Bohr radius to Earth's equatorial radius Converter Enter Bohr radius
b Earth's equatorial radius
earth's equatorial radius β
Switch to Earth's equatorial radius to Bohr radius Converter How to use this Bohr radius to Earth's equatorial radius Converter π€ Follow these steps to convert given length from the units of Bohr radius to the units of Earth's equatorial radius.
Enter the input Bohr radius value in the text field. The calculator converts the given Bohr radius into Earth's equatorial radius in realtime β using the conversion formula, and displays under the Earth's equatorial radius label. You do not need to click any button. If the input changes, Earth's equatorial radius value is re-calculated, just like that. You may copy the resulting Earth's equatorial radius value using the Copy button. To view a detailed step by step calculation of the conversion, click on the View Calculation button. You can also reset the input by clicking on Reset button present below the input field. Calculation Calculation will be done after you enter a valid input.
Examples
1
Consider that an electron in a hydrogen atom is found at 2 Bohr radii from the nucleus.
Answer:
Given:
The length in bohr radius is:
Length(Bohr radius) = 2
Formula:
The formula to convert length from bohr radius to earth's equatorial radius is:
Length(Earth's equatorial radius) = Length(Bohr radius) / 120529747123068590
Substitution:
Substitute given weight Length(Bohr radius) = 2 in the above formula.
Length(Earth's equatorial radius) = 2 / 120529747123068590
Length(Earth's equatorial radius) = 0
Final Answer:
Therefore, 2 b is equal to 0 earth's equatorial radius .
The length is 0 earth's equatorial radius , in earth's equatorial radius.
2
Consider that a quantum state calculation places an electron 3.5 Bohr radii away from the nucleus.
Answer:
Given:
The length in bohr radius is:
Length(Bohr radius) = 3.5
Formula:
The formula to convert length from bohr radius to earth's equatorial radius is:
Length(Earth's equatorial radius) = Length(Bohr radius) / 120529747123068590
Substitution:
Substitute given weight Length(Bohr radius) = 3.5 in the above formula.
Length(Earth's equatorial radius) = 3.5 / 120529747123068590
Length(Earth's equatorial radius) = 0
Final Answer:
Therefore, 3.5 b is equal to 0 earth's equatorial radius .
The length is 0 earth's equatorial radius , in earth's equatorial radius.
Bohr radius to Earth's equatorial radius Conversion TableThe following table gives some of the most used conversions from Bohr radius to Earth's equatorial radius.
Bohr radius (b ) Earth's equatorial radius (earth's equatorial radius ) 0 b 0 earth's equatorial radius 1 b 0 earth's equatorial radius 2 b 0 earth's equatorial radius 3 b 0 earth's equatorial radius 4 b 0 earth's equatorial radius 5 b 0 earth's equatorial radius 6 b 0 earth's equatorial radius 7 b 0 earth's equatorial radius 8 b 0 earth's equatorial radius 9 b 0 earth's equatorial radius 10 b 0 earth's equatorial radius 20 b 0 earth's equatorial radius 50 b 0 earth's equatorial radius 100 b 0 earth's equatorial radius 1000 b 0 earth's equatorial radius 10000 b 0 earth's equatorial radius 100000 b 0 earth's equatorial radius
Bohr radius The Bohr radius is a fundamental unit of length used in atomic physics to describe the size of the ground state orbit of an electron around a proton in a hydrogen atom. One Bohr radius is approximately 5.29177 Γ 10^(-11) meters or about 0.529 angstroms.
The Bohr radius is derived from the Bohr model of the atom, which describes the electron's orbit as quantized and stable. It provides a characteristic length scale for the electron's position in its lowest energy state, known as the ground state.
The Bohr radius is used in atomic and quantum physics to understand the size of atoms, atomic orbitals, and the fundamental structure of matter. It is a key parameter in the Bohr model and provides insight into the scale of atomic interactions and energy levels.
Earth's equatorial radius The Earth's equatorial radius is the distance from the Earth's center to the equator. One Earth's equatorial radius is approximately 6,378.1 kilometers or about 3,963.2 miles.
The equatorial radius is the longest radius of the Earth due to its equatorial bulge, caused by the planet's rotation. This bulge results in a slightly larger radius at the equator compared to the polar radius.
The Earth's equatorial radius is used in geodesy, cartography, and satellite navigation to define the Earth's shape and for accurate measurements of distances and areas on the Earth's surface. It provides a key parameter for understanding Earth's dimensions and its gravitational field.
Frequently Asked Questions (FAQs) 1. What is the formula for converting Bohr radius to Earth's equatorial radius in Length? The formula to convert Bohr radius to Earth's equatorial radius in Length is:
Bohr radius / 120529747123068590 2. Is this tool free or paid? This Length conversion tool, which converts Bohr radius to Earth's equatorial radius, is completely free to use.
3. How do I convert Length from Bohr radius to Earth's equatorial radius? To convert Length from Bohr radius to Earth's equatorial radius, you can use the following formula:
Bohr radius / 120529747123068590 For example, if you have a value in Bohr radius, you substitute that value in place of Bohr radius in the above formula, and solve the mathematical expression to get the equivalent value in Earth's equatorial radius.
