C---An important step in the synthesis of nitric acid is the reaction of ammonia (NH3) and molecular oxygen to form nitrogen monoxide gas and water vapor.

--Write a balanced equation for this reaction. (2 points)

--Calculate DHo for this reaction, using standard heat of formation values from Appendix G in the Open Stax Chemistry text. (3 points)

D----When an electron in a 2p orbital of a particular atom makes a transition to the 2s orbital, a photon of approximate wavelength 629.1 nm is emitted. What is the energy difference between these 2p and 2s orbitals?

E---Provide a numerical value (whole number) for each of the following questions. Briefly explain your reasoning (1 point each).

How many electrons can be contained in all of the orbitals withn = 4?

Among the orbitals with n = 4 (see part a), which one has the highest energy and how do you know this?

What is the l quantum number for a 4s orbital?

How many electrons can be described by the quantum numbersn = 3, l = 3, ml = 1?

l = 3, how many electrons can be contained in all the possible orbitals of a given principal quantum number?

A--Galena (also known as lead (II) sulfide) is the ore from which elemental lead is extracted. In the first step of the extraction process, galena is heated in oxygen to form lead (II) oxide and sulfur dioxide.

--Write a balanced equation for the reaction. (2 points)
--What mass of galena is converted to lead (II) oxide if 975 kJ of heat is produced? (3 points)

B--Tungsten(VI) oxide reacts with hydrogen gas (H₂) to produce tungsten metal and water vapor. The equations below represent the enthalpy change for the formation of the two compounds from their elements.

2 W (s) + 3 O₂ (g) ---> 2 WO₃ (s) ΔH = -1685.4 kJ

2 H₂ (g) + O₂ (g)---> 2 H₂O (g) ΔH = -477.84 kJ

--Write a balanced equation for the reaction. (1 point)

--What is the enthalpy change for the overall reaction written in (a)? (4 points)

C---An important step in the synthesis of nitric acid is the reaction of ammonia (NH₃) and molecular oxygen to form nitrogen monoxide gas and water vapor.

--Write a balanced equation for this reaction. (2 points)

--Calculate DH^o for this reaction, using standard heat of formation values from Appendix G in the Open Stax Chemistry text. (3 points)

D----When an electron in a 2p orbital of a particular atom makes a transition to the 2s orbital, a photon of approximate wavelength 629.1 nm is emitted. What is the energy difference between these 2p and 2s orbitals?

E---Provide a numerical value (whole number) for each of the following questions. Briefly explain your reasoning (1 point each).

How many electrons can be contained in all of the orbitals with n = 4?

Among the orbitals with n = 4 (see part a), which one has the highest energy and how do you know this?

What is the l quantum number for a 4s orbital?

How many electrons can be described by the quantum numbers n = 3, l = 3, m_l = 1?

l = 3, how many electrons can be contained in all the possible orbitals of a given principal quantum number?

(a) Using only the valence atomic orbitals of a hydrogen atom and a fluorine atom, and following the model of Figure 9.46, how many MOs would you expect for the HF molecule? (b) How many of the MOs from part (a) would be occupied by electrons? (c) It turns out that the difference in energies between the valence atomic orbitals of H and F are sufficiently different that we can neglect the interaction of the 1s orbital of hydrogen with the 2s orbital of fluorine. The 1s orbital of hydrogen will mix only with one 2p orbital of fluorine. Draw pictures showing the proper orientation of all three 2p orbitals on F interacting with a 1s orbital on H. Which of the 2p orbitals can actually make a bond with a 1s orbital, assuming that the atoms lie on the z-axis? (d) In the most accepted picture of HF, all the other atomic orbitals on fluorine move over at the same energy into the molecular orbital energy-level diagram for HF. These are called “nonbonding orbitals.” Sketch the energy-level diagram for HF using this information and calculate the bond order. (Nonbonding electrons do not contribute to bond order.) (e) Look at the Lewis structure for HF. Where are the nonbonding electrons?

This question is about relationships between the 1s, 2s and 2px orbitals.