Tuesday, May 28, 2013

The solar system. By Tzur Almog 5/24/13

Today I will be teaching you about the solar system. But before I tell you about the solar system I have to tell you how it formed. Our galaxy was originally a nebula floating around in space. As we drifted we were hit with a shockwave compressing the floating ball of gas. Even after the shockwave wore off the nebula continued to collapse in on itself as some off the gas particles had hit each other and were now creating their own gravitational field. As these masses grow their gravitational fields get larger they suck in more mass. Then finally the largest mass, (the one in the center) reaches the ignition point where hydrogen is put under enough pressure to fuse. Once it does it unleashes a waves of radiation that we call solarwinds. These solar winds blew all the dust and gas off the inner planets and out into the kuiper belt outside the 8 planets. The outer planets were not hit with as much solar wind so they remained gassy. Today we call them the gas giants. Today we have split the planets into two groups, the rocky planets and as I said before, the gas giants. The rocky planets are the densest and the spin the slowest, but because they are the closest to the sun they revolve around the sun the fastest. The gas giants are farther away from the sun and are the least dense. That just about sums up the creation of the solar system.
http://static.ddmcdn.com/gif/asteroid-belt-2.jpg






Here are a couple of quick facts about the planets:
Mercury can also get up to 800 degrees in the day. It is also the smallest planet in the solar system.
http://upload.wikimedia.org/wikipedia/commons/thumb/3/3f/Mercury_Globe-MESSENGER_mosaic_centered_at_0degN-0degE.jpg/270px-Mercury_Globe-MESSENGER_mosaic_centered_at_0degN-0degE.jpg

Venus is the hottest planet in the solar system. It was also named after the roman goddess of love.
http://upload.wikimedia.org/wikipedia/commons/thumb/8/85/Venus_globe.jpg/220px-Venus_globe.jpg

The red surface of mars is caused by rust in the soil because of high levels of iron. Mars used to be volcanically active but isn't anymore because its core has cooled down to the point where it has solidified.
http://static.ddmcdn.com/gif/mars1.jpg

Jupiter has a giant red spot that is a massive storm that has been going on for a long time. It’s magnetosphere is also larger than the sun.
https://upload.wikimedia.org/wikipedia/commons/thumb/b/b6/Jupiter_gany.jpg/220px-Jupiter_gany.jpg

Saturn has auroras on its poles like we do on earth. Saturn also has 62 moons in addition to the rings of ice and rock it has.
http://nssdc.gsfc.nasa.gov/image/planetary/saturn/saturn.jpg

Uranus has an atmosphere mostly made up of methane. It is also the only planet to be on a nearly 90 degree angle.
http://upload.wikimedia.org/wikipedia/commons/thumb/3/3d/Uranus2.jpg/240px-Uranus2.jpg

Neptune also has an atmosphere mostly made out of methane. Neptune's Magnetosphere is created by ice at its core and not iron.
https://encrypted-tbn0.gstatic.com/images?q=tbn:ANd9GcQuS0aa9xKimNeyJgDdcSM_KM4hD6OGIUHp7_fBxwDPuLVa6WyX

The rocky planets rotate around the sun faster than the gas giants because the rocky planets are closer to the sun than the gas giants. Because the sun is closer to the rocky planets they are slingshotted around the sun faster by gravity. The closer they are the faster they rotate.
However there is one thing that unites all of them, they are all planets. And as a planet they each follow the rules for being a planet. They all: orbit the sun, are nearly round in shape, and have cleared the area around them. This however will soon bring us to the term dwarf planet as people see that pluto is missing. Dwarf planets are basically the same as planets but cannot clear their own area. Pluto, Ceres, and Eris are all examples of dwarf planets.

Thanks for reading my blog.

Friday, May 24, 2013

Jupiter's Rings and Moons by Alex B.

Jupiter has a lot more to it than a huge orangey-red ball with a big dark red spot on it, lets take a look at it closely:

There are 67 known moons of Jupiter. Like Saturn, Jupiter has rings too, although they are not as visible as saturns. These rings were produced by micro meteoroids hitting the inner moons and blasting off dust, and this process must keep happening for Jupiter to keep having it’s rings.





A Picture of Jupiter and the Galilean Moons



A picture of Jupiter's ring system, mostly debris.



A shepherd’s moon is a moon that orbits through the rings of that planet. These moons create the “layers” in the rings, which are most easily visible on saturn.



This is actually a picture of Saturns Shepherd moons, but make it much easier to understand what a shepherd moon is.



