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Isaac Newton [Public domain], via Wikimedia Commons<\/a><\/figcaption><\/figure><\/div>\n\n\n\n
In the 17th century, Newton discovered that gravity is the force that keeps objects in orbit, and published it in Principia Mathematica<\/em>. The implications of this were revolutionary\u2014the same force that keeps things to the ground here on Earth governs celestial bodies! Gravity acts between any<\/em> two bodies with mass; they are attracted towards<\/em> each other. The magnitude of this force is given by:<\/p>\n\n\n \\[ where \\(m_1\\) and \\(m_2\\) are the masses of the two objects, \\(r\\) is the distance between them, and \\(G\\) is the gravitational constant. Newton did not know what the value of \\(G\\) was; it was determined for the first time in the 1790s by Henry Cavendish. The value of \u201cBig G\u201d in SI units is \\(G <\/em>= 6.67 \\times 10^{-11}\\) N \u00b7 m2<\/sup> \u2044 kg2<\/sup>.<\/p>\n\n\n\n When you are near the surface of Earth, the distance from you to the center of Earth is the planet’s radius \\(R_\\oplus = 6.371 \\times 10^6\\ \\textrm{m}\\). The mass of Earth is \\(M_\\oplus = 5.972 \\times 10^24\\ \\textrm{kg}\\). If you have a mass \\(m\\), this means the force of gravity Earth exerts on you is<\/p>\n\n\n \\[ This is how we know the value of \\(g\\), the strength of Earth\u2019s gravitational field. In fact, you can find out the strength of Earth\u2019s gravitational field even if you are not close to the surface: use \\(R_\\oplus + h\\) for any height \\(h\\) above the surface.<\/p>\n\n\n\n Furthermore, you can find the strength of gravity on the surface of any planet (or moon, or asteroid large enough to be spherical, etc.), as long as you know that planet’s mass and radius:<\/p>\n\n\n \\[ Some believe that the positions of the planets on particular days can affect their lives; many people justify this with gravity. The Sun is the most massive object in the solar system. It has a mass of \\(m_\\odot = 1.98 \\times 10^{30}\\ \\textrm{kg}\\) and is a distance \\(r_{S-E} = 1.49 \\times 10^{11}\\ \\textrm{m}\\) away. Jupiter, the most massive planet in the solar system, has a mass \\(m_J = 1.89 \\times 10^{27}\\ \\textrm{kg}\\). It is 588 million kilometers from us \\(\\left(r_{J-E} = 5.88 \\times 10^{11}\\ \\textrm{m}\\right)\\). Let’s say you have a mass \\(m_h = 70\\ \\textrm{kg}\\).<\/p>\n\n\n\n Calculate using Newton’s expression for general gravitation:<\/p>\n\n\n \\[ So, Earth is pulling on us much more strongly than the Sun, and even more strongly than the most massive planet in the solar system. You may verify for yourself that the same holds for any other body in the solar system, such as the other planets or our moon.<\/p>\n\n\n\n
\nF^G = \\frac{Gm_1m_2}{r^2} \\tag{9.8}
\n\\]<\/p>\n\n\n\n
\n\\begin{align*}
\n F^G &= \\frac{GmM_\\oplus}{R_\\oplus^2} \\\\
\n &= m\\left(9.81\\ \\textrm{m\/s}^2\\right) \\\\
\n &= mg
\n\\end{align*}
\n\\]<\/p>\n\n\n\n
\n g_\\textit{planet} = \\frac{G M_\\textit{planet}}{R_\\textit{planet}^2}
\n\\]<\/p>\n\n\n\nExample 9.12<\/h4>\n\n\n\n
\n \\begin{align*}
\n F_{S-h} &= G\\frac{m_Sm_h}{r_{S-E}^2} & F_{E-h} &= m_hg \\\\
\n &= 0.417\\ \\textrm{N} & &= 686\\ \\textrm{N} \\\\
\n F_{J-h} &= G\\frac{m_Jm_h}{r_{J-E}^2} & \\hookrightarrow F_{S-h} &= (1.63 \\times 10^4)F_{J-h} \\\\
\n &= 2.55 \\times 10^{-5}\\ \\textrm{N} & \\hookrightarrow F_{E-h} &= (1.65 \\times 10^3)F_{S-h}
\n \\end{align*}
\n\\]<\/p>\n\n\n\n
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