In lungs, definite ions are exchanged between RBC and blood plasma. It shows release of `CO_(2)` from blood.
(A) External transport of `Cl^(-)` in RBC
(B) Internal transport of `Cl^(-)` in RBC
(C) Internal transport of `HCO_(3)^(-)` in RBC
(D) External transport of `HCO_(3)^(-)` in RBC

Which structure of the lungs is directly involved in O_(2)//CO_(2) exchange between air and blood capillary? (A) Bronchi (B) Trachea (C) Alveoli (D) Secondary bronchi

Mark the odd one in each series: (a) Areolar tissue, blood, neuron, tendon (b) RBC, WBC, platelets, cartilage (c) Exocrine, endocrine, salivary gland, ligament (d) Maxilla, mandible, labrum, antennae (e) Protonema, mesothorax, metathorax, coxa

Separation of Motion of a system of particles into motion of the centre of mass and motion about the centre of mass : (a) Show p=p_(i).+m_(i)V where p_(i) is the momentum of the ith particle (of mass m_(i) ) and p_(i).=m_(i)v_(i). . Note v_(i). is the velocity of the i^(th) particle relative to the centre of mass Also, prove using the definition of the centre of mass Sigmap_(i).=0 (b) Show K=K.+(1)/(2)MV^(2) where K is the total kinetic energy of the system of particles, K. is the total kinetic energy of the system when the particle velocities are taken with respect to the centre of mass and (1)/(2)MV^(2) is the kinetic energy of the translation of the system as a whole (i.e. of the centre of mass motion of the system). The result has been used in Sec. 7.14). (c ) Show vecL=vecL.+vecRxxvec(MV) where vecL.=Sigmavec(r_(i)).xxvec(p_(i)). is the angular momentum of the system about the centre of mass with velocities taken relative to the centre of mass. Remember vec(r._(i))=vec(r_(i))-vecR , rest of the notation is the velcities taken relative to the centre of mass. Remember vec(r._(i))=vec(r_(i))-vecR rest of the notation is the standard notation used in the chapter. Note vecL , and vec(MR)xxvecV can be said to be angular momenta, respectively, about and of the centre of mass of the system of particles. (d) Show vec(dL.)/(dt)=sumvec(r_(i).)xxvec(dp.)/(dt) Further, show that vec(dL.)/(dt)=tau._(ext) where tau._(ext) is the sum of all external torques acting on the system about the centre of mass. (Hint : Use the definition of centre of mass and Newton.s Thrid Law. Assume the internal forces between any two particles act along the line joining the particles.)

Figure shows a potentiometer with a cell of 2.0 V and internal resistance 0.40 Omega maintaining a potential drop across the resistor wire AB. A standard cell which maintains a constant emfof 1.02 V (for very moderate currents upto a few mA) gives a balance point at 67.3 cmlength of the wire. To ensure very low currents drawn from the standard cell, a very high resistance of 600 k Omega is put in series with it, which is shorted close to the balance point. The standard cell is then replaced bya cell of unknown emfe and the balance point found similarly, turns out to be at 82.3 cm length of the wire. (a) What is the value epsilon ? (b) What purpose does the high resistance of 600 K Omega have ? (c) Is the balance point affected by this high resistance ? (d) Would the method work in the above situation if the driver cell of the potentiometer had an emf of 1.0V instead of 2.0 V ? (e) Would the circuit work well for determining an extremely small emf, say of the order of a few mV (such as the typical emf of a thermocouple) ? If not, how will you modify the circuit ? (f) Can we use above circuit to measure very small emf of the order of mV. (For example, emf obtained in thermocouple) ? If not, then what change would you make ?

Assertion : "A": CO_(2) transport occurs very fast through R.B.Cs. Reason : "R": Enzyme Carbonic anhydrase is absent in blood plasma. Which of the following is true for the given assertion "A" and reason "R" ?

P ,Q have position vectors vec a& vec b relative to the origin ' O^(prime)&X , Ya n d vec P Q internally and externally respectgively in the ratio 2:1 Vector vec X Y= 3/2( vec b- vec a) b. 4/3( vec a- vec b) c. 5/6( vec b- vec a) d. 4/3( vec b- vec a)