Io is a very neat planet. It has volcanos, which erupt lava, dust, and gases into space. Io is also the most volcanically active object in the solar system. It is believed to have a metallic core. It’s surface is mostly made up of plains, although there are mountains that reach up to 9km high.


This is an image of Io. You can almost tell where the mountains and plains are!


Europa, another neat moon of Jupiter’s. It is the 15th largest object in our solar system, making it bigger than pluto! It also takes 3 and ½ earth days for it to revolve around Jupiter. It has a surface temperature of about 260 degrees fahrenheit at the equator. There is a theory about life on Europa as well, which is yet to be disproven, or proven for that matter. Some scientists believe this because it has hydrothermal vents similar to Earth’s. This could be a possible habitat for micro-organisms such as barteria.



Europa, Although not visible, has underground water that could harbor life.


A third moon of Jupiter is called Ganymede. It is the largest moon in the entire solar system. It’s surface is roughly half silicate rock and half water ice. It’s core is believed to be a liquid iron core. It also has a thin oxygen atmosphere, possibly containing O, O2, and O3.



It's hard to tell, but this surface has 50% ice water covering it!


Callisto, The final moon I will talk about, is 99% the size of mercury. It is spotted by the hundreds of craters from meteor impacts. This moon has a small atmosphere containing mostly carbon dioxide and has a relatively intense ionosphere. There is a high chance that there is a ocean inside of Callisto.



Callisto as you can tell is consistently bombarded by meteors.


The Galilean Moons are the four moons that were discovered between 1609 and 1610. These moons were named after the lovers of Zeus. These moons were the first objects to be found that didn’t orbit earth (or so they thought at the time) which leads to disprove the whole “the universe revolves around Earth” business.



A size visual of all the Galilean Moons compared Jupiter


Thanks for reading my blog!

Comets By Jake Haase

This is comet Halley.

This is a comet that shows the Nucleus, Coma, and both tails. 

The nucleus is made up of rock, water ice, frozen gases, methane, ammonia, and dust. The nucleus ranges from 100 meters to 40 kilometers. The nucleus is the center of the comet, so for a comet to form a nucleus must form first. The coma is formed when the the comet goes around the sun. As the comet goes around the sun the sun melts ice and dust particles forming the cloud around the comet. The coma is made up mostly of ice and dust. The coma ranges in size depending on size of comet. Comets typically have dust tails. The two dust tails form when the comet gets close to the sun. As the comet goes near the sun the heat melts part of the comet just like how it forms the coma. Instead of just staying around the nucleus, the ice and dust particles are released from the comet and fade behind it. 

As you click on this simulation/animation it shows the orbit of a comet that you customize. The animation shows what comets do as the approach and leave the sun. When the comet is closer to the sun, orbiting around the speed increases because there is a higher gravitational pull the closer it is. As the comet approaches the sun a tail and coma is formed. The tail and coma are formed from the suns intense heat. Since the comet orbits around the sun and since there is a gravitational pull the tail always faces away from the sun. As the comet starts to leave the sun it slows down and the tail and coma get smaller.





As you look at this image you can see the Kuiper Belt. The Kuiper belt is a region of the solar system from the the orbit of Neptune (30 AU) to around 50 AU from the sun. The Kuiper belt consists of "extra parts" from the solar system. Everything that was used to make planets and other objects goes into the Kuiper belt. The Kuiper belt has asteroids that composed of frozen volatiles. The Kuiper belt also has at least three dwarf planets and multiple moons. Studies have shown that the belt is dynamically stable. Pluto is member of the Kuiper belt. The Kuiper belt has continually gained more objects over years and is going to continue to get more.


This image shows the Oort Cloud. The Oort Cloud is a hypothesized spherical cloud of predominantly icy planetesimals that is around a light year from the sun. The outer edge of the Oort Cloud defines the cosmographic boundary. The Oort Cloud is thought to be divided into two separate regions: a spherical outer and a disc shaped inner core. The Oort Cloud (at least a little bit) is the product of the sun and its sisters stars exchanging material then drifting away.


Here is an Image of Pluto. Pluto resembles a comet. Pluto resembles a comet for a lot of reasons. One resemblance between Pluto and a Comet is that Pluto is in the Kuiper Belt. The Kuiper Belt has at least two other dwarf planets, but mostly has a ton of comets. Pluto is also like a comet because of the path they take. Pluto does not take the normal path of planets but has a different angle from the sun, like comets.



Moons and Rings of Jupiter By: Kate E

Most people know of the famous gas giant, Jupiter.  It's a tan color with many different patterns that can be seen below. It is the biggest planet in our solar system with a surface area of 23.71 billion square miles. It is located just after the meter belt separating the gas planets from the rocky.

