Exploring Hooke’s Law and the Constant (K): Data Collection and Processing: Data of the Hanging Masses and the Caused Displacement of the Spring Mass Hanging (kg): Displacement of Spring Including Original Length (m): 0.050 0.413 0.100 0.451 0.150 0.458 0.200 0.485 0.250 0.504 0.300 0.522 0.350 0.543 0.400 0.567 0.450 0.587 0.500 0.610 0.550 0.633 0.600 0.655 0.650 0.674 0.700 0.698 Original Length of Spring (m): 0.392 Table 2.1 Constant K: 22.5kg/ms2 *Refer to attached graph and calculations.
Premium Measurement
pushed. To study the behavior of springs in the lab‚ one end is usually attached to a fixed support while the other end is free so that forces can be applied. A force applied to the free end of the spring stretches the spring by an amount‚ ∆x‚ measured from the equilibrium position – the position of the free end when no force is applied. With the force applied to the spring‚ the spring now comes to rest in a new position. If we apply Newton’s Laws to the mass attached to the spring in the figure
Premium Mass Force Elasticity
V. Analysis and Conclusion In this experiment we studied the elastic properties of the spring‚ the Hooke’s Law and the total work done on the spring when it is being stretch. Also‚ this experiment tackles the elasticity and deformation of a material that obeys the Hooke’s Law which states that “Within the elastic limit of a body‚ the deforming force is directly proportional to the elongation of the body.” Our experiment is to determine the force constant of the spring. The calculations used throughout
Premium Elasticity Potential energy Robert Hooke
Introduction Hooke’s law states that force is directly proportional to the displacement of the spring that has been stretched or compressed from the equilibrium position. The force that takes place is referred to as a restoring force because it acts on an object to return it to a state of equilibrium. This is Hooke’s Law. It can be shown as: F = -kx In the first formula ---> F is the force of weight k is the spring constant x is the displacement In this lab‚ we would have to know
Premium Hertz Mass Force
PHY 114 Faraday’s Law of Induction Stephanie Scott Section: 10849 Group #3 Bochao Li 3/31/15 Abstract: The objective of the Faraday’s Law of Induction lab was to verify Faraday’s law of induction by measuring the emf generated in a small coil and comparing it with the calculated value. Secondly the goal was to investigate the relationship between the emf and the frequency of the driving signal. The magnetic field was found to be uniform throughout. For the frequency of 40 Hz‚ the average
Premium Magnetic field Maxwell's equations
Physics 1405 Name(s)_____________________ HOOKE’S LAW and SIMPLE HARMONIC MOTION INTRODUCTION Any motion that repeats itself in equal intervals of time is called periodic motion. A special form of periodic motion is called Simple Harmonic Motion (SHM). Simple Harmonic Motion is defined as oscillatory motion in which the resultant force on the oscillating body at any instant is directly proportional to its displacement from the rest position and opposite in direction to its motion
Premium Force Mass
Induction and Faraday’s Thursday‚ October 25‚ 2012 Lab Report 6 Introduction and Faraday’s Law Objective: In this experiment‚ Faraday’s law of induction will be investigated. Theory: Faraday’s law of induction states the induced emf or voltage in a coil is proportional to the rate of change of magnetic flux through a coil‚ this is shown blew: Ƹ= -dɸ/dt Equation 6.1 The flux of the magnetic field is defined and the following: ɸ=BAcosΘ Equation 6.2
Premium Magnetic field Electromagnetism Maxwell's equations
LAB REPORT ON VERIFICATION OF HESS’S LAW Our purpose of doing this lab was to prove the Hess’s law correct. Hess’s law suggests that the enthalpy change of a reaction must be equal to the sum of the enthalpy changes of the related reactions which lead to the original reactions. The following are the reactions at the lab; 1) NaOH ( s) NaOH (aq) 2) NaOH (aq) + HCl (aq) NaCl (aq) + H2O (l) 3) NaOH (s) + HCl (aq) NaCl (aq) + H2O (l) As explained before‚ Hess’s Law states that the enthalpy
Premium Thermodynamics Enthalpy Heat
Joshua McMahon IB Chemistry Matt Chase 3A 11/5/14 Finding the Molar Enthalpy Change of sodium bicarbonate by using Hess Law Research Question By using Hess’ Law‚ can the Molar Enthalpy Change of sodium bicarbonate be calculated? Hypothesis If we are attempting to determine the enthalpy change of the thermal decomposition of Sodium Bicarbonate‚ then Hess’s Law will be will be the most effective. Introduction Sodium bicarbonate‚ more commonly known as baking soda‚ has many uses in todays
Free Thermodynamics Temperature Enthalpy
Robert Hooke Georgia Priest 23 September 2011 1st period Biology Honors On July 18‚ 1635‚ Robert Hooke was born in the small community of Freshwater on the Isle of Wright. His father John Hooke was a clergyman‚ as a child Hooke had ingenuity for mechanics. When Hooke was thirteen his father committed suicide by hanging himself. Hooke was left one hundred pounds in inheritance from his father. Robert went to London after the death of his father as an apprentice to the painter Sir Peter
Premium Robert Hooke