P2B_P4_part_1_MOVING_CHARGES_AND_MAGNETISM[1] - Read-Only-1.pdf
MEGHASASI1
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Aug 04, 2024
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About This Presentation
Moving charges
Slide Content
⑮
•Christian oersted discovered magnetic field surrounding a current
carrying wire
•The direction of magnetic field depends on direction of current
Oersted’s Experiment
⑭
carrying wire
•The direction of magnetic field depends on direction of current
Oersted’s Experiment
⑭
Magnetic Field
•Space surrounding a magnet, where its influence is felt.
•Strength of magnetic field is represented by magnetic field
intensity $
•SI Unit is Tesla(T) or Wb/m
2
--
-
T
-D
"¥
Sn ①
-
rected
I
=
B
.
N
- -
-
webn
=
B
-
-
-
-
webdm
-m2
--
•Space surrounding a magnet, where its influence is felt.
•Strength of magnetic field is represented by magnetic field
intensity $
•SI Unit is Tesla(T) or Wb/m
2
--
-
T
-D
"¥
Sn ①
-
rected
I
=
B
.
N
- -
-
webn
=
B
-
-
-
-
webdm
-m2
--
Magnetic Lorentz Force
•It is the force acting on a moving charged particle in an external
magnetic field
F = q v B sin
&? = q( x?;
-
--
- - - -
-
⑬
v
E
-
↑
&B
=
0
-
---
V -In-
-
angleb-
•It is the force acting on a moving charged particle in an external
magnetic field
F = q v B sin
&? = q( x?;
-
--
- - - -
-
⑬
v
E
-
↑
&B
=
0
-
---
V -In-
-
angleb-
•It is the force acting on a moving charged particle moving in an
combined magnetic field(B) and electric field(E)
F = F
electric + F
magnetic
&? = qq +q( x?;
Lorentz force
Fe
=
9E
-
Fi
=
q
(UXB)
--
--
combined magnetic field(B) and electric field(E)
F = F
electric + F
magnetic
&? = qq +q( x?;
Lorentz force
Fe
=
9E
-
Fi
=
q
(UXB)
--
--
Write the expression for Lorentz force acting on a moving charge.
[SAY – 2020]
-
-
-
-
-
-
F
=
qE
+
q(vXx)
-
-
-
[SAY – 2020]
-
-
-
-
-
-
F
=
qE
+
q(vXx)
-
-
-
An electron is placed in a magnetic field of uH s r
8
T. find the force
acting on the electron
-
E
-
-
*X
X
X
F
=
q(v-xi)
i
-
>
v
=
X
XXX
XXXX
8
T. find the force
acting on the electron
-
E
-
-
*X
X
X
F
=
q(v-xi)
i
-
>
v
=
X
XXX
XXXX
Motion of a charged particle in a uniform magnetic field
Charged particle entering parallel to external magnetic field
- -
- -
- OD
=
O
=B
q-
v
i
F
=
gubsin
o
F
=
0
-
S
-
Constantreclocity
-
-
Charged particle entering parallel to external magnetic field
- -
- -
- OD
=
O
=B
q-
v
i
F
=
gubsin
o
F
=
0
-
S
-
Constantreclocity
-
-
The path of a charged particle entering parallel to uniform magnetic
field will be
a)Circular
b)Helical
c)Straight line
d)None of these (1)[March 2020]
-
~
-
field will be
a)Circular
b)Helical
c)Straight line
d)None of these (1)[March 2020]
-
~
-
Flemings Left Hand Rule
Direction of Magnetic FieldFore finger
Direction of CurrentMiddle finger
Direction of Force on
positively charged particle
Thumb
-
-
-
-
-
Direction of Magnetic FieldFore finger
Direction of CurrentMiddle finger
Direction of Force on
positively charged particle
Thumb
-
-
-
-
-
Charged particle entering perpendicular to
external magnetic field
•When a charged particle of mass(m) and charge(q) moves
perpendicular to Mag. Field of strength($) with a velocity(v),
constant force acts right angles to the motion of particle
This provides necessary
centripetal force and path of
particle will be a CIRCLE
-
-
-
-
-
&
external magnetic field
•When a charged particle of mass(m) and charge(q) moves
perpendicular to Mag. Field of strength($) with a velocity(v),
constant force acts right angles to the motion of particle
This provides necessary
centripetal force and path of
particle will be a CIRCLE
-
-
-
-
-
&
f
i
-v
av S
↓ &
0
=
909 F
=
quBSin90
fqui
--
i
-v
av S
↓ &
0
=
909 F
=
quBSin90
fqui
--
3. Charged particle entering at an angle ? to
external magnetic field
nmen
i
·
10
----
vcose &
S
external magnetic field
nmen
i
·
10
----
vcose &
S
A charged particle enters a uniform magnetic field at an angle of
v r
?
