CALC Neutron Stars and Supernova Remnants. The Crab Nebula is a cloud of glowing gas about 10 light-years across, located about 6500 light-years from the earth ( Fig. P9.86 ). It is the remnant of a star that underwent a supernova explosion , seen on earth in 1054 A.D. Energy is released by the Crab Nebula at a rate of about 5 × 10 31 W. about 10 5 times the rate at which the sun radiates energy. The Crab Nebula obtains its energy from the rotational kinetic energy of a rapidly spinning neutron star at its center. This object rotates once every 0.0331 s. and this period is increasing by 4.22 × 10 −13 s for each second of time that elapses, (a) If the rate at which energy is lost by the neutron star is equal to the rate at which energy is released by the nebula, find the moment of inertia of the neutron star . (b) Theories of supernovae predict that the neutron star in the Crab Nebula has a mass about 1.4 times that of the sun. Modeling the neutron star as a solid uniform sphere, calculate its radius in kilometers, (c) What is the linear speed of a point on the equator of the neutron star? Compare to the speed of light, (d) Assume that the neutron star is uniform and calculate its density. Compare to the density of ordinary rock (3000 kg/m 3 ) and to the density of an atomic nucleus (about 10 17 kg/m 3 ). Justify the statement that a neutron star is essentially a large atomic nucleus. Figure P9.86
CALC Neutron Stars and Supernova Remnants. The Crab Nebula is a cloud of glowing gas about 10 light-years across, located about 6500 light-years from the earth ( Fig. P9.86 ). It is the remnant of a star that underwent a supernova explosion , seen on earth in 1054 A.D. Energy is released by the Crab Nebula at a rate of about 5 × 10 31 W. about 10 5 times the rate at which the sun radiates energy. The Crab Nebula obtains its energy from the rotational kinetic energy of a rapidly spinning neutron star at its center. This object rotates once every 0.0331 s. and this period is increasing by 4.22 × 10 −13 s for each second of time that elapses, (a) If the rate at which energy is lost by the neutron star is equal to the rate at which energy is released by the nebula, find the moment of inertia of the neutron star . (b) Theories of supernovae predict that the neutron star in the Crab Nebula has a mass about 1.4 times that of the sun. Modeling the neutron star as a solid uniform sphere, calculate its radius in kilometers, (c) What is the linear speed of a point on the equator of the neutron star? Compare to the speed of light, (d) Assume that the neutron star is uniform and calculate its density. Compare to the density of ordinary rock (3000 kg/m 3 ) and to the density of an atomic nucleus (about 10 17 kg/m 3 ). Justify the statement that a neutron star is essentially a large atomic nucleus. Figure P9.86
The Crab Nebula is a cloud of glowing gas about 10 light-years across, located about 6500 light-years from the earth (Fig. P9.86). It is the remnant of a star that underwent a supernova explosion, seen on earth in 1054 A.D. Energy is released by the Crab Nebula at a rate of about 5 × 1031 W. about 105 times the rate at which the sun radiates energy. The Crab Nebula obtains its energy from the rotational kinetic energy of a rapidly spinning neutron star at its center. This object rotates once every 0.0331 s. and this period is increasing by 4.22 × 10−13 s for each second of time that elapses, (a) If the rate at which energy is lost by the neutron star is equal to the rate at which energy is released by the nebula, find the moment of inertia of the neutron star. (b) Theories of supernovae predict that the neutron star in the Crab Nebula has a mass about 1.4 times that of the sun. Modeling the neutron star as a solid uniform sphere, calculate its radius in kilometers, (c) What is the linear speed of a point on the equator of the neutron star? Compare to the speed of light, (d) Assume that the neutron star is uniform and calculate its density. Compare to the density of ordinary rock (3000 kg/m3) and to the density of an atomic nucleus (about 1017 kg/m3). Justify the statement that a neutron star is essentially a large atomic nucleus.
suggest a reason ultrasound cleaning is better than cleaning by hand?
Checkpoint 4
The figure shows four orientations of an electric di-
pole in an external electric field. Rank the orienta-
tions according to (a) the magnitude of the torque
on the dipole and (b) the potential energy of the di-
pole, greatest first.
(1)
(2)
E
(4)
What is integrated science.
What is fractional distillation
What is simple distillation
Chapter 9 Solutions
University Physics with Modern Physics (14th Edition)
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