PCHEM Exam 1- Units 2,3,4, & 5

Hermite polynomials

(Hn (ɑ^1/2x). These are polynomial functions where Hn is a nth degree polynomial in Xi

linear operators

(ex. - operator A^) a special property of these operators is that a linear combination of two eigenfunctions of the operator with the same eigenvalue is also an eigenfunction of the operator

quantum number

(symbolized by the letter n) describes the value of an energy level. For particle in a box, n cannot equal 0, it starts at n=1. They appear natural in the Schrödinger equation, not ad hoc like in Plank model or Bohr model

normalization constant (B)

= (2/a)^1/2. Find B by setting the condition that the function Ψ(x) is normalized

radial node

= n-l-1 // point at which probability is zero of find electrons at a radius, r and probability and wave function are at zero on plotted graph // r=0 is not a node // when R(r) = 0

probability density*****

A function that describes the relative likelihood for a sample to be in a certain region. The probability of finding a particle is always positive. Generally, probability density increases as n increases.

observable

A measurable dynamical variable. Usually the eigenvalue(Energy) of an eigenfunction.

commutation

A property of operators in which A^B^f(x) is compared to B^A^f(x). (you use A^ as the operator for B^f(x) and then use B^ as the operator for A^f(x). Operators do not usually commute - they do not normally equal the same thing)

wave functions

AKA state function. has the important property that Ψ*(x)Ψ(x)dx is the probability that the particle lies in the interval dx, located at the position x.

moment of inertia****

I = μr^2. the rotational analog of mass for linear motion

average value

If a system is in a state described by a normalized wave function Ψ, then the average value, <a>, of the observable corresponding to A^ (operator) is given by : ∫ Ψ*A^(operator)Ψ dx

separable Hamiltonian

If the Hamiltonian operator can be written as a sum of terms involving different coordinates(Ex. x,y,z), then the eigenfunctions of H ^ is a product is a product of eigenfunctions of each operator, and the eigenvalues of H ^ is a sum of eigenvalues of each operator constituting the sum.

orthonormal

If the two wave functions are normalized (the integral of the product of the wave function and the complex conjugate = 1) then the 2 functions are orthonormal

Eigenvalue-eigenfunction relationship

In the relationship, there is an operator for the eigenfunction, and performing this gives an eigenvalue(a number) and the original function. An eigenvalue can not include any other variables.

legendre polynomials

P0 (x) = 1 // P1 (x) = x // P2 (x) = 1/2 (3x^2 -1) where m = 0 // orthogonal to each other the solutions P(x) depend on m and l where l=1,2,3... and m= 0,+-1,+-2,....+-l. P(x) = Θ(θ) polynomials found in the legendre equation, which solves for Y(θ,φ) (rigid rotator wave functions)

ultraviolet catastrophe

Rayleigh-Keans law reproduces the experiment at low frequencies but diverges at high frequencies (short wavelength) as radiation enters the ultraviolet range// rayleigh-Jeans law about blackbody radiant energy density - first failure in CLASSICAL physics trying to explain quantum ideas

Rydberg constant

Rh = 109677.57 cm-1

classical limit

The large quantum-number limit described in the Correspondence Principle is the classical limit

Laplacian operator

The partial derivatives in schrodingers dimensional equation with x,y and z axis // ∇2

free-electron model

The particle in a box model can be applied to electrons moving freely in a molecule (AKA free electron model)

commutator

[A^,B^] = A^B^ - B^A^. <<< perform this to get the commutator (one of the hw probs). It shows if you can measure two "observables" simultaneously.

operator

a symbol that tells you to do something (a mathematical operation) to whatever (function, number, etc.) that follows the symbol. (uses the ^ symbol)

blackbody

an ideal body, which absorbs and emits all frequencies // ideal blackbodies do not exist - most absorb/emit all frequencies in a limited range of frequencies

series limit

as n increases the lines bunch up towards this // the limit of wavelengths/frequencies allowed for the transitions in the series (lyman limit is UV light / Balmer limit is Vis light / Bracket limit is IR light) // obtained for n2 -> ∞

wave-particle duality

light behaves as a wave in some experiments and as a stream of photons in others

line spectra

certain discrete frequencies from the emission spectra of atoms // simplest is the hydrogen atom

