Question 10 1.5 pts Given that a chlorine-oxygen bond has an enthalpy of 243 kJ/mol, an...
Part A. Given the bond dissociation energies (in kJ/mol) for the following diatomic molecules Cl2 (243), F2 (158), H2 (436), O2 (498), N2 (945) choose the one(s) that could be broken by using blue light (λ=465 nm). Part B. Given the bond energies (in kJ/mol) of the following bonds: F–F (155), F–Cl (193), and Cl–Cl (243), estimate the molar enthalpy of formation of ClF(g), that is find ∆H for the following reaction ½Cl2(g) + ½F2(g) → ClF(g)
The C1-C1 bond energy is 243 kJ/mol. Therefore the breaking of the bond between chlorine atoms should require the absorption of 243 kJ per mote of Cl_2 formed. should require the absorption of486 kJ per mole of Cl_2 formed should result in the release of 243 kJ per mole of Cl_2 formed. should result in the release of 486 Id per mole of Cl_2 form A reactive element with a relatively high electronegativity would be expected to have a relatively...
For the reaction: H2(g)+C2H4(g)-->C2H6(g) Bond & Bond Enthalpy H-H 436.4 kJ/mole C-H 414 kJ/mol C-C 347 kJ/mol C=C 620 kJ/mol Substance & delta Hf H2 0 C2H4 52.3 C2H6 -84.7 (a) estimate the enthalpy of reaction, using the bond enthalpy values from the table in kJ/mol (b) Calculate the enthalpy of reaction, using standard enthalpies of formation
physical chemistry 2. The bond dissociation energy of oxygen gas is 495 kJ/mole, while the enthalpy of formation of ozone gas (O3(g))is 142.3 kJ/mole. For the reaction: NO +O3(g) NO2(g) + O2(g) it is found that AH = -198.9 kJ/mole, Determine the enthalpy change for the reaction: NO(g) + O() NO2(8)
Given the bond energies (in kJ/mol) of the following bonds: F–F (155), F–Cl (193), and Cl–Cl (243), estimate the molar enthalpy of formation of ClF(g), that is find ∆H for the following reaction ½Cl2(g) + ½F2(g) → ClF(g) A. 209 kJ/mol B. -50. kJ/mol C. –8 kJ/mol D. –209 kJ/mol E. 8 kJ/mol
Question 6 0.5 pts The table below contains the bond dissociation energies for common bonds. 410 Dissociation energy Bond (kJ/mol) |C-c 350 CNC 611 C-H 350 (c=0 799 0-0 180 O=O 498 460 C-O H-o Calculate the bond dissociation energy required for breaking all the bonds in a mole of water molecules, H20. Express your answer numerically, in terms of kJ/mol, and to three significant figures.
Question 3 1 pts Given the bond dissociation energies (in kJ/mol) for the following diatomic molecules Cl2 (243), F2 (158), H2 (436), O2 (498), N2 (945) choose the one(s) that could be broken by using blue light (=465 nm). F2 and Cl2 o F2 F2, C12, H2, O2 and N2 F2, Cl2 and H2 F2, Cl2, H2 and 02
Generally enthalpy values are given in kJ/mol. However, convert the enthalpy of neutralization value of -110.83 kJ/molNaOH to BTU/gram NaOH. BTU stands for British thermal unit. (Put your answer in 3 significant figures) Given the following information below, use Hess’s Law to calculate the enthalpy of formation for sodium oxide: Na (s) + HCl (l) à NaCl (aq) + ½ H2 (g) ∆HRx = -397.9 kJ/mol Na2O (s) + 2 HCl (l) à 2 NaCl (aq) + H2O ∆HRx = -652.8 kJ/mol H2 (g) + ½ O2 (g) à ...
The table below lists the average bond energies that you would need to determine reaction enthalpies. Use bond energies to calculate the enthalpy of combustion of one mole of methanol in kJ per mole methanol. Express your answer numerically, in terms of kJ/mol methanol and to three significant figures.
3. (14 pts.) The standard molar enthalpy of formation of Fe,Oxs is AH = -8242 kJ/mol, and the standard molar enthalpy of formation of SO2(g) is AH = -296.8 kJ/mol (both at 298 K). Use this information, along with the standard molar enthalpy change of the following reaction at 298K, 2 FeS21s) + 11/2O2(g) → Fe2O3 + 4 SO2(g) AH = -1655 kJ/mol To determine the standard molar enthalpy change of the reaction shown below are 298 K: Fe(s) +...