One of the most famous qualities of Jupiter is the moons that orbit it. Jupiter has 50 named moons
according to NASA. Jupiter's moons are very different and unique. Some have very circular paths of orbits while others have oval or ellipse shaped orbit paths.Below you can see the complicated orbital patterns of the moons. 

 Jupiter also has a ring that's made up of three main parts. The main ring (part) is 7,000 kilometers wide but ends sharply about 129,130 kilometers from the center of the giant planet.Within the main ring is the orbital path of two of Jupiter's many moons, Adrestea and Metis.  In between the main ring and cloud tops of the giant planet is an area known as the "Halo", it consists of a mixture of material and its about 20,000 kilometers thick.  The final part of the ring is a part called the "Gossamer".  It is made of tiny particles of dust and is only about 10 microns in diameter. Just for comparison a human hair on average is 75 microns across. The Gossamer exists from 129,000 kilometers from the center of the planet to 30,00 kilometers from the center.  It like the main ring has two moon's paths in it, Amalthea and Thebe.


It might seem like the rings are huge, but they are really very faint and can barely be seen without direct sunlight. This is because they are all made up of dust particles. Scientists  believe the rings were formed and continue to be supplied by small meteor crashes with Jupiter's moons. When the meteor crashes the dust is disrupted and thrown into space it then collects due to Jupiter's gravity and forms a ring. Scientists believe this because of all the moon orbital paths that exist in the rings.  Below you can see the parts of the ring and the moons the obit within them.


Adrestea, Metis, Amalthea and Thebe all have something in common. They are all shepherd moons, meaning moons inside or very close to a planet's rings (in this case Jupiter's). A shepherd moons does many things but one very important thing it does is help the rings keep their shape and form, as well as "sweeping" up ant debris that happened to float in the way.  It does this by using the it's strong gravity the acts like a ejection system because when something comes within range of it, it is thrust away. Below you can see a shepherd moon inside a ring and the gap it's gravity is creating. 




422,000 kilometers from Jupiter a moon called Io orbits. Io is very unique like many moons. It is the most volcanically active object in the solar system. It is so active that the volcanic plumes from the  over 400 volcanoes at the surface, rise up to 190 miles high. Some of the many volcanoes erupt molten rock but others erupt molten sulfur compounds. The volcanoes erupting molten sulfur compounds cause the color and color change of the planet that can be seen in the picture below. The volcanic activity on Io is due to the sub-surface liquid that is so hot and constantly moving to try and reach the surface to relive the heat and pressure. Due to the constant moving of the liquid, holes created by craters are always filled. 

Io is also the third largest known moon of Jupiter and is fifth known moon from the planet.
Also because Io is so close, the giant moons known as Europa and Ganymede the throw off its orbital path so it's path has the most drastic change in its distance from Jupiter.  Because of this drastic change Io has very extreme tidal bulges. The bulges that can be up to 330 feet of solid ground bulging. 

Scientist believe that the core of Io is Iron, the atmosphere is sulfur dioxide, and it is mostly made of either molten sulfur and it's compounds or silicate rock. Io is also cuts through the magnetic lines of Jupiter. This means that Io acts like an electric generator. Sometimes the planet holds up to 400,000 volts of across it. It also can create a current of up to 3 million amperes that travels to Jupiter's upper atmosphere resulting lots of lighting. 

Io in the roman  myths was the daughter of Inachus. The planet got the name Io because Jupiter (in the myths)  loved Io, so the planet closest to Jupiter naturally would be Io.



                 


Another moon of Jupiter is Europa. Europa is a little smaller than our moon and is phased locked meaning the same side of Europa always faces Jupiter. It revolves completely around Jupiter every 3 and a half days.

Europa is thought to have an iron core surrounded by a rocky mantle with a complete surface covered in salty ocean water. The ocean is very deep however due to the fact Europa is so far from the sun the ocean surface is always completely frozen over.

Europa has an eccentric orbit meaning that it revolves Jupiter in a non-circle way. Due to the eccentric orbit the tides on Europa change drastically causing major shifts is the ocean water beneath the layer of ice resulting in cracks.

Another interesting thing the eccentric orbiting causes is the heating of the planet more than it would normally be. Jupiter heats itself more than it gets warmth from the sun so it can heat Europa and it's surface oceans.

Because Europa has an icy surface, with more than twice as much water as we have in our own ocean, it is thought by scientist to be a possible home for life. Under the ice may be the key to alien life forms.  "Europa has the liquid water and elements, and we think that compounds like peroxide might be an important part of the energy requirement. The availability of oxidants like peroxide on Earth was a critical part of the rise of complex, multicellular life." says Kevin Hand of NASA. What Hand is saying is that we know Europa has two of the three key ingredient needed for life to form and or exist.



