When electrical current is run in the same direction as the main magnetic field, what happens to the gradients induced magnetic field?

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Study for the ARMRIT Registry Exam with detailed flashcards and multiple choice questions. Each question includes hints and explanations to help you succeed. Get ready to pass with confidence!

Multiple Choice

When electrical current is run in the same direction as the main magnetic field, what happens to the gradients induced magnetic field?

Explanation:
When electrical current flows in the same direction as the main magnetic field, it generates an induced magnetic field that aligns with and enhances the strength of the existing magnetic field. This phenomenon is a consequence of the right-hand rule in electromagnetism, which states that the direction of the induced magnetic field can be determined by the direction of the current flow. In this case, because the induced magnetic field complements the main magnetic field, the result is an increase in the overall magnetic field strength. This additive effect is crucial in various applications, especially in the design and functioning of magnetic resonance imaging (MRI) systems, where a stronger magnetic field leads to improved image quality and resolution. The other options suggest interactions that would weaken or reverse the magnetization, which does not occur when current flows in the same direction as the main magnetic field.

When electrical current flows in the same direction as the main magnetic field, it generates an induced magnetic field that aligns with and enhances the strength of the existing magnetic field. This phenomenon is a consequence of the right-hand rule in electromagnetism, which states that the direction of the induced magnetic field can be determined by the direction of the current flow.

In this case, because the induced magnetic field complements the main magnetic field, the result is an increase in the overall magnetic field strength. This additive effect is crucial in various applications, especially in the design and functioning of magnetic resonance imaging (MRI) systems, where a stronger magnetic field leads to improved image quality and resolution.

The other options suggest interactions that would weaken or reverse the magnetization, which does not occur when current flows in the same direction as the main magnetic field.

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