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INSTANT PDF DOWNLOAD: PHY250L Lab 6 Exam – Work & Conservation of Energy (2026/2027). Includes actual lab-style questions with verified answers covering work-energy theorem, kinetic and potential energy, gravitational potential energy, mechanical energy conservation, power calculations, and experimental data analysis. Designed to strengthen equation application and support success in StraighterLine physics laboratory assessments. PHY250L Lab 6 Exam PDF, PHY250L Work and Energy Lab Answers, StraighterLine PHY250L Lab 6 Test 2026, PHY250L Work Energy Theorem Problems, PHY250L Mechanical Energy Conservation Questions, PHY250L Kinetic Potential Energy Calculations, PHY250L Power Formula Practice Test, StraighterLine Physics Lab Work Exam, PHY250L Lab 6 Verified Answers PDF, PHY250L Gravitational Potential Energy Problems, PHY250L Energy Conservation Lab Test, PHY250L Lab 6 Study Guide 2027, StraighterLine PHY250L Physics Lab Review, PHY250L Work Done by Force Questions,
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Lab Report Format Expectations Utilize college level grammar and formatting when answering text based questions. Report all equations in a proper mathematical format, with the correct signs and symbols. Submissions with incomplete or improperly formatted responses may be rejected.
Given the graph of the force versus displacement graph for a spring in Figure 5, derive an equation for the amount of work done by the spring. Do not simply state a final equation. Show the mathematical steps you will take to derive this equation. You must show all work for credit. The area under the force vs. displacement graph is the work done.For a spring, W=12kx2W = \frac{1}{2} k x^2W=21kx2, where kkk is the spring constant and xxx is the displacement.
Figure 5: Force versus displacement of a spring.
Record your observed forces for each distance the spring was pulled. Then calculate the average force between the measurements. Use this average to find the work it took to pull the spring for each step and record this in the final column.
Table 1. Spring Scale Force Data
Force (N) Distance, x (m) ForceAverage (N) Δ Distance, Δx (m) Work (J) 0 0 0.4N 0.01 0.004J 0.8N 0. 1.25N 0.01 0.0125J 1.7N 0. 2.15N 0.01 0.0215J 2.6N 0. 2.95N 0.01 0.0295J 3.3N 0. 3.75N 0.01 0.0375J 4.2N 0.
b. How much energy was converted into heat after the ball bounced off the ground? (Hint: Thermal Energy (TE) will now need to be included in your conservation of energy equation and you will now need to know the mass of the ball) Initial potential energy (drop height): E₁ = mgh₁ = 0.5 × 9.8 × 3 = 14.7 J Final potential energy (bounce height): E₂ = mgh₂ = 0.5 × 9.8 × 2 = 9.8 J Energy lost to heat (thermal energy, TE): TE = E₁ - E₂ = 14.7 J - 9.8 J = 4.9 J
c. What is the speed of the ball immediately after the ball bounces off the ground? Again use energy conservation for the bounce up: mgh = (1/2)mv² 0.5 × 9.8 × 2 = (1/2) × 0.5 × v² (0.5 cancels out) 9.8 × 2 = v² 19.6 = v² v = √19.6 ≈ 4.43 m/s
Include a photo of the 2 items you used with your handwritten name in the background. Note: One of those items must be a ping pong ball. All five items must be shown, and they must match your entries in Table 5. Submissions without a photo depicting these requirements will be rejected.
Here, we provide the data and observations obtained from the experiment. Conduct the calculations necessary to complete the table. Table 5. Dropped Ball Data