Uncategorised (JEE Advanced Physics by BM Sharma + GMP Solutions)
A tall vertical cylinder of height and cross-sectional area A is in uniform gravitational field. The cylinder contains an ideal gas at uniform temperature and is closed at both ends. If density of gas at bottom and and top of the
02
Sep
A tall vertical cylinder of height and cross-sectional area A is in uniform gravitational field. The cylinder contains an ideal gas at uniform temperature and is closed at both ends. If density of gas at bottom and and top of the a molecule at the surface of the earth can escape the Eartsh's gravitation which [...]
Figure shows a network of currents. The magnitude of the current is shown here. find the current i.
02
Sep
Figure shows a network of currents. The magnitude of the current is shown here. find the current i. Figure shows a network of currents. The magnitude of the current is shown here. find the current i. September 2, 2020 Category: Uncategorised (JEE Advanced Physics by BM Sharma + GMP Solutions) ,
An ideal gas of molar mass M is filled in a horizontal cylinder closed at one end. The cylinder rotates with a constant angular velocity w about a vertical axis passing through the open end of the cylinder. The pressure at the axis of the cylinder is
02
Sep
An ideal gas of molar mass M is filled in a horizontal cylinder closed at one end. The cylinder rotates with a constant angular velocity w about a vertical axis passing through the open end of the cylinder. The pressure at the axis of the cylinder is a molecule at the surface of the earth [...]
If it has enough kinetic energy, a molecule at the surface of the earth can escape the Earth’s gravitation which means that it can continue to move away from the Earth forever. Using the principle of conservation of energy, show that the minimum kinetic energy needed to-duplicate-1
02
Sep
If it has enough kinetic energy, a molecule at the surface of the earth can escape the Earth’s gravitation which means that it can continue to move away from the Earth forever. Using the principle of conservation of energy, show that the minimum kinetic energy needed to-duplicate-1 a molecule at the surface of the earth [...]
In the given circuits, fig. (a) and (b) , calculate the resistance between points A and B.
02
Sep
In the given circuits, fig. (a) and (b) , calculate the resistance between points A and B. calculate the resistance between points A and B. fig. (a) and (b) In the given circuits September 2, 2020 Category: Uncategorised (JEE Advanced Physics by BM Sharma + GMP Solutions) ,
If it has enough kinetic energy, a molecule at the surface of the earth can escape the Eartsh’s gravitation which means that it can continue to move away from the Earth forever. Using the principle of conservation of energy, show that the minimum kinetic energy needed to
02
Sep
If it has enough kinetic energy, a molecule at the surface of the earth can escape the Eartsh’s gravitation which means that it can continue to move away from the Earth forever. Using the principle of conservation of energy, show that the minimum kinetic energy needed to a molecule at the surface of the earth [...]
Nine wires each of resistance are connected to make a prism as shown in figure. Find the equivalent resistance of the arrangement across a). AD b). AB
02
Sep
Nine wires each of resistance are connected to make a prism as shown in figure. Find the equivalent resistance of the arrangement across a). AD b). AB Nine wires each of resistance are connected to make a prism as shown in figure. Find the equivalent resistance of the arrangement across a). AD b). AB September [...]
Consider a rectangular block of wood moving with a velocity v0 in a gas at temperature T and mass density ρ. Assume the velocity is along x-axis and the area of cross-section of the block perpendicular to v0 is A.
02
Sep
Consider a rectangular block of wood moving with a velocity v0 in a gas at temperature T and mass density ρ. Assume the velocity is along x-axis and the area of cross-section of the block perpendicular to v0 is A. flying at random within this space with no way of knowing where the other planes [...]
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flying at random within this space with no way of knowing where the other planes are ,
On the average about how long a time will elapse between near collision with your ,
Ten small planes are flying at a speed of 150km/h in total darkness in an air space that is 20×20×1.5km^3 in volume. You are in one of the planes ,
In Fig., the resistances are connected as shown. Given R1= 10Ω R2= 20Ω. Determine the equivalent resistance between points (i) A and D and (ii) B and C
02
Sep
In Fig., the resistances are connected as shown. Given R1= 10Ω R2= 20Ω. Determine the equivalent resistance between points (i) A and D and (ii) B and C In Fig. the resistances are connected as shown. Given R1= 10Ω R2= 20Ω. Determine the equivalent resistance between points (i) A and D and (ii) B and [...]
Ten small planes are flying at a speed of 150km/h in total darkness in an air space that is 20×20×1.5km^3 in volume. You are in one of the planes, flying at random within this space with no way of knowing where the other planes are, On the average about how long a time will elapse between near collision with your
02
Sep
Ten small planes are flying at a speed of 150km/h in total darkness in an air space that is 20×20×1.5km^3 in volume. You are in one of the planes, flying at random within this space with no way of knowing where the other planes are, On the average about how long a time will elapse [...]
Tags:
flying at random within this space with no way of knowing where the other planes are ,
On the average about how long a time will elapse between near collision with your ,
Ten small planes are flying at a speed of 150km/h in total darkness in an air space that is 20×20×1.5km^3 in volume. You are in one of the planes ,