? It's path becomes_____________
[march 2019]
~
backcal
-
-
-
v r
?
? It's path becomes_____________
[march 2019]
~
backcal
-
-
-
Two charged particles M
5 and M
6 are moving through a uniform
magnetic field :$; as shown in figure:
(a) What is the shape of path of M
5 and M
6.
[march 2018]
-
-
-
9aheckcal
92-
q
92
/
-
--
5 and M
6 are moving through a uniform
magnetic field :$; as shown in figure:
(a) What is the shape of path of M
5 and M
6.
[march 2018]
-
-
-
9aheckcal
92-
q
92
/
-
--
Biot – Savart’s Law
•Magnetic field at a point due to current carrying element is
directly proportional to
Strength of current(I)
Length of element(dl)
Sine of angle between element and
line joining element and the point
Inversely proportional to square of
distance between element and point
- -
-
=
-
dis&I
%
Eu
dis
add
20
edissind
M
di
•Magnetic field at a point due to current carrying element is
directly proportional to
Strength of current(I)
Length of element(dl)
Sine of angle between element and
line joining element and the point
Inversely proportional to square of
distance between element and point
- -
-
=
-
dis&I
%
Eu
dis
add
20
edissind
M
di
dis
2I
delsind
-22
*
dot
paiabichty
&
B
I
doIddSind
offar
-
-
space
&
GTT
22 -
Gi
X107
Mo
=
-
2I
delsind
-22
*
dot
paiabichty
&
B
I
doIddSind
offar
-
-
space
&
GTT
22 -
Gi
X107
Mo
=
-
Biot - Savarts Law
dn =
J
?
??
u?? ???
?
?
J
? = Permeability of
free space
?? x 10
-7
Tm/A
dn =
J
?
??
u:?? ?;
?
?
?????? r???
==
-
-
~
dn =
J
?
??
u?? ???
?
?
J
? = Permeability of
free space
?? x 10
-7
Tm/A
dn =
J
?
??
u:?? ?;
?
?
?????? r???
==
-
-
~
Magnetic Field due to current carrying circular
conductor
•Consider a circular coil of radius, a carrying a current I.
•Let P be point on the axis of coil at a distance, r from the centre - O
- - -
di
⑬
discost
Whd
Se#
-z
I
*
dissing
- W
&
-----dissing
~
x
i
di
n dicosd
ad
conductor
•Consider a circular coil of radius, a carrying a current I.
•Let P be point on the axis of coil at a distance, r from the centre - O
- - -
di
⑬
discost
Whd
Se#
-z
I
*
dissing
- W
&
-----dissing
~
x
i
di
n dicosd
ad
Magnetic Field due to current carrying circular
conductor
*
Sin
90
=
1
d
B
I
do
since
-
-
-gitxh
&B
MoTdd
--I
G
= -
Gitx2
-
Totalmagnetic
feel
dB
=
dasind
+
desind
=
2
dis
sind
FF
conductor
*
Sin
90
=
1
d
B
I
do
since
-
-
-gitxh
&B
MoTdd
--I
G
= -
Gitx2
-
Totalmagnetic
feel
dB
=
dasind
+
desind
=
2
dis
sind
FF
dis'
=
2
doIdsindSind
=
witxh
dB'
=
2)
MoI
di
a
B
=
do
Ia
It
a
-
-
- -
Zitx3
2
pitx3
--
↑
a
-
dis'
=
doI
de
a 2x3
2πx3
I
I
B
=
doId
e
=
2
doIdsindSind
=
witxh
dB'
=
2)
MoI
di
a
B
=
do
Ia
It
a
-
-
- -
Zitx3
2
pitx3
--
↑
a
-
dis'
=
doI
de
a 2x3
2πx3
I
I
B
=
doId
e
Right Hand Grip Rule
•If the current carrying element is grasped
in the right hand with the thumb pointing
in the direction of current.
•Then the outer fingers lying in
perpendicular direction gives the
direction of magnetic field
-
•If the current carrying element is grasped
in the right hand with the thumb pointing
in the direction of current.
