The room temperature charges by a small amount from `T` to `T+DeltaT` (on Kelvin scale). The fundamental frequency of organ pipe changes from `f` to `f+Deltaf`, then

A body cools- from a temperature 3T to 2T in 10 minutes.The room temperature is T. Assume that Newton’s law of cooling is applicable . The temperature of the body at the end of next 10 minutes.

With the increase in temperature , the frequency of the found from an organ pipe

A uniform rod of mass m and length l is struck at an end by a force F perpendicular to the rod for a short time interval t. Calculate a. the speed of the centre of mass ,b. the angular speed of the rod about centre of mass, c. the kinetic energy of the rod and d. the angular moment of the rod about the centre of mass after the force has stopped to act. Assume that t is so small that the rod does not apreciably change its direction while the force acts.

Assertion : Beating a person with a scale or stick is an example for how momentum is converted into force. Reason : If 'm' is the mass of the scale 'v' is the velocity of the scale (movement), this 'mv' changes, from the initial point to the final point (i.e. hand or body) with respect to time As we know (mv)/(t)=ma((V)/(t))=ma=F This is how momentum is converted into force.

A rod of mass m and length L , lying horizontally is free to rotate about a vertical axis through its centre. A horizontal force of constant magnitude F acts on the rod at a distance of L/4 from the centre. The force is always perpendicular to the rod. Find the angle rotated by the rod during the time t after the motion starts.

Consider a tank which initially holds V_(0) liter of brine that contains a lb of salt. Another brine solution, containing b lb of salt per liter is poured into the tank at the rate of eL//"min" . The problem is to find the amount of salt in the tank at any time t. Let Q denote the amount of salt in the tank at any time. The time rate of change of Q, (dQ)/(dt) , equals the rate at which salt enters the tank at the rate at which salt leaves the tank. Salt enters the tank at the rate of be lb/min. To determine the rate at which salt leaves the tank, we first calculate the volume of brine in the tank at any time t, which is the initial volume V_(0) plus the volume of brine added et minus the volume of brine removed ft. Thus, the volume of brine at any time is V_(0)+et-ft The concentration of salt in the tank at any time is Q//(V_(0)+et-ft) , from which it follows that salt leaves the tank at the rate of f(Q/(V_(0)+et-ft)) lb/min. Thus, (dQ)/(dt)=be-f(Q/(V_(0)+et-ft))Q=be A tank initially holds 100 L of a brine solution containing 20 lb of salt. At t=0, fresh water is poured into the tank at the rate of 5 L/min, while the well-stirred mixture leaves the tank at the same rate. Then the amount of salt in the tank after 20 min.

The amount of heat energy required to raise the temperature of 1g of helium at NTP, from T_1K to T_2K is

A thermometer was taken from a freezer and placed in a boilling water . It took 22 seconds for the thermometer to raise from -10^(@)C to 100 ^(@)C . Show that the rate of changes of temperature at some time t is 5 ^(@) C per second