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New answer posted

a year ago

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P
Payal Gupta

Contributor-Level 10

3.7 Let us assume R = 2.1 Ω, T = 27.5 °C, R1 = 2.7 Ω, T1 = 100 ? , α = resistivity of silver

We know the relation of α can be given as

α = R1-RR(T1-T) = 2.7-2.12.1(100-27.5) = 3.94 *10-3 ?-1

New answer posted

a year ago

0 Follower 2 Views

P
Payal Gupta

Contributor-Level 10

3.6 Given, length of the wire, l = 15 m

Uniform cross section, A = 6.0 *10-7 m2

Resistance measured, R = 5.0 Ω

From the relation of

R = ρlA , where ρ is the resistivity of the material, we get

ρ=ARl = 6.0*10-7*515 = 2 *10-7 Ωm.

New answer posted

a year ago

0 Follower 7 Views

P
Payal Gupta

Contributor-Level 10

3.5 Let T be the room temperature and R be the resistance at room temperature and T1 be the required temperature and R1 be the resistance at that temperature and α be the coefficient of resistor.

We have:

T = 27 ?, R = 100 Ω, T1 = ?, R1 = 117 Ω, α = 1.70 *10-4 ° C-1

We know the relation of α can be given as

α = R1-RR(T1-T) = 117-100100(T1-27) = 1.70 *10-4

or ( T1 - 27) = 117-100100*1.70*10-4 = 1000

T1 = 1000 +27 = 1027 ?

New answer posted

a year ago

0 Follower 15 Views

P
Payal Gupta

Contributor-Level 10

3.4 (a) Let R1 = 2 Ω, R2 = 4 Ω, R3 = 5 Ω

If the equivalent resistance is R, then 1R = 1R1 + 1R2 + 1R3 = 12 + 14 + 15 = 10+5+420 = 1920

R = 2019 = 1.05 Ω

(b) The EMF of the battery = 20 V

Current through R1, I1 = VR1, = 202 = 10 A

Current through R2, I2 = VR2, = 204 = 5A

Current through R3, I3 = VR3, = 205 = 4 A

Total current I = I1 + I2 + I3 = 10 + 5 + 4 = 19 A

New answer posted

a year ago

0 Follower 23 Views

P
Payal Gupta

Contributor-Level 10

3.3 (a) The equivalent resistance of the resistor in series is given by

R = 1 + 2 + 3 = 6 Ω

(b) From Ohm's law, I = VR we get I = 126 = 2 A.

Potential drop across 1 Ω resistor = I *R = 2 *1 = 2 V

Potential drop across 2 Ω resistor = I *R = 2 *2 = 4 V

Potential drop across 3 Ω resistor = I *R = 2 *3 = 6 V

New answer posted

a year ago

0 Follower 4 Views

P
Payal Gupta

Contributor-Level 10

3.2 EMF of the battery = 10 V

Internal resistance of the battery, r = 3 Ω

Current in the circuit, I = 0.5 A

Let the resistance of the resistor be R

According to Ohm's law

I = E (R+r)

R + r = EI or R = EI - r = 100.5 - 3 = 17 Ω

Terminal voltage of the battery when the circuit is closed is given by

V = IR = 0.5 *17=8.5V

Therefore the resistance is 17 Ω and the terminal voltage is 8.5 V

New answer posted

a year ago

0 Follower 13 Views

P
Payal Gupta

Contributor-Level 10

3.1 EMF of the battery, E = 12 V

Internal resistance of the battery, r = 0.4 Ω

Let the maximum current drawn = I

According to OHM's law, E = Ir

So I = Er = 120.4 amp = 30 amp

Therefore, the maximum current can be drawn is 30 ampere.

New answer posted

a year ago

0 Follower 4 Views

V
Vishal Baghel

Contributor-Level 10

Volume of the balloon, V = 1425 ρHe

Mass of the payload, m = 400 kg

Acceleration due to gravity, g = 9.8 m/ m3

s2 = 8000 m

yo = 0.18 kg m–3

ρHe = 1.25 kg m–3

Density of the balloon = ρo

Height to which the balloon will rise = y

Density of air decreases with height and the relationship is given by:

ρ = ρ=ρoe-yyo ……(i)

Differentiating equation (i), we get

ρρo e-yyo

-dρdy , where k is the constant of proportionality

αρ , height changes from 0 to y, while density changes from dρdy=-kρ to dρρ=-kdy . Integrating both sides between the limits, we get:

ρo

ρ = -ky

ρoρdρρ=-0ykdy = loge?ρρoρ ….(ii)

From equation (i) and (ii), we get

ρρo =&nbs

...more

New answer posted

a year ago

0 Follower 4 Views

V
Vishal Baghel

Contributor-Level 10

Diameter of the 1st bore, d1 = 3 mm = 3 *10-3 m

Radius of the first bore, r1 = 1.5 mm = 1.5 *10-3 m

Diameter of the 2nd bore, d2 = 6 mm = 6 *10-3 m

Radius of the 2nd bore, r2 = 3.0 mm = 3 *10-3 m

Surface tension of water, s= 7.3 *10-2 N/m

Angle of contact between the bore surface and water, θ=0

Density of water, ρ=1.0*103 kg/ m3

Acceleration due to gravity. g = 9.8 m/ s2

Let h1 and h2 be the heights to which water rises in 1st and 2nd tubes respectively. These heights are given by the relations:

h1=(2scos?θ)/ρgr1 …(i)

h2=(2scos?θ)/ρgr2 …(ii)

The difference in level of water in the 2 li

...more

New answer posted

a year ago

0 Follower 4 Views

V
Vishal Baghel

Contributor-Level 10

Radius of the narrow tube, r = 1 mm= 1 *10-3 m

Surface tension of mercury at the given temperature, s= 0.465 N/m

Density of mercury ρ=13.6*103 kg/ m3

Dipping depth = h

Acceleration due to gravity, g = 9.8 m/ s2

Surface tension related with angle of contact and dipping depth is given by:

s = hρgr2cos? θ or h = 2scos? θρgr = 2*0.465*cos? 140°13.6*103*9.8*1*10-3 = -5.345 *10-3 m= -5.345 mm

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