Lattice energy for LiF(s) = -1047 kJ/mol Enthalpy of hydration for Li+(g) = -536 kJ/mol Enthalpy...

Given the following information: Li(s) → Li(g) enthalpy of sublimation of Li(s) = 166 kJ/mol HF(g)...

Given the following information: Li(s) → Li(g) enthalpy of sublimation of Li(s) = 166 kJ/mol HF(g) → H(g) + F(g) bond energy of HF = 565 kJ/mol Li(g) → Li+(g) + e– ionization energy of Li(g) = 520. kJ/mol F(g) + e– → F–(g) electron affinity of F(g) = -328 kJ/mol Li+(g) + F–(g) → LiF(s) lattice energy of LiF(s) = -1047 kJ/mol H2(g) → 2H(g) bond energy of H2 = 432 kJ/mol Calculate the change in enthalpy for: 2Li(s)...

te the lattice energy for LiF(s) given the following: sublimation energy for Li(s) +166 kJ/mol ∆Hf...

te the lattice energy for LiF(s) given the following: sublimation energy for Li(s) +166 kJ/mol ∆Hf for F(g) +77 kJ/mol first ionization energy of Li(g) +520. kJ/mol electron affinity of F(g) –328 kJ/mol enthalpy of formation of LiF(s) –617 kJ/mol A. none of these B. –650. kJ/mol C. 285 kJ/mol D. 800. kJ/mol E. 1052 kJ/mol

Calculate the lattice energy for NaF (s) given the following sublimation of energy +109 kj/mol Hf...

Calculate the lattice energy for NaF (s) given the following sublimation of energy +109 kj/mol Hf for F (g) + 77 kj/mol first ionization energy of Na (g) +495 electron affinity of F(g) -328 enthalpy of formation of NaF(s) -570 kj/mol A. -177 B. 192 C. -804 D. -1047 E. -923

Potassium perchlorate (KClO4) has a lattice energy of -599 kJ/mol and a heat of hydration of...

Potassium perchlorate (KClO4) has a lattice energy of -599 kJ/mol and a heat of hydration of -548 kJ/mol. A) Find the heat of solution for potassium perchlorate when 10.2 g of potassium perchlorate is dissolved with enough water to make 118.5 mLof solution.

Sodium hydroxide (NaOH) has a lattice energy of -887 kJ/mol and a heat of hydration of...

Sodium hydroxide (NaOH) has a lattice energy of -887 kJ/mol and a heat of hydration of -932 kJ/mol. How much solution could be heated to boiling by the heat evolved by the dissolution of 28.0 g of NaOH? (For the solution, assume a heat capacity of 4.0 J/g⋅∘C, an initial temperature of 25.0 ∘C, a boiling point of 100.0 ∘C, and a density of 1.05 g/mL.)

Sodium nitrate has a lattice energy of -2.48 x 10^2 kJ/mol, and a heat of hydration...

Sodium nitrate has a lattice energy of -2.48 x 10^2 kJ/mol, and a heat of hydration of -234 kJ/mol. Determine how much heat is evolved or absorbed when 16.5 g of sodium nitrate completely dissolves in water?

Using the thermochemical data and an estimated value of -2235.2 kJ/mol for the lattice energy for...

Using the thermochemical data and an estimated value of -2235.2 kJ/mol for the lattice energy for potassium oxide, calculate the value for the second electron affinity of oxygen [O− + e- → O2−]. (The answer is 748.5 kJ/mol) Quantity Numerical Value (kJ/mol) Enthalpy of atomization of K 89 Ionization energy of K 418.8 Enthalpy of formation of solid K2O -363 Enthalpy of formation of O(g) from O2(g) 249.1 First electron attachment enthalpy of O   -141.0

C2N2O2Hg(s) + O2 (g) -> Hg(g) + 2CO2(g) + N2(g) Determine the theoretical enthalpy (in kJ/mol)...

C2N2O2Hg(s) + O2 (g) -> Hg(g) + 2CO2(g) + N2(g) Determine the theoretical enthalpy (in kJ/mol) of the mercury fulminate reaction by using the enthalpy of formation for mercury fulminate (+ 386 kJ/mol) Remember, ΔH° rxn = Σn x H°f(products) - Σn x ΔH°f(reactants). Explain your work. We are assuming a constant pressure situation. This is can also be termed the heat of explosion, but when it is termed heat of explosion, the units are traditionally kJ/kg of substance. Convert...

The lattice enthalpy (formation of ionic solid from ions in the gas phase) for AgCl(s) is...

The lattice enthalpy (formation of ionic solid from ions in the gas phase) for AgCl(s) is -916 kJ/mol and the hydration enthalpy (dissolution of gaseous ions into water) is - 850 kJ/mol. How much heat (in Joules) is involved in forming 1L of saturated AgCl solution (1.8 × 10-4 g / 100 mL water) by dissolving AgCl(s)? Assume solution volume does not change much upon dissolution. The equations are given below. Ag+ (g) + Cl− (g) Æ AgCl(s) Ag+ (g)...

Use the Born Haber cycle (show relevant steps) to determine the lattice energy of CsCl (s)...

Use the Born Haber cycle (show relevant steps) to determine the lattice energy of CsCl (s) from the following data: Hf 0 [CsCl(s)] = -442.8 kJ/mol; enthalpy of sublimation of Cesium is 78.2 kJ/mol; enthalpy of dissociation of Cl2 (g) = 243 kJ/mol Cl2 ; IE1 for Cs(g) = 375.7 kJ/mol; electron affinity enthalpy-EA1 for Cl(g) = -349kJ/mol. - need answer fast - thanks