: Core-Collapse Supernovae-Gravity Wins
Type II supernovae, whose spectra exhibit hydrogen, come from massive supergiant stars whose core suddenly collapses, ejecting the rest of the star. This mechanism also applies to "stripped" stars that had previously lost their outermost layers through winds and transfer to companions....
31 min
56: The Brightest Supernova in Nearly 400 Years
In 1987 a Type II supernova only 170,000 light years away became visible. Earlier photos of the region showed that the exploded star was a blue supergiant, a previously unsuspected candidate for this fate. Ghostly neutrinos were detected from this supernova....
31 min
57: The Corpses of Massive Stars
The imploding core of a Type II supernova typically forms a bizarre, enormously compact object called a neutron star, consisting entirely of tightly packed neutrons, a teaspoon of which would weigh about a billion tons....
31 min
58: Einstein's General Theory of Relativity
Understanding the enormous gravitational fields of neutron stars requires Einstein's general theory of relativity, which postulates that gravity is a manifestation of the warping of space and time produced by matter and energy....
32 min
59: Warping of Space and Time
This lecture explores observational tests of general relativity. Astronomers exploit its effects by searching for distant objects that are gravitationally lensed, which occurs when an object's light is bent and focused by foreground masses such as galaxy clusters....
31 min
60: Black Holes-Abandon Hope, Ye Who Enter
If a neutron star exceeds two to three solar masses, it becomes unstable and collapses. The resulting object is called a black hole-a region of such extreme space-time curvature that nothing, not even light, can escape....
32 min
61: The Quest for Black Holes
Because they don't emit any light, black holes can't be seen directly. But they reveal their presence through their gravitational influence on other objects. This lecture looks at the methods astronomers use to track them down....
31 min
62: Imagining the Journey to a Black Hole
What's a black hole really like? Without taking the fatal journey into one, astronomers can calculate the bizarre experiences that would ensue, including dramatic distortions in visual phenomena as a traveler approached the event horizon....
31 min
63: Wormholes-Gateways to Other Universes?
Rotating black holes appear to connect our Universe to others or provide shortcuts-or wormholes-within our Universe. This raises the theoretical possibility of time travel, although several factors seem to rule it out....
32 min
64: Quantum Physics and Black-Hole Evaporation
Originally, astronomers thought that black holes were truly black, but physicist Stephen Hawking has calculated that black holes slowly evaporate through a quantum mechanical process. Very small black holes should literally explode as a burst of gamma rays!...
31 min
65: Enigmatic Gamma-Ray Bursts
Roughly once per day, somewhere in the sky, there is a short, intense burst of gamma rays. Most of these events originate in very distant galaxies, making them among the most powerful explosions in the Universe-but they are not evaporating black holes....
31 min
66: Birth Cries of Black Holes
Until recently, astronomers had no smoking gun to identify the precise location and cause of gamma-ray bursts. Now they have assembled an abundance of clues pointing to two separate mechanisms: the collapse of a massive star, and the merging of two neutron stars-in each case creating a black hole....
31 min
67: Our Home-The Milky Way Galaxy
Starting a series of lectures on galaxies, you begin with our home galaxy, the Milky Way. The band of light by that name is simply the Galaxy seen edge-on from our place within it. You also explore the nebulae in our Galaxy, many of which are regions of stellar birth....
30 min
68: Structure of the Milky Way Galaxy
How do you map the structure of a galaxy when you live inside it? Astronomers have used various clues to infer the spiral structure of the Milky Way, the orbital speed of its stars, and the existence of a supermassive black hole at its center....
30 min
69: Other Galaxies-"Island Universes"
The discovery of other galaxies beyond the Milky Way was one of the great scientific detective stories of the early 20th century. Astronomers now know that there are hundreds of billions of galaxies, spanning billions of light years of space....
31 min
70: The Dark Side of Matter
Until a few decades ago, astronomers thought that galaxies were composed primarily of stars. There is now strong evidence that most of the mass of galaxies may be invisible dark matter. Clusters of galaxies are also dominated by dark matter....
31 min
71: Cosmology-The Really Big Picture
This lecture starts the study of the Universe as a whole-or cosmology. A key finding made by Edwin Hubble in 1929 was that the spectra of distant galaxies are redshifted more than those of nearby galaxies, suggesting that the Universe is expanding....
32 min
72: Expansion of the Universe and the Big Bang
The Universe can be thought of as expanding into a mathematical dimension to which we have no physical access. Even an infinite Universe can expand, becoming less dense. The expansion suggests that there was a hot, dense beginning long ago-a Big Bang....
32 min
73: Searching for Distant Galaxies
The finite speed of light allows observers to look back in time and see the unfolding history of the Universe. This lecture shows how astronomers search for distant galaxies to compare with better understood, nearby galaxies....
31 min
74: The Evolution of Galaxies
How do galaxies form and evolve over time? Is it possible to determine what nearby galaxies, or even the Milky Way, once looked like? The answers can be found by examining distant galaxies that formed when the Universe was young....
31 min
75: Active Galaxies and Quasars
The central regions of many galaxies go through an active, very luminous phase early in their development. The most powerful of these active galaxies, called quasars, shine like beacons across billions of light years of space....