Rydberg formula

the generalized balmer formula when other series discovered in UV and IR // ν~ = 1/λ = Rh (1/n1^2 - 1/n2^2) where n1 < n2 therefore n1 is the lower level that the electron originated from

zeeman effect

degeneracy (2l+1) of each energy level is removed in magnetic field (becomes unequal energies due to diff m values)

Balmer formula

describes the lines in the hydrogen spectrum occurring in VIS and near UV regions // ν= 8.2202e12(1-4/n^2) Hz /// in wavenumbers -> ν~ = 109680 (1/2^2 - 1/n2^2) cm-1

quanta

discrete increments/units // energy quantization : an oscillator acquires energy in these discrete units

de Broglie wavelength

exhibited by a particle of mass, m, moving with a speed, v

odd function

f(x) = -f(-x)

even function

f(x) = f(-x)

force constant (k) ***

force required to produce unit extensions or compression. Used in the harmonic oscillator

normalizable

function is this if ∫Ψ*(x)Ψ(x)dx = A not = 1 because they can be normalized if they are divided by √A

angular momentum

given by ehrenfest rule // denoted by L // L =mevr = n(h/2π) = nħ // is quantized -> v= nh/2πmer

Heisenberg Uncertainty principle

if we wish to locate an electron within a region Δx there will be uncertainty in the momentum of the electron Δp that is greater than h/4π // ΔxΔp>= h/4π or ħ/2 OR uncertainty in energy and time ΔEΔt>= h/4π or ħ/2

rotational constant (B)

if you know B, you can solve for r, and then solve for I

azimuthal/secondary/orbital quantum number

l // describes the type of sub shell(or shape) // l = values between 0 and n-1 // assist in determining radial function // completely determines the magnitude of angular momentum of the electron about the nucleus (proton) l=0 s l=1 p l=2 d l=3 f

magnetic quantum number

m // can take (2l+1) values : m=0 to +- l // describes orientation or type of orbitals, and assists in determining actual orbital // completely determines the z component of the angular momentum // determines the energy of hydrogen atom in a magnetic field

threshold frequency

minimum frequency of light required to eject and electron // below which no electrons eject // Vo // above Vo the KE of the electrons varies linearly with frequency

principle quantum number

n // describes both the shell or level and sub shell // n=1,2,3,... // assist in determining radial function

total number of nodes

n-1

Lyman series

n1 = 1 n2= 2,3,... // UV range ~100-400 nm higher E difference

Bracket series

n1= 4 n2=5,6... // IR rang ~700 nm - 1 mm smaller E difference

Balmer series

n1=2 n2=3,4... // Vis range ~400-700 nm

tunneling

nonexistent in classical mechanics - a QM property that the wave function is non-zero in classically forbidden zones

angular node

number of nodes in the angular part is given by l // when Y (θ,φ) = 0

photoelectrons

observed emitted electrons from the surface of solids upon incidence of light having suitable wavelengths depends on frequency NOT intensity of light but number of electrons emitted is proportional to intensity of light

stationary state or orbit

observed spectrum is due to transitions from one allowed energy state to another one // spectral "terms" from ritz rule // both assumed these to exist so the electron is not accelerate toward the nucleus

nodal plane

plane that crosses through angular part at which no electrons are present

associated Laguerre polynomials

polynomials found at the end of the radial part of wave function ( back part of equations whole right section) polynomials are dependent on n and l

Correspondence Principle

quantum mechanics results and classical mechanics results tend to agree in the limit of large quantum numbers

blackbody radiation

radiation emitted by the blackbody

rigid rotator

refers to the QM treatment of rotational motion - a model for a rotating diatomic molecule

Particle-in-a-box

refers to the quantum mechanical treatment of translational motion. Solving Schrödingers equations obtains the wavefunctions and the allowed energies for the particle. Energy levels and energy separation b/w the energy levels increases as the size of the box or mass decreases

harmonic oscillator

refers to the quantum mechanical treatment of vibrational motion. the total energy is conserved, it is transferred between K and V. It is a model for vibrations in diatomic molecules

