Electric field in a region is given by , where and . If the electric potential at a point is , then the electric potential at origin is _____ V.
- A
- B
- C
- D
Electric field in a region is given by , where and . If the electric potential at a point is , then the electric potential at origin is _____ V.
Correct answer:A
Standard Method
Given: , with , , and .
Find: The electric potential at the origin.
The electric field is related to potential by
So, component-wise,
Thus,
Integrating with respect to ,
Differentiating with respect to ,
Integrating,
Hence,
Using the given value at ,
At the origin,
the solution states , which is inconsistent with the computed value. Since option A corresponds to and the source marks option A as correct, the listed answer follows the source, but the working gives .
Therefore, according to the solution's, the correct option is A.
Consistency Check
Given: from integration.
Find: Whether the final numerical value matches the derived constant.
Substitute , , :
So,
which gives
At the origin, both quadratic terms vanish:
Hence the algebra in the working supports , although the source declares option A.
Using instead of . This changes the sign of the potential function and gives the wrong constant. Always include the negative sign while relating field to potential.
Integrating only with respect to and forgetting the function of , written as . That loses the second variable dependence. After integrating partially, keep the integration 'constant' as a function of the other variable.
Substituting incorrectly, especially while squaring coordinates. Errors such as taking instead of lead to a wrong value of . Square each coordinate carefully before substitution.
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