Glossary term: 引力常數
Description: 引力常數是宇宙中最重要的常數之一。它由艾薩克-牛頓首次提出。它是牛頓萬有引力定律的一部分,該定律表明,所有有質量的粒子都會相互吸引,這種吸引力與粒子質量的乘積成正比、與物體間距離的平方成反比。這個比例常數就是引力常數。通過實驗測得的引力常數值為 6.67 × 10-11 m3 kg-1 s-2。
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Term and definition status: The original definition of this term in English have been approved by a research astronomer and a teacher The translation of this term and its definition is still awaiting approval
This is an automated transliteration of the simplified Chinese translation of this term
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In Other Languages
- 阿拉伯語: ثابت الجاذبية
- 德語: Gravitationskonstante
- 英語: Gravitational Constant
- 西班牙語: Constante gravitacional
- 法語: Constante gravitationnelle
- 義大利語: Costante gravitazionale
- 日語: 万有引力定数 (external link)
- 韓語: 중력상수
- 巴西葡萄牙語: Constante gravitacional
- 簡體中文: 引力常数
Related Media
Apparatus for determining the gravitional constant
Caption: Observations of the motions of the planets around the Sun, or the Moon around the Earth, could not yield the gravitational constant, as in those cases, the mass of the central body is not initially known. Measuring the gravitational constant required a situation where the masses involved had been determined independent of measuring their gravitational attraction. The device shown here was built by John Michell (1724–1793), but Michell died before he could perform the experiment. Henry Cavendish (1731–1810) inherited the device, modified it so as to suppress external disturbances, and successfully completed the experiment. Cavendish's report to the Royal Society was under the title of "Experiments to determine the density of the Earth" as, from knowledge of the gravitational constant, the gravitational acceleration at Earth's surface and the Earth's radius, one can determine the Earth's mass and its mean density. From the modern perspective, what is now known as the "Cavendish experiment" is seen as a way of determining Newton's gravitational constant G.
The image shows a cross-section of the apparatus, which Cavendish had further isolated from environmental influences by putting it into a separate room and inside a wooden box. The devices allowing Cavendish to illuminate, observe and manipulate the experiment from the outside are pictured as well. The core of the experiment is a torsion balance using two small lead spheres. The restoring force of the torsion pendulum is deduced from its natural oscillation frequency in the absence of the large masses. The gravitational attraction of the small lead spheres to their larger counterparts can then be determined by measuring how far it makes the torsion pendulum masses deviate from their null position.
The image is a slightly modified (cropped, contrast and brightness adjusted) version of Fig. 1 in Cavendish's article in the Philosophical Transactions of the Royal Society, Volume 88 (December 1798), pp. 469–526 [DOI: 10.1098/rstl.1798.0022]. The permission of the Royal Society to publish this image under a CC BY licenses gratefully acknowledged.
Credit: Henry Cavendish in Philosophical Transactions of the Royal Society, DOI: 10.1098/rstl.1798.0022
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