32 min
76: Cosmic Powerhouses of the Distant Past
The high luminosity of quasars puzzled astronomers in the 1960s. How could these peculiar, star-like objects be so bright and yet so far away? Only a few light years across, they are in fact even more powerful than entire galaxies....
31 min
77: Supermassive Black Holes
Astronomers now have strong evidence that quasars and other active galactic nuclei are powered by supermassive black holes, voraciously swallowing surrounding material. Less active galaxies also appear to harbor these monsters....
32 min
78: Feeding the Monster
This lecture explores the disks of gas around supermassive black holes. Material escaping from the vicinity of these objects often follows a highly focused jet along the rotation axis of the disk, sometimes approaching or even appearing to surpass the speed of light....
32 min
79: The Paradox of the Dark Night Sky
Why is the sky dark at night? In an infinitely old and large Universe the sky should be ablaze with light at all times. There are several possible answers to this paradox, each of which has profound cosmological implications. The relative youth of the Universe is now known to be the main explanation....
32 min
80: The Age of the Universe
How old is the Universe? The Hubble Space Telescope was designed, in part, to answer this question. You follow the chain of reasoning that has led astronomers to conclude that the Universe began 13.7 billion years ago....
31 min
81: When Geometry Is Destiny
According to general relativity, the fate of the Universe is tied to its global geometry. If the Universe has positive curvature, like a sphere, it must eventually collapse in a "Big Crunch." If it is flat or has negative curvature, however, it will expand forever....
31 min
82: The Mass Density of the Universe
This lecture explores methods used by astronomers to determine the mass density and expansion history of the Universe. To make this measurement, a race developed between two teams of astronomers searching for Type Ia supernovae in distant galaxies....
32 min
83: Einstein's Biggest Blunder?
The unexpected finding that the Universe is expanding at an ever-faster rate lends support for the existence of a non-zero cosmological constant, a formerly discredited idea of Einstein's, which he once called his "biggest blunder."...
31 min
84: The Afterglow of the Big Bang
An accidental discovery in 1965 overturned the "steady-state theory" of the Universe, an alternative to the Big Bang theory. The detection of a uniform microwave "glow" in all directions was exactly what was expected if the Universe was hot and dense long ago....
31 min
85: Ripples in the Cosmic Background Radiation
The cosmic microwave background radiation preserves intriguing details about the Universe around 380,000 years after the Big Bang, when the temperature had cooled enough so that neutral atoms formed, allowing photons to pass freely through space....
31 min
86: The Stuff of the Cosmos
The dark energy that is causing the expansion of the Universe to accelerate makes up about 75 percent of the cosmos. Visible matter accounts for less than 1 percent. The bulk of the remainder is dark matter, most of which may consist of exotic subatomic particles....
32 min
87: Dark Energy-Quantum Fluctuations?
According to one idea, repulsive dark energy having a negative pressure might be the result of a non-perfect cancellation of quantum fluctuations in space-virtual particles created literally out of nothing, as predicted by quantum physics....
31 min
88: Dark Energy-Quintessence?
This lecture looks at problems with the quantum fluctuations explanation for dark energy. One alternative is called quintessence?-a class of models that postulate repulsive energy that may be associated with unified forces or fields....
32 min
89: Grand Unification & Theories of Everything
A major effort is underway to unify the mutually inconsistent theories of general relativity and quantum mechanics into a theory of everything. Successfully explaining dark energy might serve as an observational test for such a theory....
32 min
90: Searching for Hidden Dimensions
The leading contenders for a theory of everything are string theories, which postulate that fundamental particles act like tiny, vibrating strings of energy. This approach requires at least 10 dimensions, most of which are curled up on minuscule size scales....
32 min
91: The Shape, Size, and Fate of the Universe
Is the Universe a finite bubble in a higher-dimensional space? Or, is it infinite regardless of whether it's imbedded in extra dimensions? Will it expand forever or ultimately recollapse? If it does expand forever, how will this limitless future unfold?...
32 min
92: In the Beginning
This lecture turns back the clock to almost the moment of creation-a fraction of a second after the Big Bang-and follows events as they sort themselves out, from what may have been packages of space-time foam winking in and out of existence, to conditions conducive for star and galaxy formation....
32 min
93: The Inflationary Universe
The remarkable large-scale uniformity and "flatness" of the Universe pose a problem for the standard Big Bang theory. A startling but powerful suggested explanation is that the Universe went through an initial period of exponential expansion, called inflation....
32 min
94: The Ultimate Free Lunch?
Why should inflation have occurred? Theorists have proposed several intriguing ideas, including that the Universe, whose total energy is quite possibly equal to zero, formed from a random quantum fluctuation that grew to gargantuan proportions....
32 min
95: A Universe of Universes
If a quantum fluctuation gave rise to our Universe, must ours be the only one? Are others possible, perhaps even with different rules? This lecture examines reasons for suspecting the existence of other universes, though we do not know how to test for their presence....
32 min
96: Reflections on Life and the Cosmos
The course ends on a philosophical note, with reflections on intelligent life in the cosmos and of our place in its grand structure. Perhaps the most astonishing thing about the Universe is that we are able to contemplate and understand it through systematic studies....
38 min
