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Experiment 9 – Conservation of Linear Momnetum
[Document subtitle]
March 29, 2016
Engineering Physics 150

March 29, 2016
Engineering Physics 150

Objectives:
The objectives of this laboratory experiment is to investigate the velocities and momentm of two carts before and after various types of collisions.
Theory:
* When objects collide and assuming there are no external forces are acting on the colliding objects, the principle of the conservation of momentum always holds. * For a two-object collision, momentum conservation is stated mathematically by the equation: * PTotali =PTotalf * m1v1i+m2v2i=m1v1f+m2v2f * When working with a complete inelastic collision, the two objects stick together after the collision, and the momentum conservation equation becomes: * PTotali =PTotalf * m1v1i+m2v2i=(m1+m2)vf * During this experiment, photogates will measure the motion of two carts before and after elastic collision. The cart masses can be measured by using a simple mass scale. * Then, total momentum of the two carts before collision will be compared to the total momentum of the two carts after collision.

Equipment: 850 Universal | Dynamic Track | Two dynamic carts | Two picket fences | Mounting brackets | Mass Balance | Mass Bar | Two Photogates |

Data:
Part A – Elastic Collision with approx. equal masses: Trial | V1 i (m/s) | V2 i (m/s) | V1 f (m/s) | V2 f (m/s) | 1 | .310 | 0 | 0 | .287 | 2 | .468 | 0 | 0 | .439 | 3 | .486 | 0 | 0 | .435 | 4 | .274 | 0 | 0 | .254 | 5 | .468 | 0 | 0 | .441 | * m1 = mass of cart 1 = .510 kg * m2 = mass of cart 2 = .529 kg |

Part B – Elastic Collision with Unequal Masses: Trial | V1 i (m/s) | V2 i (m/s) | V1 f (m/s) | V2 f (m/s) | 1 | .404 | 0 | -.113 | .245 | 2 | .417 | 0 | -.117 | .253 | 3 | .387 | 0 | -.110 | .235 | 4 | .417 | 0 | -.109 | .254 | 5 | .410 | 0 | -1.04 | .247 | * m1 = mass of cart 1 = .510 kg * mass of cart 2 = .529 kg * mass of bar = .497 kg * m2 = mass of cart 2 + mass of bar = 1.026 kg |

Part C – Completeley Inelastic Collision with Approximately Equal Masses: Trial | V1 i (m/s) | V2 i (m/s) | Vf (m/s) | 1 | .495 | 0 | .230 | 2 | .484 | 0 | .224 | 3 | .535 | 0 | .250 | 4 | .593 | 0 | .278 | 5 | .369 | 0 | .194 | * m1 = mass of cart 1 = .510 kg * m2 = mass of cart 2 = .529 kg |
Part D – Completely Inelastic Collision with Unequal Masses: Trial | V1 i (m/s) | V2 i (m/s) | Vf (m/s) | 1 | .542 | 0 | .164 | 2 | .627 | 0 | .193 | 3 | .582 | 0 | .197 | 4 | .486 | 0 | .155 | 5 | .611 | 0 | .192 | * m1 = mass of cart 1 = .510 kg * mass of cart 2 = .529 kg * mass of bar = .497 kg * m2 = mass of cart 2 + mass of bar = 1.026 kg |

Calculations:
Part A – Elastic Collision with equal masses Trial | Calculations: m1v1 i + m2v2 i | Ptotal i (kg.m/s) | 1 | (.510)(.310)+(.529)(0) | .158 | 2 | (.510)(.468)+(.529)(0) | .239 | 3 | (.510)(.486)+(.529)(0) | .248 | 4 | (.510)(.274)+(.529)(0) | .140 | 5 | (.510)(.468)+(.529)(0) | .239 |

Trial | Calculations: m1v1 f + m2v2 f | Ptotal f (kg.m/s) | 1 | (.510)(0)+(.529)(.287) | .151 | 2 | (.510)(0)+(.529)(.439) | .232 | 3 | (.510)(0)+(.529)(.435) | .230 | 4 | (.510)(0)+(.529)(.254) | .134 | 5 | (.510)(0)+(.529)(.441) | .233 |

Trial | Calculations: ([ Ptotal i – Ptotal f ] / Average) × 100% | % Difference | 1 | |.158-.151|/.112= .0714 × 100% | 4.52 | 2 | |.239-.232|/.1455= .0344 × 100% | 2.84 | 3 | |.248-.230|/.139= .0339 × 100% | 2.87 | 4 | |.140-.134|/.137= .0243 × 100% | 4.38 | 5 | |.239-.233|/.1185= .0253 × 100% | 2.54 |

Part B – Elastic Collision w/ unequal masses: Trial | Calculations: m1v1 i + m2v2 i | Ptotal i (kg.m/s) | 1 | (.510)(.272)+(1.026)(0) | .145 | 2 | (.510)(.221) (1.026)(0) | .118 | 3 | (.510)(.261)+(1.026)(0) | .139 | 4 | (.510)(.287)+(1.026)(0) | .153 | 5 | (.510)(.338)+(1.026)(0) | .180 |

