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The chemical reactivity of organic molecules come from their FUNCTIONAL GROUPS

The chemical reactivity of organic molecules come from their FUNCTIONAL GROUPS. Regardless of size!. Carbon-hydrogen backbones can stand alone…. …or they can combine with other elements like O,N,S,Cl,Br,F , etc…. … and each combination will have distinct physi -chemical properties.

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The chemical reactivity of organic molecules come from their FUNCTIONAL GROUPS

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  1. The chemical reactivity of organic molecules come from their FUNCTIONAL GROUPS Regardless of size!

  2. Carbon-hydrogen backbones can stand alone…

  3. …or they can combine with other elements like O,N,S,Cl,Br,F, etc…

  4. … and each combination will have distinct physi-chemical properties. • Solubility (polar? Nonpolar?) • Reactivity (pi bonds? Steric hindrance? Etc..) • Stable in acids? Bases? Reactive with…? • Electronegative-electropositive regions:

  5. CH21 – 12.10.13 , R.D. Bolinas Section 3.5-3.9: Organic Reactions

  6. Moving onto alkenes and alkynes, and other functional groups, we now have more reactive species. Why?

  7. Four major types of Organic Reactions: • ADDITION REACTIONS: reactants combine without anything leaving to form a product.

  8. Four major types of Organic Reactions: • ELIMINATION REACTIONS: reactant usually gives off atoms/has leaving groups. The product usually becomes more unsaturated/ forms a double/triple bond.

  9. Four major types of Organic Reactions: • SUBSTITUTION REACTIONS: reactants exchange groups, like –H and others to give two new products

  10. Four major types of Organic Reactions: • REARRANGEMENT REACTIONS: one reactant reorganizes its own bonds to form an isomer.

  11. Exercise: IDENTIFY!

  12. Exercise: IDENTIFY! catalyst

  13. Exercise: IDENTIFY!

  14. Reaction Mechanisms • Knowing the reaction type is just the beginning. • To really appreciate how we form our products and what we form, we need to study REACTION MECHANISMS

  15. Reaction Mechanisms “A mechanism describes what takes place at each stage of a chemical transformation—which bonds are broken and in what order, which bonds are formed and in what order, and what the relative rates of the steps are.”

  16. Reaction Mechanisms

  17. The movement of electrons can be… Reaction mechanisms entail the movement of electrons VS. Between TWO molecules that collide with each other In pairs (polar reactions) WITHIN ONE molecule (internal) Unpaired/solo (RADICAL reactions)

  18. The two major overarching mechanisms use arrows to show this…

  19. Radical reactions have: initiation, propagation, then termination steps. Initiation: Chemical bond breaking occurs. This can sometimes be done with RADIATION. The breaking bond makes free radicals.

  20. Radical reactions have: initiation, propagation, then termination steps. PROPAGATION: BOTHChemical bond breaking and forming occurs. When a single radical reacts with a normal compound, one product will still be a free radical.

  21. Radical reactions have: initiation, propagation, then termination steps. TERMINATION: TWO free radicals can pair up their unpaired electrons to finally form a stable covalent bond. This ends the reactions.

  22. Polar processes are the more common mechanism • Recall electronegativity and polarity • Recall how many functional groups have atoms that can make them polar • Recall also how opposite charges attract

  23. In polar mechanisms, electrons move from Nucleophile to Electrophile.

  24. In polar mechanisms, electrons move from Nucleophile to Electrophile. • Nucleophiles (Nu) – “Nucleus-loving” attracted to positive charges because it is RICH IN ELECTRONS/ negative

  25. In polar mechanisms, electrons move from Nucleophile to Electrophile. • Electrophiles (E) – “Electron-loving” attracted to negative charges because it is POOR IN ELECTRONS/ positive

  26. In polar mechanisms, electrons move from Nucleophile to Electrophile.

  27. In polar mechanisms, electrons move from Nucleophile to Electrophile. • Note that neutral compounds can often react either as nucleophiles or as electrophiles, depending on the circumstances. (e.g. H2O)

  28. Exercises: follow the arrow!

  29. Exercises: follow the arrow!

  30. Exercises: follow the arrow! TOO LAZY to make this white.

  31. Exercises: follow the arrow!

  32. Exercises: follow the arrow!

  33. Exercises: follow the arrow!

  34. Exercises: follow the arrow!

  35. Sample mechanism, and how to analyze and follow it

  36. The mechanism is noted as an ELECTOPHILIC ADDITION Which is the Nucleophile? The Electrophile?

  37. When we plot ENERGY DIAGRAMS, we can match a mechanism with THERMODYNAMIC INFO.

  38. Terms to remember • Reactants = where we start. • Transition states = the in-betweens usually with bonds halfway broken and half-formed, and are almost impossible to isolate. • Intermediates = another kind of in-between but more of a quick “rest-stop” form we can sometimes isolate and identify. It has its own structure (no “half-bonds”)

  39. Terms to remember • Activation Energy = shown as the height of a hump RELATIVE TO WHERE THE BASE IS (either the products-level or an intermediate-level). This is the energy needed to be overcome for the reaction to move forward.

  40. Terms to remember • Total Energy Change = this is the change in energy level from reactants to products. • A positive one (going net up) means it is ENDOGENIC and absorbs energy, so it is not as favorable. • A negative change (going net down) means the reaction is EXOGENIC and releases energy as the reaction progresses and is more favorable.

  41. Catalysts LOWER ACTIVATION ENERGY! DIFFERENT PATHWAY/ MECHANISM

  42. Exercises: Draw the arrows

  43. Exercises: Draw the arrows

  44. Exercises: Draw the arrows

  45. Exercises: Draw the arrows

  46. Exercises: follow the arrow! YOU CAN DO IT! ^____^

  47. Exercises: follow the arrow! OMGWTH?!!?!

  48. Exercises: follow the arrow!

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