Spectroscopy with Milder Photons: Molecular Vibrations.

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Presentation transcript:

Spectroscopy with Milder Photons: Molecular Vibrations

Solar Radiation What wavelengths are present? This depends on the wavelengths given off by the sun (black body radiation) AND the wavelengths absorbed by the atmosphere

Incident Light on Earth Water: 725, 820 and 975 Oxygen Oxygen and Ozone <400 Water Carbon Dioxide and other Greenhouse gasses >1200

Troposphere: weather Commercial airplanes and jets: 11 km, 1/3 to 1/5 atmosphere Stratosphere: from 10% to 0.1% of our density, from 18 km to > 50 km horizontal air flow Oxygen and Ozone in upper stratosphere is v. imp for UV Oxygen rich atmosphere is due to plants and algae (not originally here)

Oxygen, Ozone and UV Stratosphere: O 2 + h --> 2 O < 241 nm (496 kJ/mol) O 3 + h --> O 2 + O nm

What happens to the visible light once it reaches the earth? The pigments of life Chlorophyll Heme (e.g. Myoglobin) Carotenoids, retinal etc. These chromophores are conjugated molecules …

Wavelength and Molecule Size As the size of the conjugated system gets larger, the wavelength gets longer. Which is larger, the molecule or the wavelength? How much larger? Wavelength of 200 nm, molecule length is < 1 nm. Wavelength is much much larger.

Red lamp: emits at 600 Blue lamp: emit at 450 Red dye: absorbs at (passing at 600) Indigo dye: absorb at (passing at 450)

Chlorophyll

beta Carotene

anthocyanin

How Many Photons Are Needed? Chl + h --> Chl + + e - Energy in a nm photon: ~200 kJ/mole Energy needed for reactions below is ~ 500 kJ/mole oxygen CO 2 + H 2 O --> (CH 2 O) + O 2 2H 2 O --> 2H 2 + O 2 4 Photons/ 4 electrons/ 4 protons/ one oxygen

Some UV Radiation Does Reach the Earth How is UV distinct from visible? Almost double the energy per photon! Makes radicals, causes significant chemical reactions Skin cancer, begins with “DNA damage”

DNA 2’ Deoxyribo Nucleic Acid

Photochemistry of Alkenes: DNA Damage Several akenes can be combined to form larger carbon “skeletons” Lets review the orbitals that might be involved

Ethene

1,3 Butadiene: Conjugation

Combining two alkenes Reactants: three double bonds (612 kJ/mole), one single bond (348 kJ/mole) 2184 Product: one double bond, five single bonds 2352 More stable If aligned by matching the orbitals of two reactants: highest occupied and lowest unoccupied, can react.

UV Photochemistry Reactants: two double bonds (612 kJ/mole), 1224 Product: four single bonds (348 kJ/mole), 1392 More stable However… cannot align orbitals properly in ground state to react. Use light: reaction begins from an excited state, e.g. LUMO and LUMO can match Many alkenes undergo bond forming reactions in response to light.

DNA: UV photochemistry

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Melanin, the skin pigment, is a similarly conjugated system, formed by joining several double bonds Eumelanin:black/brown Pheomelanin: red/orange

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Global Warming: Expected Consequences drought, new deserts ocean ice melting: many major cities will be deluged

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