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∙ 9y agoalways towards the charge
Edwin Mitchell
The lines of force are drawn radially outward from a positive charge and radially inward toward a negative charge. They represent the direction a positive test charge placed in the field would move. The density of lines indicates the strength of the electric field.
The number that originates from a charge when an electric field line is drawn represents the magnitude of the charge creating the field. The field lines help us visualize the direction of the electric field and the relative strength of the field at different points around the charge. The closer the field lines are together, the stronger the electric field.
Electric field lines are drawn with arrows to show the direction of the force that a positive test charge would experience if placed in the field. The direction of the electric field at any point is the direction that a positive test charge would move when placed in the field at that point.
Electric field lines are drawn with arrows to indicate the direction a positive test charge would move when placed in the field. The arrows point in the direction of the force that the field would exert on a positive test charge. This helps visualize the electric field's strength and direction at different points around a charged object.
No, two electric field lines cannot originate from the same point because the electric field direction at that point would be ambiguous. Electric field lines always point in the direction of the electric field at a given point and represent the direction a positive test charge would move in that field.
Yes, electric field lines represent the direction in which a positive test charge would move in an electric field. The lines show the direction of the force that would be experienced by a positive charge placed in the field. Thus, the concept of electric field lines is connected to the electric field itself.
The number that originates from a charge when an electric field line is drawn represents the magnitude of the charge creating the field. The field lines help us visualize the direction of the electric field and the relative strength of the field at different points around the charge. The closer the field lines are together, the stronger the electric field.
Electric field lines are drawn with arrows to show the direction of the force that a positive test charge would experience if placed in the field. The direction of the electric field at any point is the direction that a positive test charge would move when placed in the field at that point.
Electric field lines are drawn with arrows to indicate the direction a positive test charge would move when placed in the field. The arrows point in the direction of the force that the field would exert on a positive test charge. This helps visualize the electric field's strength and direction at different points around a charged object.
An electric field is responsibly for the movement of DNA in gel electrophoresis. The net negative charge of the DNA is drawn to the positive charge of the anode.
No, two electric field lines cannot originate from the same point because the electric field direction at that point would be ambiguous. Electric field lines always point in the direction of the electric field at a given point and represent the direction a positive test charge would move in that field.
According to the law of electric charges,opposite charges attract and like repel. therefore, An electrical charge is placed on the part being painted, an opposite charge on the paint sprayer. Since opposite charges attract, paint droplets are drawn to the object being painted.
Given a positive charge the electric field lines are drawn starting from the charge and pointing radially outward, ending in principle at infinity, according to the electric field strength being proportional to the inverse square of distance. From the definition of electric field we know that the modulous of the electric field is greater for smaller distances from the field generating charge. Since the electric field lines point radially outward we consider the density of lines an indication of the strength of the electirc field. If we immagine to trace a circle around the electric field generating charge, of radius slightly greater than the radius of the object which holds the charge and therefore generates the electric field, such circle will be crossed by a number 'n' of lines. The density of lines crossing the cirle will then be the circumference of the circle divided by the number 'n' of lines. For a larger circle we will have a greater circumference, but same number of lines 'n', and therefore a smaller density of lines crossing it, which idicates a lower intesity of electric field for a greater distance from the charge.
According to the law of electric charges,opposite charges attract and like repel. therefore, An electrical charge is placed on the part being painted, an opposite charge on the paint sprayer. Since opposite charges attract, paint droplets are drawn to the object being painted.
The answer depends on how many cards are drawn and whether or not they are replaced afterwards.For a single card, drawn at random, the probability is 26/52 = 1/2.The answer depends on how many cards are drawn and whether or not they are replaced afterwards.For a single card, drawn at random, the probability is 26/52 = 1/2.The answer depends on how many cards are drawn and whether or not they are replaced afterwards.For a single card, drawn at random, the probability is 26/52 = 1/2.The answer depends on how many cards are drawn and whether or not they are replaced afterwards.For a single card, drawn at random, the probability is 26/52 = 1/2.
A single bond is typically represented as a straight line between two atoms in a drawn chemical structure. It indicates the sharing of one pair of electrons between the two bonded atoms.
The answer depends on how many cards are drawn, whether or not at random, with or without replacement. The probability for a single card, drawn at random, from a normal deck of playing cards is 2/13.The answer depends on how many cards are drawn, whether or not at random, with or without replacement. The probability for a single card, drawn at random, from a normal deck of playing cards is 2/13.The answer depends on how many cards are drawn, whether or not at random, with or without replacement. The probability for a single card, drawn at random, from a normal deck of playing cards is 2/13.The answer depends on how many cards are drawn, whether or not at random, with or without replacement. The probability for a single card, drawn at random, from a normal deck of playing cards is 2/13.
The answer depends on how many cards are drawn, whether or not at random, from an ordinary deck of cards, with or without replacement.The probability for a single card, drawn at random, from a normal deck of playing cards is 1/4.The answer depends on how many cards are drawn, whether or not at random, from an ordinary deck of cards, with or without replacement.The probability for a single card, drawn at random, from a normal deck of playing cards is 1/4.The answer depends on how many cards are drawn, whether or not at random, from an ordinary deck of cards, with or without replacement.The probability for a single card, drawn at random, from a normal deck of playing cards is 1/4.The answer depends on how many cards are drawn, whether or not at random, from an ordinary deck of cards, with or without replacement.The probability for a single card, drawn at random, from a normal deck of playing cards is 1/4.