Practical Skills II: Analysis

A student investigated standing waves using the apparatus shown.

The signal generator was adjusted until a loud sound was heard at a particular frequency, known as the resonant frequency.

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where k is a constant.

Discuss whether the graph supports this suggestion.

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A radioactive source emits beta radiation and gamma radiation.

The radiation emitted from a radioactive source can be investigated using the apparatus shown. The Geiger-Muller (GM) tube detects beta radiation and gamma radiation.

The ratemeter displays the count rate from all radiation detected by the GM tube.

Explain why the background count rate should be measured.

The corrected count rate C varies over time t according to the relationship

where C₀ is the initial count rate and λ is the decay constant.

Explain how a graph of ln C against t can be used to determine a value for λ.

The source contained two radioactive isotopes, X and Y. The table below shows the corrected count rate as the isotopes decayed.

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Determine a value of λ, in hours⁻¹, for isotope Y.

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λ = .............................. hours⁻¹

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t_1⁄2 = ...............................

A student used the apparatus shown to investigate the time taken for a hollow cylinder to roll down a ramp.

State two precautions she should take to ensure the measurement is as accurate as possible.

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Explain why the uncertainty in Δh is 1 mm.

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Mean value of t = ............................... ± ..........................

Explain how this might improve the measurement of t.

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Compare the accuracy and precision of the data that each student collected.

The relationship between t and the acceleration of free fall g is given by

where s is the distance along the ramp between the start line and the finish line.

The student recorded the following values.

   t = 2.44 s ± 0.04 s
   s = 80.0 cm ± 0.1 cm
   Δh = 43 mm ± 1 mm

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g = ..............................

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Percentage uncertainty = ...........................

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The time period of a rotating wheel can be determined using the apparatus shown.

A magnet is attached to the edge of the wheel. When the magnet passes the coil, a single pulse is displayed on the oscilloscope screen.

The horizontal axis of the oscilloscope screen represents time. The number of milliseconds per division on the horizontal scale can be adjusted.

As the wheel rotates, a series of pulses is displayed as shown.

Describe how a value of the time period should be determined from these pulses.

A student investigated the horizontal oscillations of a trolley between two springs using the apparatus shown.

The student used a stop clock to time the oscillations.

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where k is the spring constant.
Discuss the validity of this prediction.

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k = .......................................................

A student measured some dimensions of a thick, circular lens. The diagram shows approximate values of these dimensions.

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The student had a set of Vernier calipers and a micrometer screw gauge, as shown in the photograph.

State, with a reason, which of these measuring instruments she should use to measure the diameter d of the lens.

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She concluded that because her measurements were precise, they must be accurate.

Explain why this conclusion may not be justified.

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Calculate the mean value of x in mm and its uncertainty.

Mean value of x = ............................... mm ± ..........................mm

The refractive index of the material of the lens can be determined using

where f is the focal length of the lens.

Determine the value of .

= 5.10 cm ± 0.01 cm
= 8.30 mm ± 0.01 mm
 = 9.8 cm ± 0.3 cm

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n = .......................................................

Show that the percentage uncertainty in is approximately 0.5 %.

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Deduce whether this lens could be made from one of these materials.

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