What is the free change energy for molecule B at 306 K if the concentration of...

The standard free energy change for ATP hydrolysis is -30.5 kJ/mol. Therefore, the free energy change...

The standard free energy change for ATP hydrolysis is -30.5 kJ/mol. Therefore, the free energy change for this reaction in a cell in which the concentration of ATP, ADP, and Pi are 3.1 mM, 2.2 mM and 6.8 mM, respectively, and assuming a physiologically relevant temperature (37 °C), is: Answer -44.25 kJ/mol explain

The standard free energy for the reaction A ---> B is -4.00 kJ/mole. If the concentration...

The standard free energy for the reaction A ---> B is -4.00 kJ/mole. If the concentration of A known to be 4.00 mM at equilibrium at 25 oC. What would be equilibrium mM concentration of B. Provide answer to the nearest tenth mM.

What is the free energy change for the transport of calcium ions into a cell. The...

What is the free energy change for the transport of calcium ions into a cell. The intracellular [Ca2+] is 1 μM and extracellular [Ca2+] is 1 mM. Assume a membrane potential of -100 mV and T=25°C. Give your answer in kJ/mol to one decimal place.

Diamond a. At 298 K, what is the Gibbs free energy change G for the following...

Diamond a. At 298 K, what is the Gibbs free energy change G for the following reaction? Cgraphite ->  Cdiamond b. Is the diamond thermodynamically stable relative to graphite at 298 K? c. What is the change of Gibbs free energy of diamond when it is compressed isothermally from 1 atm to 1000 atm at 298 K? d. Assuming that graphite and diamond are incompressible, calculate the pressure at which the two exist in equilibrium at 298 K. e....

The standard free energy that is required for the sodium-potassium ATPase to pump two K+ ions...

The standard free energy that is required for the sodium-potassium ATPase to pump two K+ ions into the cell and three Na+ ions out is +43.8 kJ/mol but the standard free energy change of hydrolysis of ATP is only -32 kJ/mol. This apparent imbalance of free energy can be accounted for because: A) the movement of Na+ ions is down the concentration gradient . B) the movement of K+ ions is down the concentration gradient. C) the free energy provided...

The equilibrium constant of a system, K, can be related to the standard free energy change,...

The equilibrium constant of a system, K, can be related to the standard free energy change, ΔG∘, using the following equation: ΔG∘=−RTlnK where T is a specified temperature in kelvins (usually 298 K) and R is equal to 8.314 J/(K⋅mol). Under conditions other than standard state, the following equation applies: ΔG=ΔG∘+RTlnQ In this equation, Q is the reaction quotient and is defined the same manner as K except that the concentrations or pressures used are not necessarily the equilibrium values....

The equilibrium constant of a system, K, can be related to the standard free energy change,...

The equilibrium constant of a system, K, can be related to the standard free energy change, ΔG∘, using the following equation: ΔG∘=−RTlnK where T is a specified temperature in kelvins (usually 298 K) and R is equal to 8.314 J/(K⋅mol). Under conditions other than standard state, the following equation applies: ΔG=ΔG∘+RTlnQ In this equation, Q is the reaction quotient and is defined the same manner as K except that the concentrations or pressures used are not necessarily the equilibrium values....

1.      Calculate the standard free energy change at 500 K for the following reaction. Cu(s) +...

1.      Calculate the standard free energy change at 500 K for the following reaction. Cu(s) + H2O(g) à CuO(s) + H2(g) ΔH˚f (kJ/mol) S˚ (J/mol·K) Cu(s)    0    33.3    H2O(g)    -241.8    188.7    CuO(s)    -155.2    43.5    H2(g)     0    130.6 2.      When solid ammonium nitrate dissolves in water, the resulting solution becomes cold. Which is true and why? a.      ΔH˚ is positive and ΔS˚ is positive b.      ΔH˚ is positive and ΔS˚...

Calculate the standard molar Gibbs free energy change (DeltaGrxn0) at 298 K and at 400 K...

Calculate the standard molar Gibbs free energy change (DeltaGrxn0) at 298 K and at 400 K for the following reaction (the cyclotrimerization of ethene to benzene), assuming that all heat capacities are independent of temperature:                                     3 C2H4(g)   ®   C6H6(g) + 3 H2(g).

The concentration of K+ ions in the intracellular fluid of a nerve cell is approximately 361.669...

The concentration of K+ ions in the intracellular fluid of a nerve cell is approximately 361.669 mM, but in the extracellular fluid the K+ concentration is 20.15 mM. Given that the electric potential difference inside and outside the cell is given by φ (inside) - φ(outside) = –70.0 mV, calculate the Gibbs energy change (to the zeroth decimal place in Joules) for the transfer of 1.00 mol of K+ ion against the concentration gradient at 37.8oC.