Ganymede is the another very interesting moon of Jupiter. It is the 7th moon from Jupiter and the largest moon in the solar system.  Ganymede has a rotation speed of 7.115 days and a year length of about 7.15455296 Earth days.

 As mentioned before Ganymede the largest moon in the solar system. It is bigger than Pluto and Mercury! If it were not revolving around Jupiter and instead around the sun it would easily be classified as a planet. It has a volume of 76,304,506,998 kilometers cubed and a density of 1.942 g/cm cubed.

Ganymede has three general layers, the first or outer layer is an ice shell, its very thick (thought to be around 497 miles thick). The next layers are a rock like layer surrounding the metallic iron core.

Although Ganymede is not thought to be able to support life, astronomers found some evidence of what's thought to be an extremely thin oxygen layer. As well as oxygen evidence, irregular lumps have been discovered under the very icy surface of Ganymede. The lumps are probably rock formations of some kind that are either suspended by the very strong thick ice that has been frozen for the life time of the planet or are formations at the bottom on the ice layer.

Callisto is the third biggest moon in the solar system with a volume of 58,654,577,603 km cubed. It's about the size of Mercury.

The interior of Callisto is thought to consist of an inner rocky core and an outer core or mantle of ice. The surface is twice as bright as our own moon!

It like most moons recives craters however it is the most crater object in our solar system. Due to it's very thin atmosphere.

 One interesting fact about Callisto is that it has the oldest known landscape in the solar system dating back around 4 billion years ago. It is thought to be "long dead" meaning it is thought not to have any geologic movement or changes.



The first four moons of Jupiter discovered were Io, Eurpoa, Ganymeade, and Callisto. They are known as the Galilean moons because, they were discovered by the famous astronmer Galileo Galilei in 1610.  He found the moons after he improved his telescope and the moons lead to his theory (now known fact) that all planets including the earth revolved around the sun. The moons are also the four largest moons of Jupiter, they are all larger than Pluto.  Below you can see the Galilean moons in the order they are from the Jupiter.



Stellar Evolution by RockonBen (Ben Shapiro)


An HR Diagram stands for Hertzsprung-Russell Diagram. It shows the luminosity of stars compared to their temperature. The sun, our own star, is at 1 luminosity. As you go left or right along the scatterplot, you are determining the temperature. If you go up or down, you are determining the luminosity. The stars are also color-coded based on the temperature of it – as you can see, if it is lighter, it is hotter, if it is darker, it is cooler. This also surprised me because regular small-size stars, like our sun, range from a large variety of brightness and temperatures. The white dwarfs also are darker, but the temperature is usually quite high. Finally, giants and supergiants are larger and emit more light (obviously), but they are at the low-end of the temperature scale. 

 
 
All stars begin their lives in a stellar cloud with protostars, as seen above. It either becomes a small star or gains enough mass to become a large mass star. I’ll start with a small star. A whopping 90% of the activity going on inside the core is fusion of elements, because gravity squeezes the core so intensely. Due to this, energy from fusion balances out the squeeze of gravity. Fusion with hydrogen turns to helium (combine H (1 proton, 1 neutron) plus another one gives you He (2 protons, 2 neutrons)). This sinks to the center to form a helium inner core. Then at 100,000,000K, helium fusion starts, with 3 helium combining to make 1 carbon. This is now a red giant. Now there is an outer layer of hydrogen fusion, an inner layer of helium fusion, and finally an inner core of solid carbon. But now, the temperature cannot get high enough for carbon fusion which causes the core to compact. However, electrons prevent further compaction of the core. The outer layers slowly puff away, and as it does, the inner parts of it leave behind a planetary nebula, and eventually it becomes a white dwarf. This leads me into my next section.

A white dwarf is the last stage of a low-mass star’s life. These are very dense, but not as dense as a Neutron star. They are about as dense as the sun, and as big as the Earth. They are composed of electron-degenerate matter, which means it burns off the matter as time goes on. Over a very long time, it will grow darker and darker until it is no longer visible, or a black dwarf.

