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| Atlas V Rocket |
However, this is (clearly) not the most efficient way to launch a craft to Mars using conventional methods, seeing that it would take the craft more than three years to reach Mars. If the craft is launched at a higher velocity, the curved orbit from Earth to Mars will have flattened out. The only down side to launching spacecraft at these trajectories is that once at the red planet, the vessel will have to begin to slow down to enter her orbital velocity.
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In this image, the distance traveled between Earth and Mars is closer to 300 million kilometers, slicing the trip time down to only about 18 months. The truth is, there's no limit to how fast you can fly a ship from Earth to Mars (except the speed of light), thus the path between Earth and Mars will grow continually shorter with velocity. If you could accelerate a craft to the near the speed of light, the shortest possible distance would only be about 55 million kilometers. Take that divided by the speed of light and you get a trip time of about 3 minutes. So, if there is no limit, the only question is how fast can we go?
There has been a lot of talk in recent years about the possibility of using nuclear fusion power to propel a rocket to Mars. The theory behind nuclear fusion is actually quite simple. Take, for example, the fusion of deuterium, an isotopes of hydrogen. Deuterium is simply a hydrogen atom with two neutrons. In the image below, blue spheres represent neutrons while red spheres represent protons. When heated to extreme temperatures, these hydrogen atoms will begin to gain velocity. Once a certain velocity is achieved, these atoms will slam into each other with enough force to combine into a single helium atom and release a tremendous amount of energy.
Let's compare this to the energy released by liquid hydrogen, currently the most efficient and powerful rocket fuel in use today. The specific energy of a substance tells us exactly how many megajoules of energy are released per kilogram of whatever it is you are using as fuel. The specific energy of liquid hydrogen is about 141.86 megajoules per kilogram. That is a lot of energy. And that is in just 1 kilogram of liquid hydrogen. putting that into perspective, 1 kilogram of liquid hydrogen could power an average American household for 31 hours.
So how about nuclear fusion? The net reaction of one deuterium-tritium fusion (tritium being another isotope of hydrogen, actually more efficient than a deuterium-deuterium reaction) creates about 12.5 megaelectron volts, or about 2*10^-12 joules. This may seem like a tiny amount of energy, but this is only in one reaction of just one deuterium and one tritium atom! Since one mole of hydrogen is equal to one gram, we just multiply that by Avagadro's number (the number of atoms in one mole of hydrogen) to obtain how much energy is released in one gram. This turns out to be 1.2*10^12 joules in one gram, or in a kilogram, 1.2*10^15 joules. Using nuclear chemistry, we find that one gram of reacted dueterium-tritium fuel generates 1.2 billion megajoules of raw energy! Modern experiments show that at best, a fusion engine could only utilize about 30% of the total energy created. This means that the energy density of the nuclear fusion of deuterium and tritium fuel at 30% efficiency is 361 million megajoules per kilogram. This is 2.5 million times more efficient than liquid hydrogen fuel. Recall from before that the Atlas V takes 284,000 kg of traditional fuel to launch off, leave Earth's orbit, slow to Mars's orbit, and land on the surface of the planet. Using a vessel of the same mass and a fusion powered rocket, we find that a voyage to Mars would only require about 113.6 grams of fuel! If it were a manned mission, we must assume that it would be nice for the crew of the craft to return home, bringing the grand total to about 227.2 grams of both deuterium and tritium fuel, or 454.4 grams of total fuel (about 1 pound for all you Imperial system goers).
So how about nuclear fusion? The net reaction of one deuterium-tritium fusion (tritium being another isotope of hydrogen, actually more efficient than a deuterium-deuterium reaction) creates about 12.5 megaelectron volts, or about 2*10^-12 joules. This may seem like a tiny amount of energy, but this is only in one reaction of just one deuterium and one tritium atom! Since one mole of hydrogen is equal to one gram, we just multiply that by Avagadro's number (the number of atoms in one mole of hydrogen) to obtain how much energy is released in one gram. This turns out to be 1.2*10^12 joules in one gram, or in a kilogram, 1.2*10^15 joules. Using nuclear chemistry, we find that one gram of reacted dueterium-tritium fuel generates 1.2 billion megajoules of raw energy! Modern experiments show that at best, a fusion engine could only utilize about 30% of the total energy created. This means that the energy density of the nuclear fusion of deuterium and tritium fuel at 30% efficiency is 361 million megajoules per kilogram. This is 2.5 million times more efficient than liquid hydrogen fuel. Recall from before that the Atlas V takes 284,000 kg of traditional fuel to launch off, leave Earth's orbit, slow to Mars's orbit, and land on the surface of the planet. Using a vessel of the same mass and a fusion powered rocket, we find that a voyage to Mars would only require about 113.6 grams of fuel! If it were a manned mission, we must assume that it would be nice for the crew of the craft to return home, bringing the grand total to about 227.2 grams of both deuterium and tritium fuel, or 454.4 grams of total fuel (about 1 pound for all you Imperial system goers).
