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| courses:ast100:4 [2024/11/23 05:04] – [1. Birth of the Solar System] asad | courses:ast100:4 [2024/12/14 09:41] (current) – [4. Detecting Planets] asad | ||
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| - | **Hermes:** Yes, that’s shown with arrows in the last panel of my diagram. Red arrows indicate how asteroids are being flung into the asteroid belt by collisions among the inner four planets, while gray arrows show how CC-type asteroids from the outer four giant planets are entering the belt. This process created the asteroid belt. | + | **Hermes:** Yes, that’s shown with arrows in the last panel of my diagram. Red arrows indicate how asteroids are being flung into the asteroid belt by the influence of the inner four planets, while gray arrows show how CC-type asteroids from the outer four giant planets are entering the belt. This process created the asteroid belt. |
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| //[Half an hour passes for our eight characters, during which 300 million more years of the solar system’s history unfold. Suddenly, the entire solar system is thrown into turmoil.]// | //[Half an hour passes for our eight characters, during which 300 million more years of the solar system’s history unfold. Suddenly, the entire solar system is thrown into turmoil.]// | ||
| - | **Juno:** What’s happening? The entire solar system seems to be in a massive war. Because we’re experiencing time so quickly, the intensity of the chaos feels overwhelming. Planetesimals are crashing onto nearly all the planets and moons. Are the fragments of rocks, soil, and ice that failed to form planets or merge with any planet seeking revenge on them? | + | **Juno:** What’s happening? The entire solar system seems to be in a massive |
| **Hermes:** This is called the Late Heavy Bombardment. Those that couldn’t form planets near the soot and frost lines have ended up in the asteroid belt, while those near the CO snow line became part of the Kuiper Belt. Their bombardment on planets and moons will continue for another half hour in our time—that’s 300 million years. | **Hermes:** This is called the Late Heavy Bombardment. Those that couldn’t form planets near the soot and frost lines have ended up in the asteroid belt, while those near the CO snow line became part of the Kuiper Belt. Their bombardment on planets and moons will continue for another half hour in our time—that’s 300 million years. | ||
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| - | Let me know if you'd like the continuation or any other adjustments! | + | ===== - Solar System ===== |
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| - | ===== - Solar System ===== | + | **Hermes:** Since not all objects are equally bright, you cannot see everything in the solar system with the naked eye. I have shown the current state of the solar system in this image using three successive scales. On the largest scale, the solar system is actually a vast cloud made up of billions of icy fragments. Due to the gravitational influence of the four giant planets that formed near the frost line, most of the carbonaceous ice fragments between the frost line and the CO snow line were ejected from the solar system. However, they couldn' |
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| - | {{: | + | **Socrates:** Zooming in, I see two images below. On the left, there are the four outer planets, the Kuiper Belt, and the heliosphere. On the right, there' |
| + | **Hermes:** From the Sun, a continuous stream of charged particles like electrons and protons flows out across the solar system. This flow is called the **solar wind**, literally "the Sun's wind." Beyond the Kuiper Belt, this wind can no longer travel far because it slows down due to interaction with the interstellar wind from other stars and eventually stops. The boundary where the solar wind stops is called the **heliopause**, | ||
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| + | **Hermes:** Just as a ship moving quickly in the sea creates a bow-shaped wave in front of it called a **bow shock**, the Sun creates a similar bow shock as it moves through the interstellar medium. The interaction between the solar wind and the interstellar wind creates this phenomenon. The solar wind spreads equally in all directions from the Sun, but near the heliopause, the interstellar wind pulls many of the solar wind particles behind the Sun, forming the **heliotail**. Human-made spacecraft have spread across the solar system, with Voyager 1 and 2 even crossing the heliosphere. Just as airplanes move through Earth' | ||
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| + | **Hermes:** As shown in the image above, Venus rotates in the opposite direction, and Uranus rotates while tilted. The cause is undoubtedly some **catastrophic event** in the solar system' | ||
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| + | **Hermes:** Just as we measure distance in AUs, we measure the days and years of other planets relative to Earth' | ||
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| + | **Hermes:** Yes. The inner planets are called **terrestrial planets** or **rocky planets**. Jupiter and Saturn are **gas giants**, and Uranus and Neptune are **ice giants**. All four terrestrial planets have cores made of iron and nickel, surrounded by silicate, meaning a thick layer of rock. The gas giants have cores of iron and rock, surrounded first by water, then by **liquid metallic hydrogen**, and finally by layers of hydrogen gas. The hydrogen layer is much larger than the core; these two planets are about **90% hydrogen**. The ice giants also have iron and rocky cores, but outside their water layers, there is only a layer of hydrogen gas; they lack liquid hydrogen. Ice giants are about **80% hydrogen**. You could say that inside each outer giant planet is a rocky inner planet. The water outside the rocky-iron cores exists in a state that is neither fully solid nor liquid, known as a **supercritical fluid**. However, venturing there would not be wise. | ||
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| + | **Hermes:** Let’s zoom in and travel closer to Saturn. | ||
