Part 2\ All conditions are the same as for Part 1, except that the membrane is freely permeable to

Cl^(-)

and impermeable to

K^(+)

.\ (4pt) Write in the appropriate quantities of

K^(+)

and

Cl^(-)

in the Figure below.\ (1pt) What is the direction of the Chemical driving force for

K^(+)

: From solution to solution\ (1pt) What is the direction of the Chemical driving force for

Cl^(-)

: From solution to solution\ (1pt) Which ion(s) can actual diffuse down their chemical driving force?\ (1pt) Draw an arrow on the figure indicating the flow of that ion.\ (2pt) Due to the movement of the ion and the selectively permeable membrane, is there an electrical disequilibrium? If so write on the figure write in which side of the membrane becomes negatively charged and which becomes positively charged.\ Given this electrical disequilibrium,\ (1pt) What is the direction of the Electrical driving force for

K^(+)

: From solution to solution\ (1pt) What is the direction of the Electrical driving force for

Cl^(-)

: From solution to solution

Part 2 All conditions are the same as for Part 1, except that the membrane is freely permeable to Cland impermeable to K+. (4pt) Write in the appropriate quantities of K+and Clin the Figure below. (1pt) What is the direction of the Chemical driving force for K+: From solution to solution (1pt) What is the direction of the Chemical driving force for Cl: From solution to solution (1pt) Which ion(s) can actual diffuse down their chemical driving force? (1pt) Draw an arrow on the figure indicating the flow of that ion. (2pt) Due to the movement of the ion and the selectively permeable membrane, is there an electrical disequilibrium? If so write on the figure write in which side of the membrane becomes negatively charged and which becomes positively charged. Given this electrical disequilibrium, (1pt) What is the direction of the Electrical driving force for K+: From solution to solution 1pt) What is the direction of the Electrical driving force for Cl: From solution to solution