Physics Archimedes Principle Lab Report

Mea acceptedment of wad, mountain, and slow-wittedness through Archimedes formula Overview The purpose of this experiment was to measure the density of a significant and a runny using Archimedes principle. Archimedes is one of the greatest inventors and mathematicians of all time. The principle we utilise in this experiment was discovered when Archimedes stepped into a full bath tub. victimisation Archimedes principle, we were adapted to narrow the density of a hold celestial pole, water supply, and an unfathomable liquid state.Physical selective information Name MW (g/mol) ? (g/cm3) bp (? C) mp (? C) water 18. 01 g/mol 1 g/cm3 100 ? C 0 ? C run low 207. 2 g/mol 11. 34 g/cm3 1749? C 327. 5? C Equations rebound ConstantF=-kxThe equation was used to address the give continuous of work i. Density? = concourse massThis equation was used to calculate the density of an disapprove. Buoyant ForceB=? mg=? f VobjgThis equation was used to calculate the buoyant blackmai l of an object. Experimental functionProcedureA * Setup exchangeable to the spring unceasing laboratory * Use the analogous or a similar spring from the spring constant lab * Find the spring constant of the smallest spring used from prior lab if not already openB * Use the same metal perch from the misunderstanding of Propagation experiment and attach it to the bottom of the spring * Fully semiaquatic the metal rod in a beaker of water * Record the interlingual rendition of the submerged object * Repeat several times making sure the object is fully submerged and steadyC * Dry the object and then reiterate recess B with an uncharted liquid Observations * Used spring i.We worked with a different group so we used their spring with their known spring constant. * Used an iron rod, which is what the group we worked with used before. * Starting loudness reduced after the first trial * extirpation in the unvalued liquid was very similar to that of water Data/Results A sk ip over constant k=0. 023 N/m This was received from the group we worked with. B &C parachute constant (spring i) 0. 023N/cm Object Mass (g) Hanging (cm) Dis rolement in H2O (cm) Displacement in unappreciated (cm) Spring Spring 11. cm 0 0 Spring + 5g 5 15. 8 15. 5 16 Spring + 10g 10 17. 5 17. 3 17. 4 Spring +15g 15 19. 7 19. 3 19. 4 Spring +20g 20 21. 7 21. 2 21. 3 Spring +25g 25 24 23. 2 23. 3 Lead cylinder 70. 71 4 38. 9 39 amount 17. 11666667 19. 34285714 19. 48571429 Mass of control in H2O (g) 67. 2977 Volume of Pb (cm3) 3. 422567703 Mass of lead in mystic (g) 66. 1091 Density of unknown (g/cm3) 1. 344283123 Previously obtained multitude lead (cm3) 5. 455 Average density of Unknown (g/cm3) 0. 843428048Calculations ? Mass of Lead Rodma=kx? m=(0. 023Nm)(0. 4)9. 8 m*s-1? m=9. 3810-4 gThe mass of the lead rod was determined by using the spring constant formula. The spring constant of the spring was multiplied by the displacement, and then divided by gravity. Volume of Lea d RodB=? mg=? f VobjgVobj=? m? fVobj=9. 3810-4 g1. 0 g/cm3Vobj=9. 3810-4 gThe the great unwashed of the rod was strand by dividing the mass of the atomic number 30 rob and the density of the fluid (water). Density of UnknownB=? mg=? f Vobjg? f=? mVobj? f=7. 0410-49. 3810-4? f=0. 50gThe density of the unknown liquid was demonstrate by dividing the mass of zinc rob by the volume of the zinc rod. Discussion The impersonal of this experiment was to measure the density of a solid and an unknown liquid by using one of the oldest principles, Archimedes principle. For part A of the experiment, we were able to use the spring constant set from the previous lab, in order to help determine the agitate in mass and volume of an object, and the density of an unknown liquid. The spring constant that was found from the previous lab was 0. 23 N/m. In part B of the experiment, we were able to determine the change in mass of the lead rod from the origin to the water and the volume of the lead rod. After conducting five trials, we were able to acknowledge the change in mass of the lead rod by using the spring constant formula of F=kx. After modifying the formula to solve for mass, we were able to find the change in mass for each trial by multiplying the spring constant and displacement of the lead rod in carriage versus water, then dividing by gravity. The average change in mass was found to be 9. 8X10-4g. Once we had found the mass of the lead rod, we were able to find calculate the volume of the lead rod by modifying the buoyancy force formula to solve for the volume of the object. Find that formula, we divided the mass of the lead rod by the density of water as shown in the send back of literature. The average volume of the lead rod was found to be 3. 422 cm3. In part C of this experiment, we were able to determine the change in mass of the lead rod from air to an unknown liquid and the density of the unknown liquid.We used the same method in part B to calculate th e change in mass of the lead rod. The average change in mass of the lead rod in the unknown liquid was found to be Since the volume of an object does not change when submerged in various liquids, we were able to use the average volume of the lead rod found in part B. then, we were able to find the density of the unknown liquid by dividing the mass of the lead rod by the volume of the lead rod. Average density of the unknown liquid was found to be 1. 44 g/cm3. Since the unknown liquid had an aroma of rubbing alcohol, we hypothesized that the unknown liquid was a mixture of rubbing alcohol and water. Using Archimedes principle, our speculation can be supported since the average density of the unknown liquid was 0. 843 g/mL. An alternative method for this experiment would be to set up the beaker so that the liquid level would be completely leveled, versus when a person lifts the beaker with an unleveled liquid level.A way a person could do this would be to place a book under the bea ker with a leveled liquid level, so that the lead rod is equally and fully submerged in the liquid. Conclusion The objective of this experiment was to determine the mass and volume of an object and the density of an unknown liquid using Archimedes Principle. For part A, we used the spring constant from the previous lab to help determine the mass of the lead rod in part B. The displacement of the lead rod from the air to the water was found in order to help determine the average mass of the lead rod.The average change in mass of the lead rod from air to water was 9. 3810-4g. The average volume of the lead rod was 9. 3810-7cm. In part C an unknown liquid was used. A similar method was used to determine the average change in mass of the lead rod in the unknown liquid, which was found to be 7. 0410-4g. Since the volume of an object does not change in different liquids, the volume of the object found in part B was used in part C to help determine the density of the unknown liquid. The de nsity of the unknown liquid was 0. 75g/mL.