Lab 7 - The Structure of the Solar System Stars and solar systems are formed out

Question

Lab 7 - The Structure of the Solar System Stars and solar systems are formed out of giant gas and dust clouds that gather in space called nebula. The primary elements in the clouds are hydrogen and helium, mostly because in order to create heavier elements through nuclear fusion stars have to be really big or have to undergo a supernova explosion. Gravitational interactions within the nebula form dense regions as mass begins to accumulate, eventually leading to the birth of a protostar and a protoplanetary disk. Within the protoplanetary disk, planets form through gravitational interaction. The location of the planet plays an important role in how massive it becomes, how big it becomes, and what kind of atmosphere it will have. The Snow Line An important feature of the solar system is the snow line, which is also called the frost line. This is the distance from the Sun within the solar system in which the radiation is not intense enough to prevent water ice from forming out of water vapor. The water vapor in the region outside of the snow line can form ice or frost and attach to a dust grain as shown in Figure 1.

Figure 1: A) Inside the snow line, water can only exist as vapor. The water vapor would be pushed out into space and protoplanets could only form with dust grains. B) Outside the snow line, frost and ice can accumulate on a dust grain, giving planets that form in this region a greater overall mass and a smaller average density. 1 Inside the snow line, water vapor will eventually be pushed out into the outer reaches of the solar system through radiation pressure (which we’ll discuss in the next section), leaving only heavier elements in the inner part of the solar system to form protoplanets. Outside the snow line, there is more mass to form protoplanets because the water vapor condenses to form ice on the dust grains. This results in planets with more mass and a larger volume. This also has an eect on the average density of the planets. Water ice is less dense than silicate rock (the “dust grains”), the net eect is that protoplanets that form outside the snow line have a lower overall density. The density of an object can be found using the following equation

1) What is the mass of Object A? (Hint: mass = · Volume)

2) What is the mass of Object B?

3) Calculate the average density of Object C (Hint: there is 1 m3 of each type of substance in this object.) 4) Is the average density of the Object C greater than or less than the average density of the Object A?

Now let’s look at how this relates to the planets. Figure 2 shows a chart of the estimated temperatures and distances from the center of the early solar nebula for the planets. Planets inside the snow line formed into rocky planets. Planets outside the snow line formed into large gas planets.

Figure 2: Estimated temperatures and distances from the center of the early solar nebula for the planets. With more mass to form planets, the Jovian planets (gas giants) quickly grew in mass. Additionally, this means that they had high escape velocities and were able to hold onto lighter elements such as hydrogen and helium, which makes up nearly the entire composition of these planets. 5) A planet called Rython has a mass of 345 1021 kg and a volume of 1.63 1011 km3. What is the average density of Rython? 6) A planet called Dalbak has a mass of 1.4 1027 kg and a volume of 1.43 1015 km3. What is the average density of Dalbak?

Mercury, Venus, Earth, and Mars all have similar densities as Rython, while Saturn, Neptune, Uranus, and Jupiter all have similar densities as Dalbak. 7) Looking at Figure 2, what generalization can be made as to the average density of a planet inside the snow line vs. a planet outside the snow line? 8) Assume there were equal parts rock and water in the early solar system. Explain how the outer planets can have so much bigger while having lower densities. (See Figure 1 and your results from 1-4 to draw a conclusion). Radiation Pressure Earlier in the course we learned that a photon has an energy associated with its wavelength. When a photon encounters an object, it can impart some of this energy onto the object, changing its momentum. An analogy would be how a billiard ball can impart its momentum onto another billiard ball, although the actual interaction between light and matter is much more complex. Radiation pressure is what holds up the Sun from collapsing on itself, causes space craft to drift, and causes lighter elements to be pushed out into the outer reaches of the solar system. Modeling the actual interaction between photons and matter is too di"cult for our purposes, so we will model molecules as tiny solar sails. Solar sails are a type of propulsion system in which a spacecraft uses a giant sail allowing the millions of photons to push the craft away from the Sun. The ship will sail when the force of radiation pressure > force of gravity because the forces are in opposite directions. Deriving this is beyond the scope of this course, but we find a condition that relates the cross-sectional area A of the object to the mass of the object, m: A m > 628 m2 /kg (2) If this condition is met, the object will be pushed away from the Sun. If the condition is not met, the object will be bound to the Sun gravitationally.

9) Calculate the ratio A/m for each of the objects listed in Table 1 and fill in the third column.

10) Examining Eq.(2) and comparing to your results, which object(s) is/are certainly going to be blown into the outer solar system?

11) Examining Eq.(2) and comparing to your results, which object(s) is/are certainly not going to be blown into the outer solar system?

ohei/Downloads/Lab7-Spring 2017.pdf intense enough to prevent water ice from forming out of water vapor. The water vapor in the region outside of the snow line can form ice or frost and attach to a dust grain as shown in Figure 1. snow line Figure 1: A) Inside the snow line, water can only exist as vapor. The water vapor would be pushed out into space and protoplanets could only form with dust grains. B) outside the snow frost and ice can accumulate on a dust grain, giving planets that form in this region a greater overall mass and a smaller average density, MacBook Pro

Explanation / Answer

Answer- we know that density = mass/ volume

Mass of object A = density* volume

given - object A is completely made up of silcates mineral

density of silicate = 3000 kg/m3

volume of object A = 1 m3

so the mass of object A will be = density* volume = 3000* 1 = 3000kg

object B is completely made up of ice crystal

volume of object B = 1m3

density of object B (ice) = 1000 kg/m3

so the mass of object B will be = density* volume = 1000* 1 = 1000kg

average density = total mass/ total volume

object c is 50% composed of silicated mineral and 50% ice crystal

total mass = ice+crystal =3000+1000 = 4000kg

total volume = 2 m3

total density= total mass/ total volume = 4000/2 = 2000 kg/m3

answer- mass of Rython = 3.45*1021 kg

volume of Rython = 1.63*1011 kg3

density of rython will be = mass/ volume =  3.45*1021 / 1.63*1011 = 2.11*1010 kg/km3 = 2.11*1013 kg/m3

mass of dalbak = 1.4*1027 kg

volume of dalbak = 1.43*1015 km3

density of dalbak = mass/ volume = 1.4*1027 / 1.43*1015 =0.97*1012 = 9.7*1011kg/km3 = 9.7*1014 kg/m3

the general realisation that is made on the basis of average density of the planet is that the planet having low density lies out side the snow line and composed of gases common hydrogen and helium and other lighter material have low surface temperature like other jovian planet and the planet having high density lies in the inner side of snow line they have high surface temperature commonly composed of silicates mineral etc

answer= triton have no atmosphere because surface temperature is low and also have low escape velocity it will fall below snow line

Earth moon have richest atmosphere

and among callisto and triton callisto have richest atmosphere because of high surface temperature and escape velocity. etc

object mass area a/m ratio water molecule 3.00*10-36 6.16*10-30 2.05*106 iron atom 9.27*10-36 1.02*10-29 1.10*106 pebble 0.327 0.003 9.1*10-3

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