10 (a) The Sun has a mass of 2.0 x 10^30 kg. A white dwarf has a mass of 3.4 x 10^29 kg. Calculate the value of mass of this white dwarf mass of the Sun (b) Figure 18 is a diagram giving some information about main sequence stars. Luminosity is a measure of how bright something is. An increase in luminosity means an increase in brightness. (i) Estimate the temperature of the Sun. (ii) State how the brightness of a main sequence star changes with its temperature. (iii) State how the brightness of a main sequence star changes with its mass. (c) Nuclear fusion provides the energy source for stars including the Sun. Describe what happens during nuclear fusion. (d) A nebula may evolve into a main sequence star, such as the Sun. Explain how a nebula may evolve into a main sequence star.

GCSE Edexcel Physics Changing ideas about universe: 10 (a) The Sun has a mass of 2.0

10 (a) The Sun has a mass of 2.0 x 10^30 kg - Edexcel - GCSE Physics - Question 10 - 2020 - Paper 1

Question 10

10 (a) The Sun has a mass of 2.0 x 10^30 kg. A white dwarf has a mass of 3.4 x 10^29 kg. Calculate the value of mass of this white dwarf mass of the Sun (b) Figur... show full transcript

Worked Solution & Example Answer:10 (a) The Sun has a mass of 2.0 x 10^30 kg - Edexcel - GCSE Physics - Question 10 - 2020 - Paper 1

Step 1

Calculate the value of mass of this white dwarf / mass of the Sun

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Answer

To calculate the ratio of the mass of the white dwarf to the mass of the Sun, we use the formula:

$\text{mass ratio} = \frac{\text{mass of white dwarf}}{\text{mass of Sun}}$

Substituting the given values:

$\text{mass ratio} = \frac{3.4 \times 10^{29} \text{ kg}}{2.0 \times 10^{30} \text{ kg}}$

Evaluating this gives:

$\text{mass ratio} = 0.17$

Step 2

Estimate the temperature of the Sun.

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Answer

From Figure 18, the temperature of the Sun is estimated to be around 5800 K, which is typical for main sequence stars.

Step 3

State how the brightness of a main sequence star changes with its temperature.

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Answer

The higher the brightness, the greater the temperature. This means that main sequence stars with higher temperatures emit more light.

Step 4

State how the brightness of a main sequence star changes with its mass.

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Answer

The greater the mass, the higher the brightness. Heavier stars tend to have greater luminosity.

Step 5

Describe what happens during nuclear fusion.

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Answer

During nuclear fusion, smaller nuclei, such as hydrogen nuclei, come together to form a larger nucleus.

This process requires high temperatures and pressure to overcome the repulsion between the positively charged nuclei.

As the nuclei fuse, a significant amount of energy is released, which powers stars like the Sun.

Step 6

Explain how a nebula may evolve into a main sequence star.

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Answer

A nebula, which is a cloud of gas and dust, contracts under its own gravity.

As gas and dust pull together, gravitational forces increase, raising the temperature within the core of the collapsing material.

Once the temperature is high enough, nuclear fusion can initiate, allowing the nebula to evolve into a main sequence star.

10 (a) The Sun has a mass of 2.0 x 10^30 kg - Edexcel - GCSE Physics - Question 10 - 2020 - Paper 1

Worked Solution & Example Answer:10 (a) The Sun has a mass of 2.0 x 10^30 kg - Edexcel - GCSE Physics - Question 10 - 2020 - Paper 1

Calculate the value of mass of this white dwarf / mass of the Sun

Estimate the temperature of the Sun.

State how the brightness of a main sequence star changes with its temperature.

State how the brightness of a main sequence star changes with its mass.

Describe what happens during nuclear fusion.

Explain how a nebula may evolve into a main sequence star.

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