Friday, September 20, 2019
The Conservation Of Momentum Environmental Sciences Essay
The Conservation Of Momentum Environmental Sciences Essay The conservation of momentum was shown in three types of collisions, elastic, inelastic and explosive. By getting mass and velocities for two carts during the collision the change in momentum and kinetic energy was found. In an elastic collision of equal massess ÃâP = Pf-Pi =-8.595 and ÃâKE = KEf-Kei = -4.762. In an inelastic collision of equal massess ÃâP = -12.989 and ÃâKE = -43.14. In an explosive collision of equal massess ÃâP = -448.038 and ÃâKE = -118.211. This shows that conservation of momentum is conserved in elastic and inelastic equations due to their very low change in momentum; however kinetic energy is conserved in the elastic collision but not in the inelastic collision. In an explosive collision momentum is not conserved since the two objects start at rest with no momentum and gain momentum once moving opposite. Introduction Just like Newtons laws, the conservation of momentum is a fundamental principal in physics that is integral in daily life. However unlike Newtons laws, the conservation of momentum does not seem to be entirely intuitive. If a ball is thrown in the air some momentum seems to be loss to the air. This makes proving the conservation of momentum tricky and difficult to do in a real life setting. To measure the conservation of momentum in the lab, two carts will be used along a frictionless track. This allows calculation to be easier since the vectors will be moving along only one axis. This way positive direction can be movement to the right while negative direction can be movement to the left. One cart will have a plunger which is ejected by a spring that will convert its potential energy to kinetic energy of the cart. This will knock the other cart and its momentum will be transferred either partially or entirely. These velocities of the two carts will be measured by a graphing device. This is shown in diagram 1. Diagram 1. Momentum is produced by mass and velocity, in other words: p = mv. It is important to point out that momentum is not conserved on an object by object basis, however it is conserved for the isolated system. This is shown in the equation: Psystem = P1 + P2. Therefore if momentum is conserved then the initial momentum of the entire system should equal the final momentum of the entire system. Thus this can be shown in the equation where: Psystem, initial = Psystem, final M1 X V1i + M2 X V2i = M1 X V1f + M2 X V2f In the lab collisions will be shown to illustrate the conservation of momentum. In elastic collisions energy is always conserved. Unfortunately for this lab kinetic energy can be converted into heat so that energy is lost to viable measurements. If the energy is conserved, the collision is considered to be elastic, but if the energy is not conserved, then the collision is considered inelastic. Kinetic energy is energy associated with motion where an object with mass and moving with a certain velocity the equation is: KE = Ã ½ m |v|2 This allows to find the loss or gain in energy of a system much like for momentum where the change in kinetic energy of a system is determined by the equation: ÃâKESYS = KEsys,final KEsys,intial For the two collisions stated earlier if ÃâKESYS is equal to zero the collision is considered elastic, however if ÃâKESYS does not equal zero then the collision is considered inelastic. There is also another type of collision that will be determined in this lab called an explosive collision. This can be considered the opposite of an inelastic collision since the energy is not conserved because the kinetic energy is transformed for potential energy to kinetic energy. These three types of collisions will be measured in the lab under differing conditions and the change in momentum and kinetic energy of the system will be calculated. Procedure In the lab the momentum and kinetic energy will be calculated by measuring different velocities for the two carts at different masses. Two carts will be set along a frictionless track. As stated earlier this allows for easier calculations since it allows working only in one dimension. One of the carts used has a plunger while the other car is just a regular car. Both carts have different sides which will allow the emulation of the different