The force constants for F2 and I2 are 470. And 172 N m-1 , respectively. Calculate...

4. The force constant for a H35Cl molecule is 516 N m–1. a. Calculate the zero...

4. The force constant for a H35Cl molecule is 516 N m–1. a. Calculate the zero point vibrational energy for this molecule for a harmonic potential. b. Calculate the light frequency needed to excite this molecule from the ground state to the first excited state.

1)calculate the equilibrium constants at 25∘C for each reaction. Part A 2NO(g)+O2(g)⇌2NO2(g) Express your answer using...

1)calculate the equilibrium constants at 25∘C for each reaction. Part A 2NO(g)+O2(g)⇌2NO2(g) Express your answer using two significant figures. Part B N2(g)+O2(g)⇌2NO(g) Express your answer using two significant figures. 2) Calculate the change in Gibbs free energy for each of the following sets of ΔHrxn, ΔSrxn, and T. Part A ΔH∘rxn=+ 85 kJ , ΔSrxn=+ 155 J/K , T= 298 K Express your answer as an integer. Part B ΔH∘rxn=+ 85 kJ , ΔSrxn=+ 155 J/K , T= 753 K...

1. Calculate F1, the force on the baby due to Mars. Mars has a mass M1...

1. Calculate F1, the force on the baby due to Mars. Mars has a mass M1 = 6.23x1023kg, and when it is at opposition, it is at r1 = 3.78x1011m distance. 2. Calculate F2, the force on the baby due to the doctor. A reasonable mass would be M2 = 65 kg, and the distance would be small, r2 = 1m. 3. What has a greater gravitational influence on the infant, the presence of Mars or the presence of the...

1. An object with a mass m = 2.0 kg placed on a rough horizontal plane...

1. An object with a mass m = 2.0 kg placed on a rough horizontal plane is connected to a spring with a spring constant k = 1000 N/m. When shrinking the spring x = 2.0 cm after releasing your hand, answer the following questions. Note, the friction coefficient is μ = 0.50. (1) Find the work Ws that the spring did before returning to it's natural length. (2) Find the work Wf that the frictional force did during this...

Assume an object with mass m=1 kg is attached to a spring with stiffness k=2 N/m...

Assume an object with mass m=1 kg is attached to a spring with stiffness k=2 N/m and lies on a surface with damping constant b= 2 kg/s. The object is subject to the external force F(t) = 4cos(t) + 2sin(t). Suppose the object starts at the equilibrium position (y(0)=0) with an initial velocity of y_1 (y'(0) = y_1). In general, when the forcing function F(t) = F*cos(γ*t) + G*sin(γ*t) where γ>0, the solution is the sum of a periodic function...

1. Given the force constant k=516.3 N/m, predict the absorption frequency (in Hz) of D35Cl in...

1. Given the force constant k=516.3 N/m, predict the absorption frequency (in Hz) of D35Cl in terms of Hz using format 4.00E10. atomic mass: D, 2.0141;  35Cl, 34.9689 continued of 1: convert the frequency from Hz to inverse centimeter cm-1. Enter a value without unit, with three significant figures continued of 1: continue with the last question, what is the zero-point energy ( J) of the oscillator? Please enter your answer with 3 significant figures.

A stack gas flowing at 80 m^3/min (at T = 25 degree C and 1 atm)...

A stack gas flowing at 80 m^3/min (at T = 25 degree C and 1 atm) contains approximately 75% N2, 5% O2, 8% H2O, and 12% CO2. a) Calculate the gas molecular weight. b) The gas contains 650 ppm SO2; calculate the emission rate of SO2 in kg/day. please show your work in steps specially for part b

1. A caveman applies a horizontal force of 800 N at height of 0.1 m above...

1. A caveman applies a horizontal force of 800 N at height of 0.1 m above the center of a large spherical boulder of mass 400 kg and radius of 0.5 m (treat as a sphere: Icm = 2/5 mr2 ). Assume the sphere starts from rest and rolls horizontally without slipping. a) Draw a free-body diagram and label all the forces at their point of contact. b) Write equations applying Newton’s 2nd law for rotation and translation for the...

The electron concentration gradient of some material is dn/dx=1017cm-4, and the Constant Table: e0 =8.85´10-12C2×N--1×m-2 ;...

The electron concentration gradient of some material is dn/dx=1017cm-4, and the Constant Table: e0 =8.85´10-12C2×N--1×m-2 ; R=8.315J-mol-1×K-1; m0= 4π´10-7N×A-2; h = 6.63´10-34J×s; e = 1.602´10-19C; G=6.67´10-11N×m2-kg-2; me=9.11´10-31kg; g=9.8 m/s2; mobility of the electron is 1350 cm2/V.s，calculate: (a) the diffusion coefficient of the electron, assuming kT=0.0259ev at T = 300 K. (b) the diffusion current density of electrons.

Using the following code: % Ex 6.4 First-order step and impulse response for two time constants...

Using the following code: % Ex 6.4 First-order step and impulse response for two time constants % clear all; close all; t = 0:.1:100; % Time vector subplot(1,2,1); x = 250*exp(-0.05*t); plot(t,x,'k'); xlabel('Time (hrs)','FontSize',14); ylabel('P_A (mmHg)','FontSize',14); title('Impulse Response','FontSize',14); subplot(1,2,2); x = 20*(1-exp(-0.05*t)); plot(t,x,'k'); xlabel('Time (hrs)','FontSize',14); ylabel('P_A (mmHg)','FontSize',14); title('Step Response','FontSize',14);    ANSWER: The response of a 1st order linear body fluid balance system to step function (L m (t) = 1/s, Eqn. 6.9/p226) and impulse function (L d (t) = 1,...