1 mV/m = 6,241,495,961,752,113 eV/e
1 eV/e = 1.6022e-16 mV/m
Example:
Convert 15 Millivolt per Meter to Electronvolt per Elementary Charge:
15 mV/m = 93,622,439,426,281,700 eV/e
| Millivolt per Meter | Electronvolt per Elementary Charge |
|---|---|
| 0.01 mV/m | 62,414,959,617,521.13 eV/e |
| 0.1 mV/m | 624,149,596,175,211.4 eV/e |
| 1 mV/m | 6,241,495,961,752,113 eV/e |
| 2 mV/m | 12,482,991,923,504,226 eV/e |
| 3 mV/m | 18,724,487,885,256,340 eV/e |
| 5 mV/m | 31,207,479,808,760,564 eV/e |
| 10 mV/m | 62,414,959,617,521,130 eV/e |
| 20 mV/m | 124,829,919,235,042,260 eV/e |
| 30 mV/m | 187,244,878,852,563,400 eV/e |
| 40 mV/m | 249,659,838,470,084,500 eV/e |
| 50 mV/m | 312,074,798,087,605,600 eV/e |
| 60 mV/m | 374,489,757,705,126,800 eV/e |
| 70 mV/m | 436,904,717,322,647,940 eV/e |
| 80 mV/m | 499,319,676,940,169,000 eV/e |
| 90 mV/m | 561,734,636,557,690,200 eV/e |
| 100 mV/m | 624,149,596,175,211,300 eV/e |
| 250 mV/m | 1,560,373,990,438,028,300 eV/e |
| 500 mV/m | 3,120,747,980,876,056,600 eV/e |
| 750 mV/m | 4,681,121,971,314,085,000 eV/e |
| 1000 mV/m | 6,241,495,961,752,113,000 eV/e |
| 10000 mV/m | 62,414,959,617,521,130,000 eV/e |
| 100000 mV/m | 624,149,596,175,211,300,000 eV/e |
Millivolt per meter (mV/m) is a unit of electric potential gradient, representing the change in electric potential per unit distance. It is commonly used in various fields, including electrical engineering and physics, to measure the strength of electric fields. Understanding this unit is essential for engineers and scientists working with electromagnetic fields and electrical systems.
The millivolt per meter is derived from the International System of Units (SI). One millivolt (mV) is equal to one-thousandth of a volt (V), and the meter (m) is the standard unit of length in the SI system. This standardization ensures consistency and accuracy in measurements across different applications and industries.
The concept of electric potential and its measurement has evolved significantly since the early days of electricity. The introduction of the volt as a unit of electric potential was established in the 19th century, and the millivolt emerged as a practical subunit for measuring smaller electric potentials. Over time, the use of millivolt per meter has become crucial in various scientific and engineering applications, particularly in the study of electric fields.
To illustrate the use of millivolt per meter, consider an electric field with a potential difference of 50 millivolts across a distance of 10 meters. The electric field strength can be calculated as follows:
[ \text{Electric Field (E)} = \frac{\text{Potential Difference (V)}}{\text{Distance (d)}} ]
[ E = \frac{50 , \text{mV}}{10 , \text{m}} = 5 , \text{mV/m} ]
Millivolt per meter is widely used in various applications, including:
To effectively use the millivolt per meter tool on our website, follow these steps:
What is millivolt per meter (mV/m)? Millivolt per meter is a unit of electric potential gradient, measuring the change in electric potential per unit distance.
How do I convert millivolt per meter to other units? You can use our unit converter tool to easily convert millivolt per meter to other units of electric field strength.
What is the significance of measuring electric fields in mV/m? Measuring electric fields in millivolt per meter is crucial for understanding electromagnetic effects in various applications, including electronics and biology.
Can I use this tool for high voltage applications? While the tool is designed for millivolt measurements, it can help in understanding electric fields in low voltage applications. For high voltage scenarios, ensure to use appropriate units and safety measures.
Where can I find more information on electric potential and its applications? Visit our website here for comprehensive resources and guides on electric potential and related units.
By utilizing the millivolt per meter tool effectively, you can enhance your understanding of electric fields and their applications, ultimately contributing to improved performance in your projects and research.
The Electronvolt per Elementary Charge (eV/e) is a unit of electric potential energy, representing the amount of energy gained by a single elementary charge (like an electron) when it is accelerated through an electric potential difference of one volt. This tool is essential for physicists, engineers, and students who are working with concepts in quantum mechanics, particle physics, and electrical engineering.
An electronvolt (eV) is defined as the amount of kinetic energy gained by an electron when it is accelerated through an electric potential difference of one volt. The elementary charge (e) is the charge of a single proton or the negative of the charge of a single electron, approximately equal to (1.602 \times 10^{-19}) coulombs.
The electronvolt is a standard unit of energy in the International System of Units (SI) but is often used in fields such as atomic and particle physics. The relationship between eV and other energy units, such as joules (J), is crucial for accurate calculations and conversions.
The concept of the electronvolt emerged in the early 20th century as scientists began to explore the properties of subatomic particles. As research in quantum mechanics and particle physics advanced, the electronvolt became a fundamental unit for measuring energy at microscopic scales, facilitating a deeper understanding of atomic interactions and energy levels.
To illustrate the use of the electronvolt per elementary charge, consider an electron that is accelerated through a potential difference of 5 volts. The energy gained by the electron can be calculated as follows:
[ \text{Energy (in eV)} = \text{Voltage (in V)} \times \text{Charge (in e)} ] [ \text{Energy} = 5 , \text{V} \times 1 , \text{e} = 5 , \text{eV} ]
The electronvolt is commonly used in various scientific fields, including:
To use the Electronvolt per Elementary Charge tool effectively:
1. What is the relationship between electronvolts and joules?
The relationship is given by (1 , \text{eV} = 1.602 \times 10^{-19} , \text{J}). This conversion is essential for translating energy values in different contexts.
2. How do I convert volts to electronvolts?
To convert volts to electronvolts, multiply the voltage by the elementary charge (1 e). For example, 10 volts equals 10 eV.
3. Why is the electronvolt important in physics?
The electronvolt is crucial for quantifying energy at the atomic and subatomic levels, making it a standard unit in fields like particle physics and quantum mechanics.
4. Can I use this tool for other types of charges?
This tool is specifically designed for elementary charges. For other charge types, adjustments may be necessary based on the charge's magnitude.
5. Is there a limit to the voltage I can input?
While there is no strict limit, extremely high voltages may not be practical for most applications. Always consider the context of your calculations.
For more information and to access the tool, visit Inayam's Electronvolt per Elementary Charge Converter. This tool is designed to enhance your understanding and application of electric potential in various scientific fields.
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