a) calculate the coulumbian energy of the KBr molecule at equilibrium separation, R0 = 0.282 nm...

a) calculate the coulumbian energy of the KBr molecule at equilibrium separation, R0 = 0.282 nm
b) calculate the repulsion energy due to Pauli's Principle in R0
c) Determine the values ​​of A and n of the repulsive interaction model

The cesium iodide (CsI) molecule has an atomic separation of 0.127 nm. (a) Determine the energy...

The cesium iodide (CsI) molecule has an atomic separation of 0.127 nm. (a) Determine the energy of the first excited rotational state, with J = 1. (Anser in meV) (b) Find the frequency of the photon absorbed in the J = 0 to J = 1 transition. (Answer in GHz)

(a) Calculate the Coulomb electrostatic force and electrostatic energy between a Na+ ion and a Cl-...

(a) Calculate the Coulomb electrostatic force and electrostatic energy between a Na+ ion and a Cl- ion at a distance of 0.22 nm. Is this attractive or repulsive? The magnitude of the ionic charge of Na+ and Cl- ion is 1.6 x 10-19 C. (b) Calculate the Coulomb electrostatic energy between one casein submicelle and one Ca++ ion, assuming that the submicelle has negative charge - 1 x 10-17 C, and the separation between the centers of the submicelle and...

Equilibrium interionic spacing for X+ and Y- ions is 0.35 nm and also bond energy is...

Equilibrium interionic spacing for X+ and Y- ions is 0.35 nm and also bond energy is -6.13 eV. Find the attraction and repulsion energy. (n value is 10)

Q2. It is given that the net potential energy ?? of a system of two atoms...

Q2. It is given that the net potential energy ?? of a system of two atoms varies as a function of their separation distance r as follow: ?? = − A/ ? ? + ?/ ?? where − ?/ ? ? is the energy of attraction, and ?/ ?? is the energy of repulsion. (a) Show that at equilibrium the energy of attraction is ?/? times the energy of repulsion, and derive an expression to calculate the bond energy ??...

A proton and an electron are fixed in space with a separation of 837 nm. Calculate...

A proton and an electron are fixed in space with a separation of 837 nm. Calculate the electric potential at the midpoint between the two particles. potential: V Find the magnitude of the electric field at the same point. magnitude of field: N/C The direction of field is toward the proton. toward the electron. another direction. undetermined.

A proton and an electron are fixed in space with a separation of 947 nm. Calculate...

A proton and an electron are fixed in space with a separation of 947 nm. Calculate the electric potential at the midpoint between the two particles. Find the magnitude and direction of the electric field at the same point. Potential: _____V Magnitude of field: ______N/C Direction of field: (a) toward the proton (b) toward the electron (c) another direction (d) undetermined

HCl has a bond force constant of 480 N/m, oscillates at 8.66x10^13 Hz and an equilibrium...

HCl has a bond force constant of 480 N/m, oscillates at 8.66x10^13 Hz and an equilibrium bond length of 0.127nm. (a) At what wavelength (in μm) and wavenumber (in cm−1) would you expect such a molecule to absorb light? (b) When the molecule is in its ground energy state, the two atoms do not simply rest at a fixed distance of 0.127 nm and, instead, they are constantly in motion. What is the maximum and minimum distance of separation between...

Part A Part complete Calculate the "characteristic rotational energy," ℏ2/2I, for the O2 molecule whose bond...

Part A Part complete Calculate the "characteristic rotational energy," ℏ2/2I, for the O2 molecule whose bond length is 0.121 nm. ℏ2/2I = 1.79×10−4 eV Previous Answers Correct Part B What are the energy and wavelength of photons emitted in an ℓ2 = 5 to ℓ1 = 4 transition?

Assume that the molecule is linear and use the values 135 and 154 pm for C=C...

Assume that the molecule is linear and use the values 135 and 154 pm for C=C and C−C bonds. Calculate the energy levels of the π-network in hexatriene, C6H8, using the particle in the box model. The transition is between n = 3 and n = 4. What is the wavelength of light required to induce a transition from n = 3 to n = 4?

A. An electron emits a photon with an energy of 424 nm as it relaxes to...

A. An electron emits a photon with an energy of 424 nm as it relaxes to (n=2) what is the initial energy level of this electron? B. Is energy released or absorbed a result of this transition? Briefly explain. C. Calculate the wavelength (nm) of the electron having the kinetic energy (K.E. = 1/2 mv^2) of the above transition 434 nm. D. If an electron has the following three quantum number, n=2, l= 1, m= 0, and m=-1/2. Briefly explain...