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| + | **Hermes:** Galileo first observed these rings with a telescope, but it was Huygens from the Netherlands who first understood that they were indeed rings. From here, it’s clear that these rings are not continuous disks but rather a collection of countless ice particles ranging from a few centimeters to several meters in size. Besides water, many of these particles also contain various carbon compounds. These rings extend from about 30,000 km above Saturn’s surface to nearly 150,000 km. Despite a diameter of 300,000 km, the thickness of these massive rings ranges from about 10 meters to a maximum of a few hundred meters. The A, B, C, D, and F rings can be seen here, and the gaps between the rings are named after different scientists. For instance, the gap between the A and B rings is called the Cassini Division and the Huygens Gap; between the B and C rings is the Coulomb Gap, and between the C and D rings is the Maxwell Gap. Maxwell, the founder of electromagnetic theory, was the first to understand that Saturn’s rings are not a single disk but rather a collection of countless small objects. | ||
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| + | **Hermes:** If a moon or asteroid comes too close to a planet, the planet’s gravitational force pulls the near side of the object more strongly than the far side, as gravity decreases with distance. This results in the object being stretched and eventually torn apart into fragments due to the gravitational pull. These fragments then form a ring around the planet. Saturn’s rings were formed in this way. Moreover, if you observe closely, you will see small rocky fragments, about 10–20 km in size, scattered in certain places within the rings. These are called moonlets. Due to these moonlets, spiral structures, similar to spiral galaxies, form within Saturn’s rings. Saturn’s rings and its 62 moons can be compared on one hand to an entire solar system and on the other hand to a spiral galaxy like the Milky Way, with the spiral patterns of the rings resembling those of a galaxy. | ||
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| + | **Hermes:** Why not? Because of the gravity of these moonlets in Saturn’s rings, small waves sometimes form in the ocean of the rings. Waves spread evenly outward from a moonlet. However, since the inner rings of Saturn rotate faster than the outer rings, the inward-moving waves outpace the outward-moving waves. The perfectly circular wave (technically called a __density wave__) becomes spiral due to this uneven velocity, just as a circular ring can be twisted into a spiral pattern. In the case of galaxies, replace the moonlets with nebulas and stars, and replace the ocean of rings with the gases and stars of a galaxy. Since the velocity of stars and gas in galaxies also decreases with distance, the density waves created within galaxies similarly give them their spiral shape. | ||
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| ===== - Earth ===== | ===== - Earth ===== | ||
| + | **Hermes:** If you understand how auroras form on Earth, you’ll understand Saturn’s as well. The solar system is now about 1 billion years old. If we travel from Saturn to Earth, we can see how auroras formed near Earth’s poles even 3.6 billion years before the emergence of humans. | ||
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| + | **Hermes:** In this image, you can see Earth’s atmosphere (the word originates from the Greek ‘atmos, | ||
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| - | {{youtube> | + | **Hermes:** Yes, the distance between the two axes is actually 11 degrees. Earth is indeed a giant bar magnet, and to understand its source, we must examine Earth’s interior. Earth’s structure can be divided into three parts: the core, mantle, and crust. With a radius of about 6,500 km, the crust is only 50 km thick, akin to Earth’s skin. Beneath the crust lies the mantle, about 3,000 km thick, and below that, the core, about 3,500 km thick, is divided into the outer and inner core. The inner core, roughly 1,300 km in size, is composed of solid iron and nickel, while the outer core, about 2,000 km thick, contains the same elements but in liquid form. If we compare the inner core to a furnace, the outer core can be likened to a pot of water on that furnace. As water boils, hot water rises as bubbles, cools, becomes heavy, and sinks again, creating a circular flow called convection. Similarly, the outer core exhibits convection due to the inner core’s heat. This flow of conductive metallic liquid generates convection currents. In the 19th century, French physicist Ampère showed that when electric current flows through a wire loop, a magnetic field is generated perpendicular to the loop’s area. The convection currents in Earth’s outer core act like such loops, and these electric currents are the source of Earth’s magnetic field. |
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| + | **Hermes:** Correct. It’s also important to note that convection currents are not confined to the outer core due to its heat; they are also prominent in another layer. The uppermost layer of the mantle, called the asthenosphere, | ||
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| + | **Ishtar:** I think the movement of plates is better observed from space than on a globe. For now, we should return to the Brahmaputra River by boat. The peace and vastness of the Siang River descending into the Assam valley will give us a sense of tranquility akin to the calm after an epoch of chaos. | ||
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| + | **Hermes:** Meanwhile, watch this video showing how Earth’s major plates have moved over the last 1 billion years. This simulation, published in the journal *Earth-Science Reviews* in 2021, reveals that plates sometimes move slowly, sometimes quickly, sometimes approach each other, and sometimes drift apart. About 500 million years ago, most plates shifted southward, and as they moved northward, nearly all plates merged into a single supercontinent around 300 million years ago, called Pangaea. The combined oceans at that time were collectively called Panthalassa. Over the last 300 million years, the plates have separated again, forming the current seven continents. India’s northward journey toward Asia is particularly clear in the video. | ||
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| + | **Hermes:** No. Mercury, Venus, and Mars don’t exhibit tectonic activity. However, Saturn’s moon Enceladus might have it. | ||
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| + | ===== - Detecting Planets ===== | ||