Large mass stars work in a completely different function, such as red giants. H fuel in the star becomes low very quickly, making the star red and swollen, hence the word “red” in “red giant”. He fusion begins extremely quickly and builds up a layer of solid carbon. The outer layers expand like in a low-mass star, and compress the core until electrons try to resist. However, this is where large-mass stars stand out. It bypasses the resistance of the electrons, compressing the core even further. Finally, it compresses the core so hard that carbon fusion starts which forms oxygen. Then suddenly, a chain reaction fusion process uses up the previous fuel incredibly quickly to make multiple different layers. (To be specific, O to Ne to Mg to Si to Fe, and Fe (iron) is the last product made. Having this be the last product made, gravity squeezes the core. Instantaneously, in a fraction of a second, this core (about the size of Earth) is reduced to the size of Brooklyn, NY. The weak force instantly turns protons into neutrons (hence the term neutron star) and releases neutrinos. Then, in the next thousandth of a second, the neutrons crystallize, the core explodes at 20% the speed of light and slams into the outer layers, creating a supernova that creates a massive shockwave which rips the outer layers to shreds. In the explosion, much heavier elements such as silver, gold even uranium are made by the fusion. The cloud from the explosion does not dissipate for thousands of years, but when it does, the new neutron star is revealed.

A Neutron Star might be one of the strangest stars in the universe. It forms from a supernova of a star that has a solar mass of 1.5-3. (In other words, it doesn’t form from the small mass stars but not from the biggest high-mass stars.) As it collapses, it gains so much mass because the supernova turns the whole star into one incredibly dense ball. Its mass is typically 500,000 times more than the mass of the Earth, with the diameter only the length of my dad’s birth town – Brooklyn, NY. These also have insanely powerful magnetic fields – charged particles can spiral down to the surface through it. They spin rapidly, up to 1000 rotations a second.

 

A Pulsar is a neutron star that happens to emit radio waves that cross Earth’s path. This name really comes from the word “pulse” because it emits electromagnetic radiation in short bursts. In order to see it from Earth, the radio waves would have to be pointing at Earth. This is like a lighthouse at night – you can only see it when the light is facing towards you. The link below is a movie about what this is.


Thanks for reading my post - RockonBen

What are black holes? by Andrea Ponce

Recently we have done an assignment on itslearning about stellar evolution and black holes. Black holes are a place where an object's gravitational pull is very strong because a much larger object has been compressed very small in comparison. Here the gravitational pull is very strong that the only things which would escape it's grip would be something with a speed greater than light which is impossible, at least so far to our knowledge. In a black hole there is a singularity, an event horizon, an accretion disk, and a jet. The singularity is at the center of the black hole, there at its center there is an infinite density but a volume of zero, at the singularity the laws of physics break. The event horizon is what surrounds the black hole in a way the black holes edge. There is where light disappears, nothing can be seen and nothing can escape, it is known as the point of no escape. The acceleration disk is where bright matter being sucked into the black hole surrounds it. It "feeds" the black hole but is dimmed when there is nothing left to "feed" the black hole with. The jet/jets are produced from the black hole and are powered by the energy of the spinning black hole and interactions with the acceretion disk.


Space time is a measure of change that would happen over a period of time in space. It puts two concepts together in one continuum, "something that is continuous and the same throughout it is usually thought to be a series of elements or values which are only different by small small amounts". It is putting together our knowledge of the three dimensions, height, width, and depth with time in a mathematical model.
In class we did as I said an activity in which we saw through a simulation how stellar black holes are formed. This is when a star falls on itself at the end of its life. This happens to suns much larger than ours when they stop being able to have enough energy to use fusion to keep from letting the gravity compress it and turn into a red giant then a supernova. See when it turns into a Red giant we learned that even though on the outside the appearance is greater than before that on the inside gravity starts to do its magic and starts compressing the core making it hotter and denser stopping gravity's force for a short while. The star has then nothing left to use for fusion so that its temperature rises crushing all the atoms left together. 
the repulsive force that is happening between the nuclei is overcome by gravity so the core first compresses then falls back under pressure and a shock wave is processed. Material is heated and fusion makes new elements which get exploded out into space, these being the supernova. Not even the neutrons of the old star remain.


The black hole in the center of our galaxy is a super massive black hole. It is known as an area named Sagittarius A. Its radius is 6.25 light hours or a little less but it contains 3.7 million solar masses. Some evidence for this is center stars which seem to be orbiting around nothing. Which according to the rules of science cannot happen it has to be something large with a heavy gravitational pull. The object that they seem to be circling would be too small to contain that much of gravitational pull if it wasn't a black hole considering it itself is not pulled by anything. Also radio waves have been found projected/ released from that area.
http://scienceblogs.com/startswithabang/files/2012/05/Black_Hole_Milkyway.jpeg
Links:
http://www.nbcnews.com/id/46968468/ns/technology_and_science-space/t/scientists-closing-black-hole-center-milky-way/#.UZ84erWTh-0