Wein displacement law

relationship between the wavelength at maximum intensity and the temperature; λmaxT=constant = 2.8979e-3 mK

degeneracy

represents the property of two or more eigenfunctions having the same eigenvalue. (AKA levels contain multiple wave functions with the same energy). = 2J+1

photon

small packets (quanta) of light of radiation (blackbody) // proposed by einstein E = hν

IR spectrum

the QM harmonic-oscillator model accounts for the IR spectrum of a diatomic molecule

Planck constant

the constant h in the planck distribution law for blackbody radiation // law reproducible for all frequencies if h=6.626e-34 Js and temps // explains the constant in weins law

complete set

the eigenfunctions of QM operators form a complete set

orthogonal

the eigenfunctions of the QM operators are orthogonal. If you know something about one, you know nothing about the other. If the eigenvalues of the wave functions are real, then the integral of product of the two functions = 0.

fundamental vibrational frequency

the existence of only one frequency in the spectrum of a diatomic molecule - harmonic oscillator predicts this

microwave spectroscopy

the frequency of transitions in the rigid-rotator is in the microwave range of electromagnetic radiation (10^10 - 10^11 Hz)

complex conjugate

the function Ψ. It is obtained by replacing i with -i in the expression of the wavefunction Ψ. The produce ΨΨ becomes real. Ψ*(x)Ψ(x)dx is the probability that the particle to be located between x and x+dx.

Schrödinger equation

the is the fundamental equation of QM for finding the wave function of a particle. Based on the idea that if the matter possesses wavelike properties there must be a wave equation that governs them. It cannot be demonstrated, only seen as a fundamental postulate. Time independent // for 1-D 2-D and 3-D

Bohr frequency condition

the lines in the spectrum were a result of two allowed stationary states (terms) and planck-einstein equation E=hν holds with the energy being equal to energy difference between two states, n1 and n2 (energy difference is same thing as the light absorbed/emitted hν)

most probable value of r

the maximum probability // the first bohr radius is equal to the most probable radius for the 1 s orbital // the average vale of r for 1s is = 3/2 ao (bohr radius)

work function

the minimum energy required to remove an electron from the surface of a particular metal // denoted Φ // KE of the ejected electrons is the difference between the incidence photon hν and the min energy to eject // KE = 1/2 mv^2 = hν - Φ = hν - hνo where Φ=hνo where νo is the threshold frequency // usually eV

reduced mass (μ)

the movement of a two-body system can be reduced to the movement of a one-body system with a mass equal to the "reduced mass" of the two-body system. Shown by μ on the equation sheet, but make sure to multiply by the conversion from amu to kg!!

zero-point energy

the residual energy of the harmonic oscillator, it is different than zero, and it is obtained for the vibrational quantum number n=0

spherical harmonic functions

the rigid-rotator wave functions

first Bohr radius

the smallest radius, obtained for n=1 // ao = 5.292 e-11 m = 0.5292 A = 1 bohr

boundary surface

the surface 9of equal density) that contains 90% of electron density

selection-rule

the transitions between various levels in harmonic oscillator follow this rule - that there can only be transitions between adjacent states

angular momentum magnitude

the value of L by solving from the eigenvalue of the angular momentum operator. The eigenvalue itself give the square of it

atomic orbitals

these are given by solving the schrodinger equation for the hydrogen atom, one obtains the allowed energies (eigenvalues) and the wave functions of the electron (eigenfunctions)

term

transitions are said to take place between two terms // another name for energy level // Ritz combination rule // T1 = Rh/n1^2 and T2 = Rh/n2^2 and that ν~= T1-T2 essentially the breakdown of rydberg eqt //

variance/standard deviation

variance is a statistical mechanics quantity, the variance of experiments becomes zero bc the standard deviation is zero, so the only values observed are the An values (the eigenvalues)

normalized

wave functions that satisfy the condition of ∫Ψ*(x)Ψ(x)dx = 1

operand

what follows the operator

associated legendre polynomials

when m does not equal 0 there is a structured equation that you fill in based on m and l values // P ml (x) // normalizable

ground state

when n=1 // E1 = -13.6 eV = -1312 kJ/mol = -109690 cm-1

excited states

when n=2,3,... // E2 = -3.4 eV = -328 kJ/mol E3 = -1.5 eV = -134 kJ/mol