| + | **Hermes:** Planets gravitationally bound to stars other than the Sun or free-floating in interstellar space are called exoplanets. It’s still unknown whether their crusts exhibit tectonic activity, though more than seven thousand exoplanets have already been discovered. | ||
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| + | **Hermes:** Most planets have been discovered through the transit method. Think of transit as a smaller sibling of an eclipse, as shown in this video. From our perspective, | ||
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| + | **Hermes:** Yes, the larger the planet, the deeper the dip in the light curve. If a star has multiple planets orbiting it, the light curve becomes even more interesting. The video illustrates a system with three planets undergoing transit. Each planet creates a separate dip in the curve. However, since the second and third planets transit simultaneously, | ||
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| + | **Hermes:** No, planets aren’t directly visible. They don’t emit visible light, and the infrared light they do emit is negligible compared to their stars. This is why stars dominate daytime skies on Earth, and similarly, planets around distant stars cannot be directly seen. Only the star is visible, and the planet’s transit is detected through the slight dimming of the star’s light. | ||
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| + | **Hermes:** They do. However, due to the immense distance, it’s currently impossible to distinguish reflected light from the planet itself. Compared to the distance between us and a star, the distance between a star and its planets is incredibly small. This makes it challenging to resolve planets separately using existing telescopic resolution. Images of nearby planetary systems have been captured using " | ||
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| + | **Hermes:** Absolutely. This event is called a secondary transit, as illustrated in this diagram. A primary transit occurs when a planet passes in front of its star, while a secondary transit happens when it moves behind the star. When the planet is to the side, no transit occurs, but phases similar to those of the Moon are observed, with different parts of the planet illuminated by the star. The diagram’s lower panel shows a complete light curve from one secondary transit to the next, along with images of the various phases. The dip from the secondary transit is much shallower compared to the primary transit, so only its upper part is visible here. | ||
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| + | **Hermes:** No, it’s nearly impossible to measure the reflected light of a planet separately. However, an interesting fact is that if a star has orbiting planets, not only the planet but also the star orbits a common center of mass. People assume planets orbit stars, which is only partially true; both planets and stars orbit the center of mass of their planetary system. In this video, the small circle represents the star’s orbit, the larger one represents the planet’s orbit, and their shared center is the center of mass of the system. You can see that the star itself moves, and when it moves toward us, its light becomes bluer (shorter wavelengths), | ||
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| + | **Hermes:** Exactly. This motion of the star is called a " | ||
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| + | ===== - Classification of Planets ===== | ||
| + | **Hermes:** Exactly. From size, we can derive volume, and dividing mass by volume gives density. This figure shows the radius of all discovered planets plotted against their mass. The x-axis represents planetary mass relative to Earth, while the y-axis represents planetary radius relative to Earth. Each bubble represents a planet, and the color of the bubble indicates the discovery method. | ||
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| + | **Hermes:** Yes. A planet on the lower diagonal line has the same density as Earth, meaning its mass per cubic centimeter is 5 grams. Planets on the upper diagonal line have the same density as Saturn, about 0.7 grams per cubic centimeter. Planets between these lines have densities between Earth and Saturn. Planets below the lower line are denser than Earth, and those above the upper line are less dense than Saturn. The discovery methods are also shown here. | ||
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| + | **Hermes:** Not all methods need to be discussed for now. | ||
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| + | **Hermes:** Life is short, and watching rhinos in the Kaziranga National Park along the banks of the Brahmaputra is much more enjoyable than endless study. Look, two rhinos bathing over there. | ||
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| + | **Hermes:** Since we’ve already discussed the classification of galaxies and stars, it’s only fair to talk about planetary classification too. In this scatter plot, the y-axis again shows planetary radius, but the x-axis now shows orbital period instead of mass, meaning the time a planet takes to orbit its star. | ||
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| + | **Hermes:** A planet’s equilibrium temperature is the temperature it would have if it emitted as much energy as it receives from its star. This may differ from its actual surface temperature. For example, Earth’s average surface temperature is 15°C, but its equilibrium temperature is -18°C. The actual temperature is higher because some reflected energy is retained in Earth’s atmosphere due to the greenhouse effect. In this plot, you can see that planets with shorter orbital periods are closer to their stars and thus have higher temperatures (more red-colored bubbles). Those with longer periods are farther from their stars and cooler (more blue-colored bubbles). Kepler discovered the relationship between period and distance 400 years ago, and we met him during the Stellar Age. | ||
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| - | ===== - Detecting | + | **Hermes:** The black diamond icon represents Earth, with a period of 365 days. Planets |
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| - | ===== - Classification | + | **Hermes:** Planets at least twice the size of Earth but smaller than Neptune are commonly called super-Earths. These range from molten-hot to ice-cold worlds. One well-known super-Earth, |
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courses/ast100/4.1732363499.txt.gz · Last modified: 2024/11/23 05:04 by asad