Question

In: Chemistry

Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power...

Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light. The chemical reaction in the battery is: 1/2 N2 (g) + 3/2 H2 (g) → NH3 (g) a. What is the free-energy change for the reaction at 25o C, 1 bar? b. Calculate the free-energy change for the reaction at 50o C, 1 bar. State any assumptions made for this calculation. c. The limiting reactant in the battery is 100 g of H2. Calculate the maximum length of time (seconds) the light can operate at 25o C.

Solutions

Expert Solution

G = Gproducts - Greactants

G = fG (NH3) - 1/ 2 f G (N2) -3 /2 f G (H2)

= - 16.48 - 1/2 x 0 -3/2 x0

  = - 16.48 kJ / mol

free energy energy = - 16.48 kJ/mol

part B)

If we assume that the enthalpy and the entropy are both independent of temperature,

rG(323) = rG(298) - (323 - 298) rS

rS = S (NH3) - 1/ 2H2 - 3/2 S(N2)

= 192:45 - 1/ 2 x 191:61 - 3 /2 x 130:684

= 99:38 J mol-1 K-1

rG(323) = 16.45 -25 x (- 0:09938)

= -13.97 kJ

free energy = -13.97 kJ /mol

part C)

From the answer to part (a), the maximum amount of work that can be done by the battery is 16 450 J/ mol NH3. For 100 g of H2,

w = 16 450 J/mol NH3 x 2/ 3 mol NH3/ mol H2 x 1/ 2.016 mol H2/ g H2 x 100 g H2

= 544 000 J S

Since the batter is operating at 1 mwatt (or 103 J/sec), the battery can run for 5.44 x 10^8 s or 17 years!

5.44 X 10^8 seconds


Related Solutions

Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power...
Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light. The chemical reaction in the battery is: 1/2 N2 (g) + 3/2 H2 (g) → NH3 (g) a. What is the free-energy change for the reaction at 25o C, 1 bar? b. Calculate the free-energy change for the reaction at 50o C, 1 bar. State any assumptions made for this calculation. c. The limiting reactant in the battery is 100...
Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power...
Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light. The chemical reaction in the battery is: 1/2 N2 (g) + 3/2 H2 (g) → NH3 (g) a. What is the free-energy change for the reaction at 25o C, 1 bar? b. Calculate the free-energy change for the reaction at 50o C, 1 bar. State any assumptions made for this calculation. c. The limiting reactant in the battery is 100...
Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power...
Chapter 3, problem 21. An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light. The chemical reaction in the battery is: 1/2 N2 (g) + 3/2 H2 (g) → NH3 (g) a. What is the free-energy change for the reaction at 25o C, 1 bar? b. Calculate the free-energy change for the reaction at 50o C, 1 bar. State any assumptions made for this calculation. c. The limiting reactant in the battery is 100...
An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light....
An electrochemical battery is used to provide 1 milliwatt (mW) of power for a (small) light. The chemical reaction in the battery is: 1/2 N2 (g) + 3/2 H2 (g) → NH3 (g) a. What is the free-energy change for the reaction at 25o C, 1 bar? b. Calculate the free-energy change for the reaction at 50o C, 1 bar. State any assumptions made for this calculation. c. The limiting reactant in the battery is 100 g of H2. Calculate...
Electrochemical capacitor and battery are electrochemical energy storage system. The former has a very good power...
Electrochemical capacitor and battery are electrochemical energy storage system. The former has a very good power density (fast charging/discharging) but low energy density, while the latter has the opposite properties. Please design a device that can have good power density and energy density by combining the electrochemical capacitor and battery. Please provide an equivalent circuit (use -||- to represent capacitor and -©- to represent battery) to describe your design and how they work under charging/discharging conditions. You can use multiple...
1. The power of a signal is 50 mW and the power of the noise is...
1. The power of a signal is 50 mW and the power of the noise is 3 μW; what are the values of SNR and SNRdB? & 2. Distinguish between multilevel TDM, multiple-slot TDM, and pulse-stuffed TDM? (Min:100 Words)
A 1000 MW power plant of 35% thermal efficiency is proposed. The plant burns 3% sulphur...
A 1000 MW power plant of 35% thermal efficiency is proposed. The plant burns 3% sulphur coal with a heating value of 6000 Kcal/kg and emits 64000 m3/min of flue gas. What is the concentration of SO2 in the flue gas in ppm? Assume that the density of SO2 is 1920 g/m3.
3. The service life of a battery used in a cardiac pacemaker is assumed to be...
3. The service life of a battery used in a cardiac pacemaker is assumed to be normally distributed. A sample of twelve batteries is subjected to an accelerated life test by running them continuously at an elevated temperature until failure, and the following lifetimes (in hours) are obtained: 26.5, 24.8, 25.7, 24.4, 26.3, 25.6, 24.5, 26.1, 24.5, 24.9, 26.2, and 24.7. Test the hypothesis that the mean battery life exceeds 25 hours. a) State the null and alternative hypothesis. b)...
Hello, Could you please provide me with the FORMULAS used to solve problem 20.5 (chapter 20/Accounting...
Hello, Could you please provide me with the FORMULAS used to solve problem 20.5 (chapter 20/Accounting Information Systems). The solution you have is the correct solution, but I need the formulas used. The Question: Rossco is considering the purchase of a new computer with the following estimated costs: initial system design:$54,000, hardware:$74,000,software:$35,000,one-time initial training:$11,000, system installation:$20,000 and file conversion:$12,000. A net reduction of 3 employees is expected with average yearly salary of $40,000.The system will decrease average yearly inventory by...
3)When a power source like a battery is connected to a circuit, an electric field pushes...
3)When a power source like a battery is connected to a circuit, an electric field pushes electrons within the conducting wires causing them to flow. The electric field exists due to an uneven build up of charge on the surfaces of the wires (called a surface charge gradient). In this set of problems we will explore a simple model of how this all comes about and emphasize the connection between source charges, electric fields, and voltage differences in the context...
ADVERTISEMENT
ADVERTISEMENT
ADVERTISEMENT