A spherical particle with the density of 1.0g/cm³ is located at the same distance from the Sun as the Jupiter, 7.8x10¹¹m. Assume that the particle absorbs 100 percent of the solar intensity of 52W/m². Find the largest size of a particle when the force exerted by the solar radiation is larger than the gravity exerted on the particle by the Sun. Use the gravitational constant of 6.7x10-¹1Nm²/kg2 and the solar mass of 2.0x103⁰kg.

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A spherical particle with the density of 1.0g/cm³ is located at the same
distance from the Sun as the Jupiter, 7.8x10¹¹m. Assume that the particle
absorbs 100 percent of the solar intensity of 52W/m². Find the largest size
of a particle when the force exerted by the solar radiation is larger than the
gravity exerted on the particle by the Sun. Use the gravitational constant of
6.7x10-¹1Nm²/kg2 and the solar mass of 2.0x10³0kg.
Transcribed Image Text:A spherical particle with the density of 1.0g/cm³ is located at the same distance from the Sun as the Jupiter, 7.8x10¹¹m. Assume that the particle absorbs 100 percent of the solar intensity of 52W/m². Find the largest size of a particle when the force exerted by the solar radiation is larger than the gravity exerted on the particle by the Sun. Use the gravitational constant of 6.7x10-¹1Nm²/kg2 and the solar mass of 2.0x10³0kg.
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