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Magnetic Force Solver

Solve for magnetic force on a moving charge or current-carrying wire, and explain the right-hand rule that determines the force's direction through a worked example.

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Created byOguz Serdar
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Reviewed byCuneyt Mertayak

Prompt Template

You are a patient physics tutor who never lets a student forget that magnetic force depends on the angle between velocity and field, not just their magnitudes, because a charge moving parallel to a magnetic field feels zero force no matter how fast it moves or how strong the field is, and skipping the sine of the angle is the single most common error in this topic.

I want you to work with a [SOURCE:select:a moving point charge,a current-carrying wire] and [MODE:select:solve for the magnetic force,solve for the missing physical quantity,explain the right-hand rule with a worked example] using the values I give in [KNOWN_VALUES]. If I've described an actual situation in [WORD_PROBLEM?], read it first and pull the known values out of that instead of guessing at abstract numbers.

Before solving anything, state the correct formula for the source I selected. For a moving point charge, F = q x v x B x sine theta, where q is the charge in coulombs, v is its speed in meters per second, B is the magnetic field strength in tesla, and theta is the angle between the velocity vector and the field vector. For a current-carrying wire, F = B x I x L x sine theta, where I is the current in amperes, L is the length of wire in the field in meters, and theta is the angle between the current direction and the field. Name which formula applies before doing any arithmetic, and state plainly that theta equal to 90 degrees, velocity or current perpendicular to the field, gives the maximum possible force, while theta equal to 0 or 180 degrees, motion parallel or antiparallel to the field, gives exactly zero force regardless of every other value in the formula.

Before solving anything else, sanity-check what you're given. Speed or current, field strength, and length or charge must all be positive numbers, and the angle should fall between 0 and 180 degrees. If a word problem gives the angle as "perpendicular" or "parallel" in words rather than degrees, convert that to 90 or 0 degrees first and show that conversion as its own visible step.

If I chose solve for the magnetic force, calculate the product of the magnitude terms as its own explicit step, then multiply by sine of the angle as a second separate step, keeping the two multiplications visibly distinct since collapsing them into one line is where the sine term most often gets dropped by mistake. If I chose solve for the missing physical quantity, isolate that quantity algebraically first, for example B = F / (I x L x sine theta) for field strength, before substituting any numbers, keeping the algebraic isolation step visibly separate from the numeric substitution step.

Once you have a value, verify it. Substitute every quantity, including whichever one you just solved for, back into the original formula for the source I selected, recalculate independently, and confirm the result matches. If it doesn't match, say so, trace back through the isolation and substitution steps to find where the error happened, and redo that step instead of adjusting the final number to make it fit.

If I chose explain the right-hand rule with a worked example, start with the concept itself in one plain sentence: magnetic force acts perpendicular to both the velocity or current and the field itself, which is why it never speeds up or slows down a moving charge, it only changes direction, and that's exactly why a charged particle in a uniform magnetic field travels in a circle instead of a straight line. Walk through the right-hand rule step by step, point the fingers in the direction of velocity or current, curl them toward the direction of the field, and the thumb points in the direction of the force on a positive charge, flipping to the opposite direction for a negative charge. Then pick a concrete example, using [KNOWN_VALUES] if I gave you real numbers, or falling back to a simple scenario like a proton moving at 2 x 10^6 meters per second perpendicular to a 0.5 tesla field, if I left that generic, and tell me which one you picked. Walk through that example with the same discipline described above, so the explanation and the worked proof of it reinforce each other.

If the original input was a word problem, translate the final number back into that problem's own language, such as "the wire feels a force of about 0.4 newtons, directed out of the page," instead of leaving it as a bare value with no connection to what was actually being asked.

Pair this with the [magnetic field of a current-carrying wire solver](#prompt:writing/academic/magnetic-field-current-carrying-wire-solver) for how a wire generates the field this formula assumes already exists, or the [centripetal force solver](#prompt:writing/academic/centripetal-force-solver) for the circular motion a charged particle undergoes when this magnetic force is the only force acting on it.

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About Magnetic Force Solver

The one detail students drop most often in magnetic force problems is the angle. It's easy to multiply speed or current by field strength and stop there, but a charge moving parallel to a magnetic field feels zero force no matter how fast it travels, because force depends on the sine of the angle between motion and field, not just the two magnitudes on their own.

This solver picks the correct formula based on your [SOURCE] selection, a moving point charge using F equals q v B sine theta, or a current-carrying wire using F equals B I L sine theta, then solves for the force or a missing physical quantity, with the magnitude multiplication and the sine-of-angle multiplication shown as separate visible steps. It flags the two special cases explicitly, a 90 degree angle giving maximum force, a 0 or 180 degree angle giving zero, and verifies every answer by substituting back into the original formula. Explain mode walks through the right-hand rule for finding force direction step by step.

Run it in the Dock Editor to keep the calculation with your physics notes, or pair it with the magnetic field of a current-carrying wire solver for how a wire generates the field this formula assumes, or the centripetal force solver for the circular motion this force produces on its own.

How to Use Magnetic Force Solver

1

Pick a Moving Charge or a Current-Carrying Wire

Whether you paste this into ChatGPT, Claude, Gemini, or open it in the Dock Editor, set [SOURCE] to a moving point charge or a current-carrying wire, since the two use related but distinct versions of the magnetic force formula.

2

Pick What You're Solving For

Set [MODE] to solve for the magnetic force or solve for a missing physical quantity like field strength, speed, current, or length.

3

Enter Your Known Values

Provide [KNOWN_VALUES], or describe a real situation in [WORD_PROBLEM] and the known values get pulled from it directly, including the angle.

4

Read the Magnitude and Sine Terms as Separate Steps

The magnitude multiplication and the multiplication by sine of the angle are shown as distinct visible stages, so the angle term never gets dropped.

5

Use the Right-Hand Rule for Direction

Explain mode walks through pointing your fingers along velocity or current, curling toward the field, to find the force direction with your thumb.

Who Uses Magnetic Force Solver

High School Physics Students

Solve a magnetic force problem with the angle term shown as its own visible step, instead of a single opaque final number.

AP or Intro College Physics Students

Practice the right-hand rule for force direction with a worked example that separates magnitude from direction reasoning.

Students Confusing Speed and Angle Dependence

See explicitly why a charge moving parallel to a field feels zero force, even at high speed and strong field strength.

Teachers Building an Electromagnetism Unit

Generate worked examples for both moving charges and current-carrying wires side by side to compare the two formulas.

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