COMEDK 2024 Shift 2 Paper

To determine the magnitude of the magnetic force on a current-carrying wire in a magnetic field, we use the formula for the magnetic force on a current element, which is given by:

d

→

F

=Id

→

l

×

→

B

where:
I is the current,
d

→

l

is the infinitesimal length vector of the wire, and

→

B

is the magnetic field vector.
In this problem, the given parameters are:
Length of the wire, L=2m
Current, I=1A
Direction of the wire along the x axis, so d

→

l

can be expressed as dx

^

i

.
The magnetic field

→

B

=B0(

^

i

+

^

j

+

^

k

)T.
Firstly, since the wire is along the x axis, its length vector is:

→

l

=2

^

i

m
Since it carries a current of 1 A , the force on the wire can be given by integrating along its length:

→

F

=I‌∫d

→

l

×

→

B

=I

→

l

×

→

B

Substituting the values, we get:

→

F

=1A×2

^

i

×B0(

^

i

+

^

j

+

^

k

)
Using the distributive property of the cross product, we have:

→

F

=2B0

^

i

×(

^

i

+

^

j

+

^

k

)
Since the cross product of any vector with itself is zero,

^

i

×

^

i

=0 :

→

F

=2B0(

^

i

×

^

j

+

^

i

×

^

k

)
We know from the right-hand rule for cross products that:
‌

^

i

×

^

j

=

^

k

‌

^

i

×

^

k

=−

^

j

Substituting these into the equation, we have:

→

F

=2B0(

^

k

−

^

j

)
The magnitude of this force is obtained by finding the vector magnitude:
Thus, the magnitude of the magnetic force on the wire is:
Option D: 2√2B0N