2 models of bondings and structure

Question 1

Formal charge

Answer 1

Formal charge (FC) is determined for each atom in a structure from:
FC = V – (½B + L)
where V = valence electrons, B = number of bonding electrons, L = number of one pair electrons

The most stable of several Lewis (electron dot) structures is the structure that has: the lowest formal charges, negative values for formal charge on the
more electronegative atoms.

Question 2

Ionic bonding

Answer 2

Electrostatic attraction between oppostiely charged ions

Question 3

Physical properties of ionic compound

Answer 3

• lattice structures ➪positively charged ions are packed as closely as possible to the negative
  charged ions, while ions of the same charge are as far apart as possible ➪maximizes electrostatic attraction between the ions, while minimizing repulsion
• surrounded by 6 other atoms
• low volatility
• Higher temperature (solid at room temperature)
• no conductivity, except at molten or aqeous state
• ionic compounds are soluble in polar solven ➪ partial charges of water is attracted to opposite charge in the lattice (eg: H2O)

Question 4

Compare the conductvity of AlCl3 (s) and AlCl3(l)

Answer 4

• AlCl3 (s) : no conductivity at solid state ➪ no delocalized electrons at covalent
• AlCl3(l): covalent bonds but no delocalized electrons due to cordiante bonds to Al

Question 5

Draw the ionic strucure between Na and Cl

Answer 5

Question 6

a) state the electronegative value and the shape of pure covalent

Answer 6

• 0<x<0.5: non polar bond have equal sharing of bond electrons/dipole moment is cancled ➱temporailiy dipole ➱ they are symmetrical [F2, H2, and O2]
• 0.5<x<1.8: polar covalent are paritally ionic/partial tansfer of unequal sharing of electron➱ permanent dipole ➱ they are unsymmetrical
• 1.8<x: greatest electronegtaive difference➱complete transfer of electrons

Question 7

Covalent bonds

Answer 7

• electrostatic attraction between a shared pair of electrons and the positively charged
• generally occur between non metals
• Most stable of similar ionization and affinity for electrons by sharing of electrons
• in a covalent strucure, shared electron are attracted to the nulceus of both atoms
• exists as london dispersion force, permanent dipole force, instaneous dipole force and hydrogen bond

Question 8

Bond length

Answer 8

measure of the distance between the two bonded nuclei

Question 9

Bond strength

Answer 9

described in terms of bond enthalpy, and is effectively a measure of the energy required to break the bond

Question 10

Lattice enthalpy

a) write an equation for lattice enthalpy NaCl

Answer 10

energy needed to seperates the ions and the entahlprt change is positive

Question 11

Describe the relationship between bond strength and length

Answer 11

• bond length increases down the group
• Bond length decreases as the number of electron pair increases because there will be a greater attractive force between
  the two nuclei
• bond strength increase up the group
• Bond strength increases as the number of electron pair increases as more energy is required to break them

Question 12

Rules to Expanded octect

Answer 12

• Atoms of elements in period 3 and below may expand their octet by using d-orbital’s in their valence shell
  *surrounding atoms must have electron number full shelll but central atom dosent need it

Question 13

rules to drawing the lewis diagram

Answer 13

1. (desired number of electrons - actual number)/2= # lone pairs
2. draw the central atom by using the least electronegative electron
3. complete the octect

desired number of hydrogen= 2
actual e= # valence electron
desired e= valence electrons + extra set of theoritical lone pair

Question 14

rules for drawing polyatomic ion

Answer 14

1. (desired number of electrons - actual number+charge number)/2= # lone pairs
2. draw the central atom by using the least electronegative electron
3. complete the octect
4. check for resonance strucure

*indivisual charge -ve/extra e are distributed to the surrounding atoms to make full valence electrons. Cooridnate dative bond is from the central atom to make bondings with the surrounding atom.
*charge +ve/ electron are removed from sourrounding atoms, therefore central atom needs to donate an coordinate bond. You need to draw an arrow indicating where the coordinate bond came from.

Question 15

2)Draw an resonance structure of sulfate SO42-
3)find its bond order

Answer 15

Question 16

Draw
a) BeCl2
b) BF3
c)BF3NH3

Answer 16

• incomplete octect, they are electron deficient and have tendency to accept electron pair from NH2 or H20

Question 17

Coordinate bond

Answer 17

• dative bond, covalent bond in which both the shared electrons are provided by one of the atoms.

Question 18

Drawing expanded octect

Answer 18

1) number of valence electrons in the central atom is the number of bonds/surrounding atoms attached

Question 19

find the bond order of C~O bond in CH3CO2-

Answer 19

• resonance strucure with bond order of 1.5
• shorter than single bond and longer than double bond

(#bond involved in coordinate bond)-(# atoms bonded)/2

Question 20

Draw
a)NO2

Answer 20

No is an electron deficient central atom, 0.5 bond mean the central atom has radical.

