`S rarr G + F`
Time `" "t " "prop`
Rotation of Glucose & Fructose `r_(t)" " r_(prop)` Find k.

A : D-fructose is levorotatory R : D-Glucose is dextrorotatory

A spherical black body of radius r radiates power P , and its rate of cooling is R (i) P prop r (ii) P prop r^(2) (iii) R prop r^(2) (iv) R prop (1)/(r)

For planets revolving round the sun, show that T^(2) prop r^(3) , where T is the time period of revolution of the planet and r is its distance from the sun.

The inverison of a sugar follows first order rate equation which can be followed by noting the change in the rotation of the plane of polarization of light in the polarimeter. If r_(oo), r_(f) and r_(0) are the rotations at t = oo, t = t , and t = 0 , then the first order reaction can be written as

A body is moved along a straight line by a machine delivering a power proportional to time (P prop t) Then match the following : {:(,"Column-1",," Column-2"),("(A)","Velocity is proportional to",,"(P) t"),("(B)","Displacement proportional to",,(Q) t^(2)),("(C)","Work done proportional to",,(R) t^(3)):}

The period of revolution (T) of a planet around the sun depends upon (i) radius (r ) of obit (ii) mass M of the sun and (iii) gravi-tational constant G. Prove that T^2 prop r^3