Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Physics-

General

Easy

Question

The magnetic field due to a current carrying square loop of side a at a point located symmetrically at a distance of a/2 from its centre (as shown is)

$\frac{\sqrt{2} μ_{0} i}{\sqrt{3} π a}$
$\frac{μ_{0} i}{\sqrt{6} π a}$
$\frac{2 μ_{0} i}{\sqrt{3} π a}$
zero

The correct answer is: $fraction numerator 2 mu subscript 0 end subscript i over denominator square root of 3 pi a end fraction$

Related Questions to study

A long wire carrying current i is bent to form a right angle as shown in figure .Then magnetic induction at point P on the bisector of this angle at a distance r from the vertex is

A long wire carrying current i is bent to form a right angle as shown in figure .Then magnetic induction at point P on the bisector of this angle at a distance r from the vertex is

Physics-General

Find the magnetic induction of the field at the point O of a loop with current I, whose shape is illustrated in fig. the radius a and the side b are known

Find the magnetic induction of the field at the point O of a loop with current I, whose shape is illustrated in fig. the radius a and the side b are known

Physics-General

Find the magnetic field at P due to the arrangement shown

Find the magnetic field at P due to the arrangement shown

Physics-General

parallel

If the magnitude of the resultant magnetic field inductions at the points A, B and C due to the infinitely long parallel conductors carrying currents $I$ in the direction shown are B. B and B respectively then, the ascending order of magnetic fields induction are

If the magnitude of the resultant magnetic field inductions at the points A, B and C due to the infinitely long parallel conductors carrying currents $I$ in the direction shown are B. B and B respectively then, the ascending order of magnetic fields induction are

Physics-General

Consider two different ammeters in which the deflections of the needle are proportional to current. The first ammeter is connected to a resistor of resistance $R subscript 1 end subscript$ and the second to a resistor of unknown resistance $R subscript x end subscript$ . At first the ammeters are connected in series between points A and B [as shown in fig. a)]. In this case the readings of the ammeters are $n subscript 1 end subscript$ and $n subscript 2 end subscript.$ Then the ammeters are connected parallel between A and B as shown in fig.(B) and indicated $n subscript 1 end subscript superscript ´ end superscript$ and $n subscript 2 end subscript superscript ´ end superscript.$ Determine the unknown resistance $R subscript x end subscript$ of the second resistor.

Consider two different ammeters in which the deflections of the needle are proportional to current. The first ammeter is connected to a resistor of resistance $R subscript 1 end subscript$ and the second to a resistor of unknown resistance $R subscript x end subscript$ . At first the ammeters are connected in series between points A and B [as shown in fig. a)]. In this case the readings of the ammeters are $n subscript 1 end subscript$ and $n subscript 2 end subscript.$ Then the ammeters are connected parallel between A and B as shown in fig.(B) and indicated $n subscript 1 end subscript superscript ´ end superscript$ and $n subscript 2 end subscript superscript ´ end superscript.$ Determine the unknown resistance $R subscript x end subscript$ of the second resistor.

Physics-General

A voltmeter of resistance $R subscript 1 end subscript$ and an ammeter of resistance $R subscript 2 end subscript$ are conected in series across a battery of negligible internal resistance. When a resistance R is connected in parallel to voltmeter, reading of ammeter increases three times while that of voltmeter reduces to one third. Find $R subscript 1 end subscript$ and $R subscript 2 end subscript$ in terms of R.

A voltmeter of resistance $R subscript 1 end subscript$ and an ammeter of resistance $R subscript 2 end subscript$ are conected in series across a battery of negligible internal resistance. When a resistance R is connected in parallel to voltmeter, reading of ammeter increases three times while that of voltmeter reduces to one third. Find $R subscript 1 end subscript$ and $R subscript 2 end subscript$ in terms of R.

Physics-General

parallel

A galvanometer of resistance $95 capital omega$ ,shunted by a resistance of 5 ohm gives a deflection of 50 divisions when joined in series with a resistance of $20 k capital omega$ and a 2 volt accumulator. What is the current sensitivity of the galvanometer (in div/ $mu$ (A) ?

A galvanometer of resistance $95 capital omega$ ,shunted by a resistance of 5 ohm gives a deflection of 50 divisions when joined in series with a resistance of $20 k capital omega$ and a 2 volt accumulator. What is the current sensitivity of the galvanometer (in div/ $mu$ (A) ?

Physics-General

A galvanometer has a current sensitivity of 1mA per division. A variable shunt is connected across the galvanometer and the combination is put in series with a resistance of $500 capital omega$ and cell of internal resistance $0.5 capital omega$ . It gives a deflection of 5 division for shunt of 5 ohm and 20 division for shunt of 25 ohm. Find the emf of cell and resistance of galvanometer.