collision types. For and elastic collision the plunger cart will be placed against the side of the ramp and then set off by a small piece of wood. It will the knock the other cart and emulate a elastic collision because the carts have magnets facing each other that will help conserve energy and momentum by having the opposite sides face each other. Having magnets of opposite charge face each other help keep the collision elastic since major contact between the two carts can convert kinetic energy into heat and will be lost. This will be done in three different ways, first having equal mass carts, second having the plunger cart heavier than the regular cart, and lastly by having the plunger cart lighter than the regular cart. The velocities for these carts will be measured for the different variable for six different trails and averaged. For the inelastic the set up will be identical except to emulate this collision the carts will have Velcro sides that will be facing each other and cause the carts to stick together once they hit each other. This will be done in three different ways similar to the elastic collision, first having equal mass carts, second having the plunger cart heavier than the regular cart, and lastly by having the plunger cart lighter than the regular cart. The velocities for these carts will be measured for the different variable for six different trails and averaged also. For the explosive collision the two carts will be sitting next to each other. The plunger car will have its plunger faced toward the adjacent regular car so when the button is pressed the will move away from each other in opposite directions. This will only be done in two different ways, one way having the carts equal in mass and one ways have one cart heavier than the other cart. The velocities for these carts will be measured for the different variable for six different trails and averaged as well. Results Table 1. Elastic Collision Data Elastic Equal Mass regular car (g) 506.2 plunger car (g) 503.3 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0.5 0 0.483 251.65 244.4946 62.9125 59.04545 0.494 0 0.482 248.6302 243.9884 61.41166 58.8012 0.574 0 0.505 288.8942 255.631 82.91264 64.54683 0.422 0 0.405 212.3926 205.011 44.81484 41.51473 ÃâP = Pf-Pi 0.482 0 0.496 242.5906 251.0752 58.46433 62.26665 -8.595433333 0.516 0 0.498 259.7028 252.0876 67.00332 62.76981 ÃâKE = KEf-KEi average 250.6434 242.048 62.91988 58.15744 -4.762437183 Elastic Heavy Int. regular car (g) 506.2 plunger car (g) 1000.9 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0.412 0 0.501 294.3059 237.5554 84.94838 63.52835 0.502 0 0.59 310.6885 245.6916 126.1154 88.10411 0.321 0 0.466 324.3081 244.3456 51.56687 54.96218 0.462 0 0.544 337.2292 242.4102 106.818 74.9014 ÃâP = Pf-Pi 0.51 0 0.602 354.5463 242.5007 130.167 91.72445 -81.71491849 0.486 0 0.52 324.2156 242.5007 118.2043 68.43824 ÃâKE = KEf-KEi average 324.2156 242.5007 102.97 73.60979 -29.36021623 Elastic Light Int. regular car (g) 1003.8 plunger car (g) 503.3 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0.563 0 0.309 468.8014 310.1742 79.76525 47.92191 0.396 0 0.243 495.1158 243.9234 39.46275 29.63669 0.697 0 0.351 523.2297 352.3338 122.2538 61.83458 0.554 0 0.296 563.0325 297.1248 77.23541 43.97447 ÃâP = Pf-Pi 0.596 0 0.343 610.7959 344.3034 89.39011 59.04803 -227.7090311 0.493 0 0.278 532.195 279.0564 61.16328 38.78884 ÃâKE = KEf-KEi average 532.195 304.486 78.21177 46.86742 -31.34434946 For the elastic collision with equal masses the change in momentum and kinetic energy is every small. Where as in the other two methods the change in momentum is much larger since the masses where different then the change in kinetic energy. Table 2. Inelastic Collision Data Inelastic Equal Mass regular car (g) 506.2 plunger car (g) 503.3 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0.622 0.292 0.297 313.0526 297.305 97.35936 43.78238 0.481 0.242 0.243 242.0873 244.8052 58.222 29.68293 0.619 0.289 0.289 311.5427 291.7455 96.42247 42.15722 0.602 0.276 0.274 302.9866 277.6096 91.19897 38.17143 ÃâP = Pf-Pi 0.51 0.236 0.237 256.683 238.7482 65.45417 28.23227 -12.98885 0.502 0.248 0.249 252.6566 250.8622 63.41681 31.16993 ÃâKE = KEf-KEi average 279.8348 266.846 78.67896 35.5327 -43.14626406 Inelastic Heavy Int. regular car (g) 506.2 plunger car (g) 1000.9 v1 (m/2) v1f (m/s) v2f (m/s) Pi Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 0.495 0.322 0.321 319.6722 484.78 122.6228 77.96833 0.506 0.343 0.342 323.0093 516.4291 128.1332 88.48103 0.497 0.317 0.318 336.2746 478.2569 123.6157 75.8842 0.499 0.312 0.312 352.9982 470.2152 124.6126 73.35357 ÃâP = Pf-Pi 0.323 0.211 0.208 367.6309 316.4795 52.21145 33.23065 115.4745216 0.486 0.31 0.308 339.917 466.1886 118.2043 72.10332 ÃâKE = KEf-KEi average 339.917 455.3916 111.5667 70.17019 -41.39646683 Inelastic Light Int. regular car (g) 1003.8 plunger car (g) 503.3 v1 (m/2) v1f (m/s) v2f (m/s) Pi Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 0.575 0.181 0.181 480.8526 272.7851 83.20178 24.68705 0.589 0.172 0.163 506.4235 250.187 87.30267 20.77979 0.555 0.179 0.183 534.182 273.7861 77.51449 24.87125 0.563 0.186 0.186 573.035 280.3206 79.76525 26.06982 ÃâP = Pf-Pi 0.367 0.115 0.113 619.6586 171.3089 33.89449 9.736832 -289.887818 0.574 0.178 0.179 542.8304 269.2676 82.91264 24.05466 ÃâKE = KEf-KEi average 542.8304 252.9426 74.09855 21.6999 -52.3986526 For the inelastic collision the change in kinetic energy is much larger then it was in elastic collision. This holds true for the other all three methods used. Table 3. Explosive Collision Data Explosive Equal regular car (g) 506.2 plunger car (g) 503.3 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0 0.482 0.503 0 497.2092 0 122.4709 0 0.448 0.471 0 463.8986 0 106.6245 0 0.489 0.512 0 505.2881 0 126.4901 0 0.438 0.469 0 457.8532 0 103.9089 ÃâP = Pf-Pi 0 0.478 0.492 0 489.6278 0 118.7447 488.0378833 0 0.506 0.513 0 514.3504 0 131.0292 ÃâKE = KEf-KEi average 0 488.0379 0 118.2114 118.2113751 Explosive- Unequal regular car (g) 506.2 plunger car (g) 1000.9 v1 (m/2) v1f (m/s) v2f (m/s) Pi = m1vi1+ m2 vi2 Pf = m1vf1 + m2 vf2 Kei = .5m1vi1 + .v5m2vi2 Kef= .5m1vf1 + .v5m2vf2 0 0.297 0.615 0 608.5803 0 139.8729 0 0.34 0.618 0 653.1376 0 154.517 0 0.292 0.619 0 605.6006 0 139.6484 0 0.307 0.633 0 627.7009 0 148.5813 ÃâP = Pf-Pi 0 0.276 0.574 0 566.8072 0 121.5127 599.3574667 0 0.24 0.581 0 534.3182 0 114.2626 ÃâKE = KEf-KEi average 0 599.3575 0 136.3992 136.399151 For the explosive collision the change in momentum is much larger than in the other two collisions. There is no initial momentum for this collision since the two carts started together at rest. Conclusion From momentum and the kinetic energies calculated from the formulas the different trails were averaged to find the initial and final momentum and kinetic energy for each of the eight conditions. They the change in momentum of the system was calculated for the system by subtracting the final momentum minus the initial momentum. This was then done for kinetic energy to find the change in kinetic energy by subtracting final minus initial as well. This produced different values for the different conditions. For the elastic collision the momentum and kinetic energy are supposed to be conserved. As table 1 shows, the momentum and kinetic energy for the equal mass carts is very close to zero, much closer than for the other conditions. For the heavier plunger cart, the initial force had much more inertia and caused the lighter second car to move much further. This is opposite in the other conditions where the plunger cart was much light. It had a harder time moving the second heavier cart. The main difference for the change in momentum and kinetic energy for the two unequal mass cart conditions was due to the fact the final velocity for cart one was never measured properly. It was assumed that the velocity was zero when in fact the plunger cart moved slightly after the collision. The assumption was due to careless human error. For the inelastic collision kinetic energy is not conserved. This is evident very much in the results for the change in kinetic energy. There is a much larger value or this change then in the elastic counterpart since the carts stick together and move as one unit. This close interaction allows for the loss of energy as heat. As for the explosive collision, the change in momentum is by far the largest. Since the system start at rest it is entirely potential energy. When the collision happened the carts move apart and become kinetic energy. Since the final momentum is subtracted by an initial momentum of zero, it is obvious why the change is so large.
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