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"examples": "<div class=\"example\">\n <div class=\"example_head\"><span class=\"example_n\">1</span>\n <h3 class=\"question\">Consider that an electron in a hydrogen atom is found at 2 Bohr radii from the nucleus.<br>Convert this distance from Bohr radii to Earth's equatorial radius.</h3></div>\n <h4 class=\"answer\">Answer:</h4>\n <p><strong>Given:</strong></p>\n <p>The length in bohr radius is:</p>\n <p class=\"step\"><span>Length<sub>(Bohr radius)</sub></span> = 2</p>\n <p><strong>Formula:</strong></p>\n <p>The formula to convert length from bohr radius to earth's equatorial radius is:</p>\n <p class=\"formula step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = <span>Length<sub>(Bohr radius)</sub></span> / 120529747123068590</p>\n <p><strong>Substitution:</strong></p>\n <p>Substitute given weight <strong>Length<sub>(Bohr radius)</sub> = 2</strong> in the above formula.</p>\n <p class=\"step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = <span>2</span> / 120529747123068590</p>\n <p class=\"step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = 0</p>\n <p><strong>Final Answer:</strong></p>\n <p>Therefore, <strong>2 b</strong> is equal to <strong>0 earth's equatorial radius</strong>.</p>\n <p>The length is <strong>0 earth's equatorial radius</strong>, in earth's equatorial radius.</p>\n </div>\n <div class=\"example\">\n <div class=\"example_head\"><span class=\"example_n\">2</span>\n <h3 class=\"question\">Consider that a quantum state calculation places an electron 3.5 Bohr radii away from the nucleus.<br>Convert this distance from Bohr radii to Earth's equatorial radius.</h3></div>\n <h4 class=\"answer\">Answer:</h4>\n <p><strong>Given:</strong></p>\n <p>The length in bohr radius is:</p>\n <p class=\"step\"><span>Length<sub>(Bohr radius)</sub></span> = 3.5</p>\n <p><strong>Formula:</strong></p>\n <p>The formula to convert length from bohr radius to earth's equatorial radius is:</p>\n <p class=\"formula step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = <span>Length<sub>(Bohr radius)</sub></span> / 120529747123068590</p>\n <p><strong>Substitution:</strong></p>\n <p>Substitute given weight <strong>Length<sub>(Bohr radius)</sub> = 3.5</strong> in the above formula.</p>\n <p class=\"step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = <span>3.5</span> / 120529747123068590</p>\n <p class=\"step\"><span>Length<sub>(Earth's equatorial radius)</sub></span> = 0</p>\n <p><strong>Final Answer:</strong></p>\n <p>Therefore, <strong>3.5 b</strong> is equal to <strong>0 earth's equatorial radius</strong>.</p>\n <p>The length is <strong>0 earth's equatorial radius</strong>, in earth's equatorial radius.</p>\n </div>\n ",
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"table1n": "<h2><span class=\"x\">Bohr radius</span> to <span class=\"y\">Earth's equatorial radius</span> Conversion Table</h2><p>The following table gives some of the most used conversions from Bohr radius to Earth's equatorial radius.</p><table><thead><tr><th scope=\"column\" role=\"columnheader\">Bohr radius (<span class=\"unit\">b</span>)</th><th scope=\"column\" role=\"columnheader\">Earth's equatorial radius (<span class=\"unit\">earth's equatorial radius</span>)</th><tr></thead><tbody><tr><td>0 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>1 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>2 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>3 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>4 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>5 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>6 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>7 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>8 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>9 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>10 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>20 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>50 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>100 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>1000 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>10000 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr><tr><td>100000 <span class=\"unit\">b</span></td><td>0 <span class=\"unit\">earth's equatorial radius</span></td></tr></table>",
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"x_long_desc": "The Bohr radius is a fundamental unit of length used in atomic physics to describe the size of the ground state orbit of an electron around a proton in a hydrogen atom. One Bohr radius is approximately 5.29177 Γ 10^(-11) meters or about 0.529 angstroms. </p><p>The Bohr radius is derived from the Bohr model of the atom, which describes the electron's orbit as quantized and stable. It provides a characteristic length scale for the electron's position in its lowest energy state, known as the ground state.</p><p>The Bohr radius is used in atomic and quantum physics to understand the size of atoms, atomic orbitals, and the fundamental structure of matter. It is a key parameter in the Bohr model and provides insight into the scale of atomic interactions and energy levels.",
"y_long_desc": "The Earth's equatorial radius is the distance from the Earth's center to the equator. One Earth's equatorial radius is approximately 6,378.1 kilometers or about 3,963.2 miles. </p><p>The equatorial radius is the longest radius of the Earth due to its equatorial bulge, caused by the planet's rotation. This bulge results in a slightly larger radius at the equator compared to the polar radius.</p><p>The Earth's equatorial radius is used in geodesy, cartography, and satellite navigation to define the Earth's shape and for accurate measurements of distances and areas on the Earth's surface. It provides a key parameter for understanding Earth's dimensions and its gravitational field."
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