Question 21

Determine which molecule has the strongest bond: ethane, ethyne and ethyne

Answer 21

Question 22

Electrogentive value for central atom

Answer 22

F>O>CL>N

Question 23

Rules to drawing coordiante covalent bond

a) (NH4)+1
b)(H3O)+
c)CO
d)CH3OOH
e)HCOOH
6) CH3CH2COOH

Answer 23

• try using the HONC rule first
• if Honk rule dosent work then that means there is coorindate bond
• put electrons away from each other
• look at the functional group to identigy the structure, eg:COOH, OH
• make sure to put lone pairs of electron in atoms that does not meet the desired number of electrons

Question 24

\

electron domain

Answer 24

Describes the number of electrons in the valence shell. They may be occupied by lone pairs, single, doubleor triple bonds. Includes number of bonding pairs and non-bonding pairs surrounding the central molecule

Question 25

Draw
a) Mgcl2
b)AlCl3
Al2O3

Answer 25

Question 26

VSEPR theory

Answer 26

lone pair – lone pair > lone pair – bonding pair > bonding pair – bonding pair

Question 27

draw
a) XeF4
b)XeF2

Answer 27

Question 28

intermolecular force

Answer 28

Van der waals

• lone disperion force: all molecules, weak attraction between non-polar electron
• Dipole-induced force: induces non polar to become temporary dipole
• Dipole-dipole force: permanent dipole/polar molecules
• hydrogen bond:F,O,N——H

• intermoleulcar force depends on electronegativity difference.

Question 29

What factor that increases the strength of intermolecular force

Answer 29

1. down the group, larger number of electrons, decreases electron density (larger), stronger london dispersion force➱ higher boiling/melting point/lower volatility
2. increased molar mass/size
3. extent of polarity within the molecule

Question 30

What causes increases in bond polarity?

Answer 30

Electronegativity (larger difference between partial charges) across period/up the group: higher nuclear charge but same sheilding or less electron shell therefore high electron affinity, shared electrons with stronger attraction to the nucleus of the opposite atom, increased electronegativity/dipole moment, will cause unsymmetrical shape and show ionic

Question 31

Benzene

Answer 31

*C6H6
* delocalized pi electron spread equally through the ring.
* carbon-carbon bond have intemediate bond strength and length between single and double bond
* resonance structure that provides stabillity, unreactive

Question 32

1)draw ozone resonance strucure
2) describe the strength and length bonds of ozone
3) what makes causes double bonds in ozone

Answer 32

• resonance hydride have delocalized elecrron to be shared in more than on bonding position to make double bond.
• It has intermediate bond strength and length between single and double bond
• The double bond is composed of a sigma (σ) bond from the overlap of
  hybrid orbitals, and a pi (π) bond from the overlap of unhybridized p orbitals. The electrons in the pi bond are less tightly held so become delocalized through the structure, giving rise to the resonance forms

Question 33

allotropes of carbon

Answer 33

different form of an elemet in the same physical state

Question 34

State the type of intermolecular force involved in CH3OCH3 and C3H8

Answer 34

melting and boiling points of polar compounds to be higher than those of non-polar substances of comparable molecular mass.

Question 35

Hydrogen bonding

Answer 35

• attatched to fluorine, nitrogen, or oxygen causes large electronegativity difference
• small size no shielding, the hydrogen now exerts a strong attractive force on a lone pair in the electronegative atom of a neighbouring molecule
• two hydrogen atoms in each molecule and the two lone pairs on the oxygen atom, each H2O can form up to four hydrogen bonds with neighbouring molecules

Question 36

Solubility of molecular compoud

Answer 36

• Non-polar substances are generally able to dissolve in non-polar solvents by the formation of London dispersion forces between solute and solvent
• Polar covalent compounds are generally soluble in water by dipole interactions and hydrogen bonding

• ionic: must become molten state
• molecular: depends on polarity/electronegativity difference
• Giant covalent: insoluble

Question 37

Fill out the physical properties of ionic compound and covalent compounds

Answer 37

Question 38

Explain the bonding strucure of sillicion dioxide

Answer 38

• tetrahedral in giant lattice strucure that involved all four sillicon valence electrons
• each si atom is covalently bonded to four O atoms and each O to two Si atoms

Question 39

What are the physical properties of sillixion

Answer 39

1. strong
2. insoluble in water
3. high melting point
4. non-conductor of electricity.

Question 40

1)Explain why H2O, HF and NH3 have higher boiling points

2) Explain why boiling point increases from peiroid 3

Answer 40

1) hydrogen bonds
2) increased number of electrons as you go down the group

Question 41

Metallic bonding

Answer 41

electrostatic attraction between sea of delocalized electron and postive cations

Question 42

What impacts the strength of metallic bonds

Answer 42

1. number of delocalized electrons
2. charge of the cation
3. radius of the cation

Question 43

a) Does Mg or Na have higher boiling point?
b) Does Na, K or Rb have higher melting poin?