•Then the outer fingers lying in
perpendicular direction gives the
direction of magnetic field
-
Ampere’s Circuital Law
•The line integral of magnetic field around any closed loop is equal
to μ
r times the total current enclosed by the loop
?$?@HLμ
r+
?$ @H?KO?Lμ
r+
I
-
-
-
=- =-
del
-
-
-
>
11
I
I
-
&
M
-
I11
-
I
•The line integral of magnetic field around any closed loop is equal
to μ
r times the total current enclosed by the loop
?$?@HLμ
r+
?$ @H?KO?Lμ
r+
I
-
-
-
=- =-
del
-
-
-
>
11
I
I
-
&
M
-
I11
-
I
B At Point Due To An Infinitely Long Straight
Wire Carrying Current
P
=
-
SB
.
di
=
do
I
NE
SBdd
Cosc
=
doI
[
0
=
8
B
M
↑
Sidd
=
clot
B/dd
=
do
I
--
Wire Carrying Current
P
=
-
SB
.
di
=
do
I
NE
SBdd
Cosc
=
doI
[
0
=
8
B
M
↑
Sidd
=
clot
B/dd
=
do
I
--
B At Point Due To An Infinitely Long Straight
Wire Carrying Current
BLITZ
=
do
I
do
I
=
-
B
-
2π
y
-
Wire Carrying Current
BLITZ
=
do
I
do
I
=
-
B
-
2π
y
-
Magnetic Field Intensity Due to Solenoid
D
- C--
-
-
i
-
·
BE
i
----
-A B
-
L
-
GB
.
del
=
Mo
I
A
A
C
Side
+
Bidd
+fide
+
I
de -lot
B
S
D
- C--
-
-
i
-
·
BE
i
----
-A B
-
L
-
GB
.
del
=
Mo
I
A
A
C
Side
+
Bidd
+fide
+
I
de -lot
B
S
t t
Ba
"
op
·
self p
Si
-
!
O
O
6
=
MOI
I
BL
=
MowI
B Mol MONI
&
Bac
=
N
=
n
I
B
= -L
B
Sdd
=
Mol B
=
Mon
I-
Ba
"
op
·
self p
Si
-
!
O
O
6
=
MOI
I
BL
=
MowI
B Mol MONI
&
Bac
=
N
=
n
I
B
= -L
B
Sdd
=
Mol B
=
Mon
I-
SAY
EXAM PYQ(2021)
State Ampere's circuital law. Use this law to obtain the expression for
the magnetic field inside a current carrying solenoid at an axial point
near the centre.
3 Marks
BOARD
EXAM PYQ(2021)
EXAM PYQ(2021)
State Ampere's circuital law. Use this law to obtain the expression for
the magnetic field inside a current carrying solenoid at an axial point
near the centre.
3 Marks
BOARD
EXAM PYQ(2021)
Force acting on a current carrying conductor placed in
magnetic field
Consider a rod of uniform cross-section ‘A’ and length ‘l’ . Keep
this in a magnetic field of ‘B’
n number of electrons per unit volume ( number density )
Total charge in the conductor = nAlq
8
? average drift velocity of all the charges
F =
magnetic field
Consider a rod of uniform cross-section ‘A’ and length ‘l’ . Keep
this in a magnetic field of ‘B’
n number of electrons per unit volume ( number density )
Total charge in the conductor = nAlq
8
? average drift velocity of all the charges
F =
Moving Coil Galvanometer
•Principle : A current carrying rectangular coil placed in a magnetic
field experiences a torque
•This torque is proportional to the strength of the current passing
through it
-
-D
•Principle : A current carrying rectangular coil placed in a magnetic
field experiences a torque
•This torque is proportional to the strength of the current passing
through it
-
-D
Conversion of galvanometer into voltmeter
•By putting high resistance R in series with the galvanometer
R =
- - -
VG
-
-
&
um
F
OIg
high
on
•By putting high resistance R in series with the galvanometer
R =
- - -
VG
-
-
&
um
F
OIg
high
on
Conversion of galvanometer into ammeter
•By putting low resistance S in parallel with the galvanometer
S =
S = Shunt Resistance
Ig
9
6
-
=
--Ig
O
T
dow
reach
mu
•By putting low resistance S in parallel with the galvanometer
S =
S = Shunt Resistance
Ig
9
6
-
=
--Ig
O
T
dow
reach
mu
A galvanometer with coil resistance 12Ω shows full-scale deflection
for a current of 2.5 mA. How will you convert it in to an ammeter of
range 0 – 7.5 A ?
for a current of 2.5 mA. How will you convert it in to an ammeter of
range 0 – 7.5 A ?
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