A galvanometer has a current sensitivity of 1mA per division. A variable shunt is connected across the galvanometer and the combination is put in series with a resistance of $500 capital omega$ and cell of internal resistance $0.5 capital omega$ . It gives a deflection of 5 division for shunt of 5 ohm and 20 division for shunt of 25 ohm. Find the emf of cell and resistance of galvanometer.

Physics-General

A thin non conducting disc of radius R is rotating clockwise (see figure) with an angular velocity w about its central axis, which is perpendicular to its plane. Both its surfaces carry +ve charges of uniform surface density. Half the disc is in a region of a uniform, unidirectional magnetic field B parallel to the plane of the disc, as shown. Then,

A thin non conducting disc of radius R is rotating clockwise (see figure) with an angular velocity w about its central axis, which is perpendicular to its plane. Both its surfaces carry +ve charges of uniform surface density. Half the disc is in a region of a uniform, unidirectional magnetic field B parallel to the plane of the disc, as shown. Then,

Physics-General

parallel

A conducting ring of mass 2kg and radius 0.5m is placed on a smooth horizontal plane. The ring carries a current i=4A. A horizontal magnetic field B=10T is switched on at time t=0 as shown in figure. The initial angular acceleration of the ring will be

A conducting ring of mass 2kg and radius 0.5m is placed on a smooth horizontal plane. The ring carries a current i=4A. A horizontal magnetic field B=10T is switched on at time t=0 as shown in figure. The initial angular acceleration of the ring will be

Physics-General

Calculate the magnetic moment of a thin wire with a current I=0.8A, wound tightly on half a tore. The diameter of the cross-section of the tore is equal to d=5.0cm, the number of turns is N=500.

Calculate the magnetic moment of a thin wire with a current I=0.8A, wound tightly on half a tore. The diameter of the cross-section of the tore is equal to d=5.0cm, the number of turns is N=500.

Physics-General

A straight current carrying conductor is placed in such a way that the current in the conductor flows in the direction out of the plane of the paper. The conductor is placed between two poles of two magnets, as shown. The conductor will experience a force in the direction towards

A straight current carrying conductor is placed in such a way that the current in the conductor flows in the direction out of the plane of the paper. The conductor is placed between two poles of two magnets, as shown. The conductor will experience a force in the direction towards

Physics-General

parallel

A long horizontal wire AB which is free to move in vertical plane and carries a steady current 20A, is in equilibrium at a height of 0.1 meter above another parallel long wire CD, which is fixed in horizontal plane and carries current 30A, as shown in the figure. Find the time period of oscillations when AB is slightly depressed $open parentheses g equals 10 m divided by s to the power of 2 end exponent close parentheses$

A long horizontal wire AB which is free to move in vertical plane and carries a steady current 20A, is in equilibrium at a height of 0.1 meter above another parallel long wire CD, which is fixed in horizontal plane and carries current 30A, as shown in the figure. Find the time period of oscillations when AB is slightly depressed $open parentheses g equals 10 m divided by s to the power of 2 end exponent close parentheses$

Physics-General

Figure shows a rod PQ of length 20.0cm and mass 200g suspended through a fixed point O by two threads of lengths 20.0cm each. A magnetic field of strength 0.500T exists in the vicinity of the wire PQ as shown in the figure. The wires connecting PQ with the battery are loose and exert no force on PQ. A current of 2.0A is established when the switch S is closed. Find the tension in the threads now.

Figure shows a rod PQ of length 20.0cm and mass 200g suspended through a fixed point O by two threads of lengths 20.0cm each. A magnetic field of strength 0.500T exists in the vicinity of the wire PQ as shown in the figure. The wires connecting PQ with the battery are loose and exert no force on PQ. A current of 2.0A is established when the switch S is closed. Find the tension in the threads now.

Physics-General

A particle of charge Q and mass M moves in a circular path of radius R in a uniform magnetic field of magnitude B. The same particle now moves with the same speed in a circular path of same radius R in the space between the cylindrical electrodes of the cylindrical capacitor. The radius of the inner electrode is R/2 while that of the outer electrode is 3R/2. Then the potential difference between the capacitor electrodes must be

A particle of charge Q and mass M moves in a circular path of radius R in a uniform magnetic field of magnitude B. The same particle now moves with the same speed in a circular path of same radius R in the space between the cylindrical electrodes of the cylindrical capacitor. The radius of the inner electrode is R/2 while that of the outer electrode is 3R/2. Then the potential difference between the capacitor electrodes must be

Physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.