2.2) The Morse interatomic potential for a diatomic molecule is given by VM(r) D[1-e-a-1 r-ro where...
Draw a typical Morse potential energy surface for a diatomic molecule. Label the following i) The vertical and horizontal axes ii The equilibrium bond length. iii) The v=0, 1, 2 vibrational iv) The dissociation energy (Do) from the v-0 vibrational level 1 levels.
The potential energy of two atoms in a diatomic molecule is approximated by U(r)=d/r12-b/r6, where r is the spacing between atoms and a and b are positive constants. Find the force F(r) on one atom as a function of r. Find the equilibrium distance between the two atoms. Express your answer in terms of the variables a and b. Is this equilibrium stable? Suppose the distance between the two atoms is equal to the equilibrium distance found in part (b)....
The potential energy of two atoms in a diatomic molecule is approximated by U(r)=a/r^12−b/r^6, where r is the spacing between atoms and a and b are positive constants. Find the component of force along the line connecting the two atoms, Fr(r), on one atom as a function of r. Find the equilibrium distance between the two atoms. Is this equilibrium stable? Suppose the distance between the two atoms is equal to the equilibrium distance found in part A. What minimum...
The potential energy of a diatomic molecule (a two-atom system like H, or 02) is given by А B E, (1) 76 where r is the separation of the two atoms of the molecule and A and B are positive constants. Eq. 1 is also known as Lennard-Jones potential. (a) Derive the force acting between the two atoms as a function of their distance r. [4 marks] (b) Find the system's equilibrium separation. [4 marks] (c) For a total mechanical...
4. Energetics of diatomic systems The energy of a diatomic molecule can be represented by the empirical function A B R9 R where A and B are positive constants. The second term is the usual Coulomb interaction, while the first term is introduced to account for the repulsive effect of the two ions at small distances. Find A and B in terms of the equilibrium separation Req and the dissociation energy Eo
Anharmonic oscillator. Hydrogen bromide, H8Br, vibrates approximately according to a Morse potential VM(r) = Dell-e-ck/2De)i/2(r-re) , with De= 4.810 eV, = 1.4144 A, and k= 408.4 N m-1. With a0-Vk/a, the energies of the stationary states in a Morse potential are En (n + 1/2)2. (A) On the same graph, plot the Morse potential and the harmonic potential as a function of bond length (from 0.7 to 2 %). Use the software of your choice to generate this plot. (B)...
1 Vibrational states of a diatomic molecule 1. Use Taylor expansion to get a harmonic approximation Vharmonic( 0.5k(r Ro2 of the following potential 2. Find the expressions for the equilibrium distance Ro and for the harmonic 3. Calculate the zero point energy in terms of the parameters of the given 4. Calculate the energy of a photon emitted upon a transition between ad- force constant k potential (a, ro and D jacent levels in terms of the parameters of the...
1. Anharmonic oscillator. Hydrogen bromide, 'HiBr, vibrates approximately according to a Morse potential VM(r) = Dell-e-w2De)1/2 (r-rej2 with De= 4.8 10 eV, re= 1.4 1 44Ă, and k= 408.4 N m-1. With ω,-VRA, the energies of the stationary states in a Morse potential are En (hwo) 4D ho(n+ 1/2)- (n + 1/2)2. (A) On the same graph, plot the Morse potential and the harmonic potential as a function of bond length (from 0.7 Te to 2 re).(B) Describe the differences....
5. (10 points) A simple function that looks like the potential well of a diatomic molecule is the Morse potential given by: U(x) = D. (1-e-Bx) (1) where, x is the displacement of the bond from its equilibrium position, and D. is the value of U(x) at large separations. D. is called the classical dissociation energy and is characterized by the depth of the potential well. We can expand U(x) in a Taylor series about x = 0 to obtain...
Compute the interatomic distance between two atoms inside a diatomic molecule given spectroscopic data (the rotational temperature) Θ r o t This problem has two questions. The first is for a real molecule . The second is a hypothetical molecule (made up atomic masses and Θ r o t ) 1) compute the internuclear separation for 35Cl2 in picometers (pm). For consistent mass data use values from: 2) Consider a hypothetical diatomic molecule where the mass of atom 1 =...