Answer:
The statements that apply are:
Explanation:
Faraday's law says that the induced emf [tex]\varepsilon[/tex] is equal to
[tex]\varepsilon = N \dfrac{d\Phi_ B}{dt },[/tex]
where N is the number of turns, and [tex]\Phi_B[/tex] is the magnetic flux through the loop:
[tex]\Phi_B = BA cos(\theta)[/tex];
therefore,
[tex]\varepsilon = N \dfrac{d(BAcos(\theta))}{dt },[/tex]
which means emf will be induced in a coil whenever the magnetic field [tex]B[/tex], the area [tex]A[/tex], or the angle [tex]\theta[/tex] is changed. Given this, let us look at each of the statements one by one:
(1). It is possible to induce a current in a closed loop of wire by changing the orientation of a magnetic field enclosed by the wire. ( Yes. This changes [tex]\theta[/tex])
(2). It is possible to induce a current in a closed loop of wire by changing the strength of a magnetic field enclosed by the wire. ( Yes. This changes [tex]B[/tex])
(3). It is possible to induce a current in a closed loop of wire without the aid of a power supply or battery. (Yes, a changing magnetic field can also do the job)
(4). It is possible to induce a current in a closed loop of wire located in a uniform magnetic field without rotating the loop and without changing the loop shape. (Nope. This does not change [tex]B,A,[/tex] or [tex]\theta[/tex].)
(5). It is possible to induce a current in a closed loop of wire located in a uniform magnetic field by either increasing or decreasing the area enclosed by the loop. (Yep. This changes [tex]A[/tex])
Thus, the statements that apply are (1), (2), (3), and (5).