Answer 43

a) Na (98ºC) < Mg (650ºC)
Mg has greater number of delocailized electron and smaller cations causing stronger metallic bond strength
b) Na (98ºC) > K (63ºC) > Rb (39ºC
decrease down a group as the size of the cation
increases, reducing the attraction between the delocalized electrons and the positive charges

Question 44

Why does transitonal elements have strong metallic bonds?

Answer 44

e large number of
electrons that can become delocalized, from both 3d and 4s sub-shells

Question 45

What are the physical properties of metallic bonding

Answer 45

Question 46

Alloyes

Answer 46

• Contain more than one metal and have enhanced peroperties
• Alloys have non-directional nature of the delocalized electrons, and the lattice can accommodate ions of different size, harder for positive ions to slide ove each other preventing bending
• Alloys are often more chemically stable, stronger and more resistant to corrosion

Question 47

Name the components to steel, stainless steel, brass and bronze

Answer 47

Question 48

sigma bond (σ)

Answer 48

direct head-on/end-to-end overlap of atomic orbitals, resulting in electron density concentrated between the nuclei of the bonding atom

Question 49

pi bonds

Answer 49

sideways overlap of atomic orbitals, resulting in electron density above and below the plane of the nuclei of the bonding atom

Question 50

Exceptions to the octect rule

Answer 50

-small atoms like Be and B form stable molecules with fewer than an octet of
electrons.
- atoms of elements in Period 3 and below may expand their octet by using d
orbitals in their valence shel

Question 51

Hydridization

Answer 51

mixing atomic orbitals to form new hybrid atomic orbitals of intermediate enrgy

Question 52

1)Describe the hydrization of carbon
2)draw the hydrization electron configuration

Answer 52

A) Ecitation occurs in which an electron is promoted within the atom from the 2s orbital to the vacant 2p orbital. The atom now has four singly occupied electrons for bonding

Question 53

SP3

Answer 53

• four hydrization between 1 s and 3 p oribtals
• forms four single bond
• 109.5 tetrahedra
• makes four sigma bonds

Double covalent bonds contain
one sigma bond and one pi bond.  Triple covalent bonds contain one sigma bond and two pi bonds.

Question 54

Sp2

Answer 54

• three hydridization between one s and 2 p electrons, one unhydrizied p oribtal
• 120 triangular planar
• 1 pi bond one sigma bonds
• shown in double bonds

Double covalent bonds contain
one sigma bond and one pi bond.  Triple covalent bonds contain one sigma bond and two pi bonds.

Question 55

SP

Answer 55

• two unhydridized p orbital, two sp hybrizied oritals
• 180 linear shape
• triple bonds
• two sigma bonds, 2 pi bonds

Question 56

Kienetic energy formula of ionix compound

Question 57

Describe the physical properties and bonding strucure of diamond, graphite, graphene and fullerene.

Answer 57

Question 58

Fill out the bond angles

Answer 58

Question 59

Explain the structure, electrical/thermal conductivity and physical properties of diamond

Answer 59

• Each C atom is sp3 hybrizied and covalently bonded to 4 other tetrhedrally arranged in a regular repetitive pattern with bond angels of 109.5
• no conductor as there are no delocalied eletrons as it is used for covalent bonds
• good thermal conductor
• hardest, and high melting point
• used for jewllery and cutting glass

Question 60

Explain the structure, electrical/thermal conductivity and physical properties of fullerene

Answer 60

• C atom in sp2 hybridized and bondded in a sphere of 60 carbons (12pent, 20 hex) bonded to 3 other carbons (no fixed formula)
• poor electrical conductor as molecules have delocalized electrons, there is little electrons movement between molecules
• low thermal conductivity
• light and strong, makes reacts with K to make superconducting crystalline material with low melting point
• used for medical field and nanotubes

Question 61

Explain the structure, electrical/thermal conductivity and physical properties of graphite

Answer 61

• each C atoms is sp2 hybrized and covaently bonded to 3 others forming hexagons with parrallel layers with bonded angle of 120. the valence electrons is delocalized and moves freely across the later. The layers london dispersion force allowing to slide over each other
• The covalent bonds within the layers are very strong, the LDF is weak between laters
• good conductor of electricity
• bad therm conductor as long as heat can be forced to conduct in a direction parrallel to the crystal later
• soft and slipperly, brittle, high melting point
• pencils, lubricants

Question 62

Explain the structure, electrical/thermal conductivity and physical properties of graphene

Answer 62

• Each C atoms is sp2 hybridized and covalently bonded to 3 other as graphite, forming hexagons with bond angles of 120 in single layer.
• good electrical conductor due to delocalized, mobile electrons
• best thermal conductivity
• strongest, flexible, high melting point
• electronic devices, TEM

Question 63

why are metallic bonds mealiable

Answer 63

metallic bonds are non-directional. layer of cation can slide over each other and change shape without dirupting bonding