ch. 6 - chemical bonding; section 5 Flashcards
molecular geometry
3D arrangement of atoms in molecule, helping to make up its properties
molecular polarity
unequal pull of electrons/uneven distribution of molecular shape
influences forces that act between molecules in liquids and solids
how to tell if a molecule is polar?
if it has lone pairs on central atom or isn’t symmetrical
VSEPR theory
- repulsion between sets of valence-level electrons surrounding an atom causing them to be oriented as far apart as possible
- minimizes repulsions of electrons while maximizing distance between them
- elements must be certain distance apart so they don’t push one another away
- predicts arrangement of electron pairs around each central atom and usually the correct arrangement of atoms in a molecule
- ONLY consider electron-pair repulsions
lone pairs
exert greater repulsions and are less confined in space, reducing other bond angles or causing them to ‘bend’
what is the difference between electron-pair geometry and molecular structure?
- electron-pair geometry includes lone electrons and bonded electrons; all regions where electrons are located
- molecular structure is the location of ATOMS, therefore excluding lone pairs
what are the 5 molecular shapes and formulas?
- AB2 = linear, angles of 180 degrees
- AB3 = trigonal-planar, angles of 120 degrees
- AB4 = tetrahedron, angles of 109.5 degrees
- AB5 = trigonal bipyramidal, axial angles of 90 degrees, equatorial angles of 120 degrees
- AB6 = octahedron, all angles of 90 degrees
hybridization
a model involving the mixing of two or more atomic orbitals of similar energies on the same atom to produce new hybrid atomic orbitals of equal energies
s + p = sp (2 hybrid orbitals)
s+p+p = sp2 (3 hybrid orbitals)
s+p+p+p = sp3 (4 hybrid orbitals)
hybrid orbitals
orbitals of equal energy produced by the combination of two or more orbitals on the same atom
i. e. s and p orbitals combine together to create sp3 hybrid orbital
- sp2 = trigonal planar
- sp3 = tetrahedral
- sp3d = trigonal bipyramidal
- sp3d2 = octahedral
intermolecular forces
the forces of attraction between molecules
dipoles
- molecules that contain both positively and negatively charged regions
- created by equal but opposite charges that are separated by a short distance
- direction of dipole is from positive pole to negative pole
- a polar molecule can induce a dipole in a nonpolar molecule by temporarily attracting its electrons; this accounts for fact that nonpolar molecules, like oxygen, can dissolve in water
dipole-dipole forces
- interactions between polar molecules
- molecules attract eachother with opposite charges/regions
hydrogen bonding
- intermolecular force in which a hydrogen atom, bonded to a highly electronegative atom, is attracted to another highly electronegative tom on nearby molecule
- hydrogen can ONLY bond with fluorine, oxygen, or nitrogen
london dispersion forces
- intermolecular attractions resulting from constant motion of electrons and the creation of instantaneous dipoles
- the connection between everything interacting with each other
- mainly on nonpolar molecules
ion-dipole forces
ions interacting with polar molecules
