Complete this table relating the values of Ecell and ΔG to the Q/K ratio Q/K Ecell...

Consider the formation of [Ni(en)3]2+ from [Ni(H2O)6]2+. The stepwise ΔG∘ values at 298 K are ΔG∘1...

Consider the formation of [Ni(en)3]2+ from [Ni(H2O)6]2+. The stepwise ΔG∘ values at 298 K are ΔG∘1 for first step=−42.9 kJ⋅mol−1 ΔG∘2 for second step=−35.8 kJ⋅mol−1 ΔG∘3 for third step=−24.3 kJ⋅mol−1 Calculate the overall formation constant (Kf) for the complex [Ni(en)3]2+.

Select the true statement below.    when Q < K, the system can release no more...

Select the true statement below.    when Q < K, the system can release no more free energy     when ΔG > 0, the system can release free energy when ΔG < 0, the system can release free energy until Q = K when ΔG > 0, ΔG is the maximum useful work obtainable from the system    when ΔG = 0, ΔG° must also = 0

Using the table of standard entropies and enthalpies of formation, calculate ΔH°, ΔS°, and ΔG° for...

Using the table of standard entropies and enthalpies of formation, calculate ΔH°, ΔS°, and ΔG° for the following reactions at 298.15 K. (Use only the table of standard entropies and standard enthalpies of formation, not the table of standard Gibbs free energies.) Compound ΔHof (kJmol)ΔHfo (kJmol) ΔSof (Jmol⋅K)ΔSfo (Jmol⋅K) The equation SiO2(s) + 2 Mg(s) → Si(s) + 2 MgO(s) ΔHoΔHo  kJ ΔSoΔSo  J/K ΔGoΔGo  kJ C(s) 0 5.7 CO(g) -110.5 197.7 CO2(g) -393.5 213.8 Cl2(g) 0 223.1 H2(g) 0 130.7 HCl(g) -92.3...

Q3: Complete the following table. Hint: Start with the first row. Q (units) TFC ($) TVC...

Q3: Complete the following table. Hint: Start with the first row. Q (units) TFC ($) TVC ($) TC ($) AFC ($/unit) AVC ($/unit) ATC ($/unit) MC ($/unit) 0 $1,800 – – – – 1 $600 2 $400 3 $1,200 4 $2,800

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....

Complete the following table accurately. [5 Marks]      Draw the TC, MR, MC in one graph Q...

Complete the following table accurately. [5 Marks]      Draw the TC, MR, MC in one graph Q TFC TVC TC P=MR TR MC Profit 0 $10 0 $15 1 10 2 15 3 20 4 30 5 50 6 80

Complete the following table assuming that each unit of labour costs $65 L Q AP MP...

Complete the following table assuming that each unit of labour costs $65 L Q AP MP TFC$ TVC$ TC$ AC$ MC$ 0 - 400 1 6 65 2 9 3 16 4 19 5 20

Perfect competition in Q and L(Short Run), if P=200, Q=2L^(0.5)k^(0.25), w=10, r=10; Find values of Q,L...

Perfect competition in Q and L(Short Run), if P=200, Q=2L^(0.5)k^(0.25), w=10, r=10; Find values of Q,L and K.

± Free Energy and Chemical Equilibrium The equilibrium constant of a system, K, can be related...

± Free Energy and Chemical Equilibrium 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 standard temperature in kelvins 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...