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Application of quantum in chemistry
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The Particle in A Box
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The ‘Classical’ Case
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The ‘Quantum’ Case
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The absolutely small particle in the nanometer size box is a quantum particle, and it must obey the Uncertainty Principle, that is, ΔxΔp= h/4π. If V=0 and x= L/2, we know both x and p. The result would be ΔxΔp 0, the same as the classical racquetball. This is impossible for a quantum system. Therefore, V cannot be zero. The particle cannot be standing still at a specific point. If V cannot be zero, then Ek can never be zero. The Uncertainty Principle tells us that the lowest energy that a quantum racquetball can have cannot be zero. Our quantum racquetball can never stand still.
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Energies of a Quantum Particle in a Box
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Wave functions must be zero at the walls
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Nodes are the points where the wave function crosses zero
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Energies are quantized
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A Discreet set of energy levels
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Why are Cherries Red and Blueberries blue ?
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The Colour of Fruit This energy corresponds to Deep Red Colour
If L=0.7 nm, =540 nm If L=0.6 nm, =397 nm Green Colour Blue Colour
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Particle in a box Step 1: Define the potential energy Step 2: Solve the Schrodinger equation Step 3: Define the wave function Step 4: Determine the allowed energies Step 5: Interpret its meaning
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Particle in 1-dimensional box
Infinite walls Time Independent Schrödinger Equation V(x)=0 V(x)=∞ L x Region I Region II Region III KE PE TE Applying boundary conditions: Region I and III:
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Functions with this property sin and cos.
Second derivative of a function equals a negative constant times the same function. Functions with this property sin and cos. Copyright – Michael D. Fayer, 2007
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b) x=L ψ=0 Region II: Thus, wave function: But what is ‘A’? a) x=0 ψ=0
This is similar to the general differential equation: But what is ‘A’? Applying boundary conditions: a) x=0 ψ=0
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Normalizing wave function:
Calculating Energy Levels: Thus normalized wave function is: Thus Energy is:
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Particle in a 1-Dimensional Box
Difference b/w adjacent energy levels: 2) Non-zero zero point energy 3) Probability density is structured with regions of space demon- -strating enhanced probability. At very high n values, spectrum becomes continous- convergence with CM (Bohr’s correspondance principle) + + + - + + E y y*y
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Particle in a 3-D box
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Question: An electron is in 1D box of 1nm length
Question: An electron is in 1D box of 1nm length. What is the probability of locating the electron between x=0 and x=0.2nm in its lowest energy state?
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Question: An electron is in 1D box of 1nm length
Question: An electron is in 1D box of 1nm length. What is the probability of locating the electron between x=0 and x=0.2nm in its lowest energy state? Solution:
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Question: What are the most likely locations of a particle in a box of length L in the state n=3
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Example: What are the most likely locations of a particle in a box of length L in the state n=3
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Expectation value of position and its uncertainty
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Expectation values Position Uncertainity
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Expectation value of Momentum
And square of momentum
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Momentum
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Estimating pigment length
Assumptions:
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Wavelength of transition for Anthracene
Particle in a Box Simple model of molecular energy levels. Anthracene L p electrons – consider “free” in box of length L. Ignore all coulomb interactions.
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Pigments and Quantum mechanics
High degree of conjugation!! Electrons have wave properties and they don’t jump off the pigments when they reach its ends. These electrons resonances determine which frequencies of light and thus which colors, are absorbed & emitted from pigments
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Electron resonances in a cyclic conjugated molecule
A crude quantum model for such molecules assumes that electrons move freely in a ring. Resonance condition: R: radius of molecule, λ wavelength of electron
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Energy is once again quantized
Energy is once again quantized. It depends on variable n which posseses discrete values only
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