A uniform meter scale is in equilibrium as shown in the diagram :

Which of the following options is correct to keep the ruler in equilibrium when 40 gf wt is shifted to 0 cm mark? F is shifted towards 0 cm. Or F is shifted towards 100 cm.

A uniform meter scale is in equilibrium as shown in the diagram : Calculate the weight of the meter scale. (ii) Which of the following options is correct to keep the ruler in equilibrium when 40 gf wt is shifted to 0 cm mark? F is shifted towards 0 cm. Or F is shifted towards 100 cm.

A uniform meter scale is kept in equilibrium when supported at the 60 cm mark and a mass weight of the scale is greater than, less than or equal to the weight of mass M.

In which of the following reactions equilibrium will shift towards right?

Out of the following one which is correct for equilibrium state ? (a) Delta G=0 (b) Delta S=0 (c ) r_(f)=r_(b) (d) E_(cell)=0

A uniform thermometre scale is at steady state with its 0 cm mark at 20°C and 100 cm mark at 100°C . Temperature of the 60 cm mark is-

A uniform metre scale can be balanced at the 70.0 cm mark when a mass of 0.05 kg is hung from the 94.0 cm mark. Draw a diagram of the arrangement.

A uniform metre scale can be balanced at the 70.0 cm mark when a mass of 0.05 kg is hung from the 94.0 cm mark. Find the mass of the metre scale.

Fig.1.33 shows a uniform metre rule placed on a fulcrum at its mid point O and having a weight 40gf at the 10cm mark and a weight of 20gf at the 90cm mark. (i) Is the metre rule in equilibrium? If not , how will the turn? (ii) How can the rule be brought in equilibrium by using an additional weight of 40 gf?

A uniform metre rule rests horizontally on a knife edge at the 60cm mark when a mass of 10g is suspended from one end. Draw a diagram of the arrangement. (a) At which end must this mass be suspended (b) What is the mass of the rule? (c ) THe 10g mass is now shifted to the 90cm mark. In which direction must the knife edge be shifted to make the rule horizontal again?

A body of mass 200 g is in equibrium at x = 0 under the influence of a force F(x) = (- 100x + 10x^(2))N . (a) If the body is displacement a small distance from equilibrium, what is the period of its oscillations ? (b) If the amplitude is 4.0 cm , by how much do we eror in assuming that F(x) = - kx at the end points of the motion.