| 21. | Where \ rho is the charge density and \ vec { J } the current density.
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| 22. | First, calculate the charge density, where is a function of the coordinates } }.
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| 23. | An example occurs in a capacitor circuit where time-varying charge densities exist on the plates.
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| 24. | This means that charge density is related to time, while current density is related to space.
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| 25. | The additional charge density is typically achieved by allowing higher manifold pressures before the onset of detonation.
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| 26. | The term on the left is the rate of change of the charge density at a point.
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| 27. | These are commonly called charge density waves, and they are an example of collective charge transport.
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| 28. | And in accordance of the charge density Q the following shaft is being set in mutual induction.
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| 29. | The charge density and electric potential are related by the first of Maxwell's equations, which gives
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| 30. | The rate of EOF is dependent on the field strength and the charge density of the capillary wall.
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