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| Proposed NASA Nuclear Fusion Rocket |
Using the ideal gas law, we can determine the volume of two spherical fuel tanks to hold the deuterium and tritium as well. For a system at reasonable temperatures and pressures, PV = nRT, where:
P = Pressure
V = Volume
n = moles
R = .08206 (constant)
T = Temperature
We want a pressure of 1 earth atmosphere, and since one gram equals one mole for hydrogen, n will equal 227.2. Room temperature in Kelvins is 294. Thus:
(1)*V = (227.2)*(.08206)*(294)
V = 5481.3 liters, or 5.48 cubic meters
For a sphere:
V = (4/3)*pi*r^3
Thus:
r = 1.09 meters
So we would need two spherical fuel tanks just over 1 meter in radius to bring a manned crew to Mars and back in a vessel about the mass of the Atlas V. This is an incredibly small amount of fuel compared to the thousands of kilograms needed to launch the Atlas V towards Mars. Nuclear fusion is definitely a cheaper source of spaceflight, but what about faster? According to NASA, the exhaust velocity of a nuclear fusion powered rocket is likely to be upwards of 30 kilometers per second. Compared to that of the Atlas V rocket, whose exhaust velocity is approximately 4 kilometers per second, this would cut the trip time from here to Mars by more than 7 times, leaving the ETA at about 36 days. Not to mention that the only byproduct of nuclear fusion is helium and neutrons. So there you have it; cleaner, faster, and cheaper. So, why are we not using it?
The sad fact of the matter is that fusion isn't easily achieved. For deuterium and tritium atoms to smash together with enough force to fuse and release energy, we must first heat them to 700 million degrees Kelvin, a temperature hotter than the core of the sun. Not only do we not have the means with current technology to heat anything to such a temperature, but no known material could contain such heat without deformation. Furthermore, though hydrogen is very abundant, deuterium and tritium only compose a fraction of a percent of the total amount of hydrogen in the universe.
So fusion may not be practical as a source of rocket propulsion today. It is only a matter of time, however, until we are able to find a way to heat hydrogen to such temperatures, possibly by way of microwaves, and keep it contained maybe in an extremely rigid futuristic material or with a powerful electromagnetic field. In the near future, we may even be able to synthesize deuterium and tritium fuel by somehow combining excess neutrons with hydrogen atoms, using the strong nuclear force as a glue for the new isotopes. Though fusion may seem difficult today, we will, as a human race, find way to overcome these setbacks in order to further mankind. Mars is our nearest celestial neighbor besides our own moon, and we know so little about it under its mysterious, dusty red crust. With the nuclear fusion rocket, a trip to the red planet may be only a few pounds of fuel and 36 days away. So what are we waiting for?
P = Pressure
V = Volume
n = moles
R = .08206 (constant)
T = Temperature
We want a pressure of 1 earth atmosphere, and since one gram equals one mole for hydrogen, n will equal 227.2. Room temperature in Kelvins is 294. Thus:
(1)*V = (227.2)*(.08206)*(294)
V = 5481.3 liters, or 5.48 cubic meters
For a sphere:
V = (4/3)*pi*r^3
Thus:
r = 1.09 meters
So we would need two spherical fuel tanks just over 1 meter in radius to bring a manned crew to Mars and back in a vessel about the mass of the Atlas V. This is an incredibly small amount of fuel compared to the thousands of kilograms needed to launch the Atlas V towards Mars. Nuclear fusion is definitely a cheaper source of spaceflight, but what about faster? According to NASA, the exhaust velocity of a nuclear fusion powered rocket is likely to be upwards of 30 kilometers per second. Compared to that of the Atlas V rocket, whose exhaust velocity is approximately 4 kilometers per second, this would cut the trip time from here to Mars by more than 7 times, leaving the ETA at about 36 days. Not to mention that the only byproduct of nuclear fusion is helium and neutrons. So there you have it; cleaner, faster, and cheaper. So, why are we not using it?
The sad fact of the matter is that fusion isn't easily achieved. For deuterium and tritium atoms to smash together with enough force to fuse and release energy, we must first heat them to 700 million degrees Kelvin, a temperature hotter than the core of the sun. Not only do we not have the means with current technology to heat anything to such a temperature, but no known material could contain such heat without deformation. Furthermore, though hydrogen is very abundant, deuterium and tritium only compose a fraction of a percent of the total amount of hydrogen in the universe.
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| Temperatures for Achieving Fusion (Blue line is Deuterium-Tritium) |
So fusion may not be practical as a source of rocket propulsion today. It is only a matter of time, however, until we are able to find a way to heat hydrogen to such temperatures, possibly by way of microwaves, and keep it contained maybe in an extremely rigid futuristic material or with a powerful electromagnetic field. In the near future, we may even be able to synthesize deuterium and tritium fuel by somehow combining excess neutrons with hydrogen atoms, using the strong nuclear force as a glue for the new isotopes. Though fusion may seem difficult today, we will, as a human race, find way to overcome these setbacks in order to further mankind. Mars is our nearest celestial neighbor besides our own moon, and we know so little about it under its mysterious, dusty red crust. With the nuclear fusion rocket, a trip to the red planet may be only a few pounds of fuel and 36 days away. So what are we waiting for?
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