Trial | Calculations: m1v1 f + m2v2 f | Ptotal f (kg.m/s) | 1 | (.532)(-.0704)+(1.029)(.181) | .149 | 2 | (.532)(-.0511)+(1.029)(.147) | .124 | 3 | (.532)(-.0637)+(1.029)(.172) | .143 | 4 | (.532)(-.0826)+(1.029)(.204) | .166 | 5 | (.532)(-.0900)+(1.029)(.227) | .186 |

Trial | Calculations: ([ Ptotal i – Ptotal f ] / Average) × 100% | % Difference | 1 | [.145-.149]/ .147 = .0272 × 100% | 2.7 | 2 | [.118-.124]/.121= .0496 × 100% | 5.0 | 3 | [.139-.143]/.141= .0284 × 100% | 2.8 | 4 | [.153-.166]/.1595= .0815 × 100% | 8.2 | 5 | [.180-.186]/.183= .0328 × 100% | 3.3 |

Part C – Completely Inelastic with unequal masses Trial | Calculations: m1v1 i + m2v2 i | Ptotal i (kg.m/s) | 1 | (.532)(.350)+(.509)(0) | .186 | 2 | (.532)(.395)+(.509)(0) | .210 | 3 | (.532)(.450)+ (.509)(0) | .234 | 4 | (.532)(.464)+ (.509)(0) | .247 | 5 | (.532)(.548)+ (.509)(0) | .292 |

Trial | Calculations: (m1+m2)vf | Ptotal f (kg.m/s) | 1 | (.532+.509)(.164) | .171 | 2 | (.532+.509)(.178) | .185 | 3 | (.532+.509)(.224) | .233 | 4 | (.532+.509)(.229) | .234 | 5 | (.532+.509)(.273) | .284 |

Trial | Calculations: ([ Ptotal i – Ptotal f ] / Average) × 100% | % Difference | 1 | [.186-.171]/ .1785= .0840 × 100% | 8.4 | 2 | [.210-.185]/ .1975= .1266 × 100% | 12.7 | 3 | [.234-.233]/ .2335= .0400 × 100% | .04 | 4 | [.247-.234]/ .2405= .0541 × 100% | 5.4 | 5 | [.292-.284]/ .288= .0278 × 100% | 2.8 |

Part D- Completely Inelastic Collision with Unequal Masses: Trial | Calculations: m1v1 i + m2v2 i | PTotal i (kg.m/s) | 1 | (.532)(.660)+(1.029)(0) | .351 | 2 | (.532)(.634)+ (1.029)(0) | .377 | 3 | (.532)(.607)+ (1.029)(0) | .323 | 4 | (.532)(.545)+ (1.029)(0) | .290 | 5 | (.532)(.573)+ (1.029)(0) | .305 |

Trial | Calculations: (m1+m2)(Vf) | Ptotal f (kg.m/s) | 1 | (.532+1.029)(.208) | .320 | 2 | (.532+1.029)(.191) | .294 | 3 | (.532+1.029)(.199) | .306 | 4 | (.532+1.029)(.176) | .270 | 5 | (.532+1.029)(.187) | .288 |

Trial | Calculations: ([ Ptotal i – Ptotal f ] / Average) × 100% | % Difference | 1 | [.351-.320]/.3355= .0924 × 100% | 9.2 | 2 | [.337-.294]/ .3155= .1363 × 100% | 13.6 | 3 | [.323-.306]/ .3145= .0541 × 100% | 5.4 | 4 | [.290-.270]/ .280= .0714 × 100% | 7.1 | 5 | [.305-.288]/ .2965 = .0573 × 100% | 5.7 |

Conclusions:
After completing this experiment I have been able to use my data and theories to help create a variety of conclusions along with thoughts and personal opinions on this experiment. It can be noticed that the main focus of this experiment is the conservation of linear momentum and being able to calculate the momentum with multiple equations. These equations can be found in the theory section of the experiment which is extremely useful for this experiment. As the section includes a large amount of important information such as the explanation of how it is critical to compare the total momentum of the two carts before and after the collision. The equations for solving for this are provided in the theory section for both elastic and inelastic collisions which is very important for calculating our results. Reason for this is because an inelastic equation does not have a V1 f and V2 f, but instead just a Vf. With such an accurate and valuable theory section it was easy to conduct this experiment and receive excellent results, with my percent differences providing proof. My % differences were reasonably low in this experiment as they were mostly in the range of .04%-13% but provided an average of about 4.4%, which in my opinion is more than accurate. Also we did not go over 10% more than twice and we did not even have to restart trials often, which is a success. When speaking about trends within this experiment it can be noticed that there are quite a few. One of them being that during an inelastic equation (approx. equal masses), the momentum and velocity increase after every trial, such as Ptotal f starting at .171 in Part C, and ends with a value of .284 kg.m/s. This is vice versa for an inelastic collision with unequal masses, velocity and momentum have a negative trend. For some reason I noticed in my results that elastic collisions did not provide too many trends, as the data seemed to bounce all over the place but still resulting in reasonable percent differences. After being able to make conclusions about the trends and results of this experiment, I can also conclude that this experiment was very successful in providing knowledge about conservation of momentum and I would recommend it for future use.
Sources of Error: * Air resistance * Gravity * The excess force pushed on the first cart
References:
* RVCC Physics – Mechanics Lab * Fundamental of Physics, 10th edition, by David Halliday * www.pasco.com * Pasco Capstone Software