Milk turns sour at `40^(@)C` three times as faster as `0^(@)C`. Hence `E_(a)` in cal of process of turning of milk sour is `:`

In the start of summer, a given sample of milk turns sour at room temperature (27^(@)C) in 48 hours. In a refrigerator at 2^(@)C , milk can be stored there times longer before it sours. The activation energy of the souring of milk is (kJ mol^(-1))

In the start of summer, a given sample of milk turns sour at room temperature (27^(@)C) in 48 hours. In a refrigerator at 2^(@)C , milk can be stored there times longer before it sours. Calculate the rate constant at 310 K , when rate constant at 300 K is 1.6 xx 10^(5)

In the start of summer, a given sample of milk turns sour at room temperature (27^(@)C) in 48 hours. In a refrigerator at 2^(@)C , milk can be stored there times longer before it sours. The time taken by the milk to sour at 37^(@)C Given: Activation energy:: 30146 J/mol (a) 35.2 hr (b) 32.5 hr (c) 35.3 hr (d) 32.3 hr

When m gram of steam at 100^(@) C is mixed with 200 gm of ice at 0^(@)C . it results in water at 40^(@) C . Find the value of m in gram . (given : Latent heat of fusion ( L_f ) = 80 cal/gm, Latent heat of vaporisation ( L_v ) = 540 cal/gm., specific heat of water ( C_w )= 1 cal/gm/C)

When milk is heated at 62^(@) C for 30 minutes and then cooled, the process is called

The freezing point of a diluted milk sample is found to be -0.2^(@)C , while it should have been -0.5^(@)C for pure milk. How much water has been added to pure milk to make the diluted sample?

When m gram of steam at 100^@ C is mixed with 200 gm of ice at 0^@ C. it results in water at 40^@ C . Find the value of m in gram . (given : Latent heat of fusion ( L_f ) = 80 cal/gm, Latent heat of vaporisation ( L_v ) = 540 cal/gm., specific heat of water ( C_w )= 1 cal/gm/C)

Imagine a system, that can keep the room temperature within a narrow range between 20^@C to 25^@C . The system includes a heat engine operating with variable power P = 3KT, where K is a constant coefficient, depending upon the thermal insulation of the room, the area of the walls and the thickness of the walls. T is temperature of the room in temperature drops lower than 20^@C , the engine turns on, when the temperature increase over 25^@ C, the engine turns off, room looses energy at a rate of K(T - T_0), T_0 is the outdoor temperature. The heat capacity of the room is C. Given (T_0=10^@C, ln(3/2) =0.4 , ln(6/5)=0.18 , C/K =750 SI-unit) Suppose at t = 0, the engine turns off, after how much time interval, again, the engine will turn on

Imagine a system, that can keep the room temperature within a narrow range between 20^@C to 25^@C . The system includes a heat engine operating with variable power P = 3KT, where K is a constant coefficient, depending upon the thermal insulation of the room, the area of the walls and the thickness of the walls. T is temperature of the room in temperature drops lower than 20^@C , the engine turns on, when the temperature increase over 25^@ C, the engine turns off, room looses energy at a rate of K(T - T_0), T_0 is the outdoor temperature. The heat capacity of the room is C. Given (T_0=10^@C, ln(3/2) =0.4 , ln(6/5)=0.18 , C/K =750 SI-unit) Suppose at t = 0, the engine turns on, after how much time interval again, the engine will turn off

When a white powder (A) is strongly heated, it gives of a colourless, odourless gas (B) which turns lime water milky (C) and if the passage of this gas is continued the milkiness disappears and gives a solution (D). The solid residue (E) is yellow when hot, but turns white on cooling. Idnetify (A) to (E) with help of the equations.