Molecular Compounds Molecular Compounds Molecular Formulas [PDF]

Molecular Compounds John W. Moore Conrad L. Stanitski Peter C. Jurs

• Contain 2 or more elements.

http://academic.cengage.com/chemistry/moore

• Form when nonnon-metals combine.

• Nanoscale: a discrete molecule.

Molecular formula • shows the number and kind of elements used

Chapter 3 Chemical Compounds

e.g.

water benzene

H2O C6H6

ammonia NH3

Stephen C. Foster • Mississippi State University

Molecular Compounds

Molecular Formulas

Inorganic compounds

Ethanol has the formula C2H6O …

• Do not contain C or (C and H). water H2O

carbon dioxide

• Doesn’t show atom connections.

ammonia NH3

CO2

• A structural formula does.

C2H6O may not be ethanol.

Organic compounds • always contain C, usually H • may contain many other elements. e.g. benzene C6H6 ethanol • most (but not all) are molecular.

Molecular Formulas Condensed formula Similar information in a compact form.

• Two C2H6O structural formulas:

C2H6O

H H | | H–C–C–O–H | | H H

ethanol

H H | | H–C–O–C–H | | H H

dimethyl ether

Molecular Formulas More elaborate models:

C, what’s attached to it, C … CH3CH2OH ethanol

CH3OCH3 dimethyl ether

Groups of atoms attached to C (like OH) are called functional groups • –OH is the alcohol group.

Ball-and-stick model

Space-filling model

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Naming Binary Inorganic Compounds

Naming Binary Inorganic Compounds

Binary compounds contain two different elements. elements

Not monooxide, the

CO NO2 N2O P2O5 PBr3 PBr5 SF6 P4O10

• Name the elements in formula order • Prefixes show the number of atoms present.  but don’t use “mono” for the first element

1

mono

6

hexa

2

di

7

hepta

3

tri

8

octa

4

tetra

9

nona

5

penta

10

deca

extra vowel is carbon monoxide dropped to make it sound better nitrogen dioxide dinitrogen monoxide Not pentaoxide diphosphorus pentoxide phosphorus tribromide phosphorus pentabromide sulfur hexafluoride Not decaoxide tetraphosphorus decoxide

• Change the 2nd element’s name to end in “--ide” ide

Naming Binary Inorganic Compounds

Hydrocarbons

Exceptions to these rules:

Binary molecules (C and H) are known as hydrocarbons.

Hydrogen plus a group 6A or 7A element: • All prefixes are omitted

HCl H2S HF

Alkanes are hydrocarbons with C-C single bonds only.

hydrogen chloride hydrogen sulfide hydrogen fluoride

• Use an –ane ending. • They exist as linear and branched molecules

Common names in wide-spread use: H2O water NO nitric oxide NH3 ammonia N2O nitrous oxide PH3 phosphine N2H4 hydrazine

 formula CnH2n+2

Butane, C4H10

Hydrocarbons H H

C

H

H

methane

H

H

H

C

C

H

H

H

ethane

Hydrocarbons H

H

H

H

C

C

C

H

H

H

H

propane

H

H

H

H

C

C

C

H C

H

H

H

H

H

# of C prefix

1 meth

2 eth

3 prop

4 but

5 pent

6 hex

7 hept

8 oct

butane Similar to molecular compound prefixes

C8H18 = octane C5H12 = pentane Boiling points (°C) -162 -89

-42

-1

Larger mass = higher b.p.

2

Hydrocarbons

Alkanes and Their Isomers

LineLine-angle structures

Branched alkanes occur.

• Lines represent C-C bonds.

Isomer: Isomer same formula, different atom arrangement.

• Each junction and end is a C • Each C needs 4 bonds. • C–H bonds are omitted ethane

H H | | H―C―C― H | | H H

propane

H H H | | | H―C―C―C― H | | | H H H

C with 3H (missing 3 bonds)

becomes

C4H10

C with 2 H (missing 2 bonds)

Alkanes and Their Isomers Formula

methylpropane

|

CH3CHCH3

isopropyl

isomers

becomes

Alkyl groups • An alkane with a H atom removed. • Named by replacing “-ane” with “-yl” methyl ethyl propyl

methylpropane H H H | | | H ―C―C―C― H Ι Ι H H H C H | H

C4H10

Alkanes and Their Isomers

-CH3 -CH2CH3 -CH2CH2CH3

butane H H H H | | | | H ―C―C―C―C― H | | | | H H H H

H H H | | | H―C―C―C― H Ι Ι H H H C H | H a methyl group

Ions and Ionic Compounds Ions - charged units - formed by transfer of e- between elements. Cation = positive ion. Metals form cations Na Na+ + e-

Anion = negative ion. Nonmetals form anions S + 2 eS2-

Isomers

Formula

Isomers

C6H14

CH4

1

C9H20

35

C2H6

1

C10H22

75

C3H8

1

C4H10

2

C12H26

355

C5H12

3

C15H32

4,347

C6H14

5

C20H42

366,319

C7H16

9

C30H62

4.1 x 109

C8H18

18

C40H82

6.3 x 1013

Monatomic Ions Main group elements Add/lose enough e- to “get to” the nearest noble gas. • Charge on ion = group A# or (8-grpA#) • Number of e- transferred = charge S Na P Sr

→ → → →

S2Na+ P3Sr2+

16 e11 e15 e38 e-

→ → → →

18 e10 e18 e36 e-

(like Ar) (like Ne) (like Ar) (like Kr)

3

Monatomic Ions

Monatomic Ions

Transition metals: metals • lose varying number of e-. • old (and new) group number not very helpful. Ti2+ Cr2+ Fe2+ Cu+ Mn2+

Ti Cr Fe Cu Mn

(grp 4B) (grp 6B) (grp 8B) (grp 1B) (grp 7B)

Cr3+

or or Fe3+ or Cu2+ Mn5+ or Mn7+

Polyatomic Ions

Ionic Compounds

Multiple atom “units” with a net electrical charge. NH4+

ammonium ion

OH-

hydroxide ion

SO42-

sulfate ion

Common monatomic ions:

Ions are held together by electrostatic forces. • Cations (+) and anions (–) attract each other. • Larger charges = larger attraction. • Larger separation = lower attraction. • Coulomb’s law:

CN-

cyanide ion

Force between ions

QQ F = k 12 2 d constant

Distance between ions

Memorize all the ions in table 3.7!

Ionic Compounds

Q1 = charge on ion 1, Q2 = …

Naming Ions and Ionic Compounds

Charges are always balanced.

Positive ions Most are metal ions (exception: ammonium NH4+ ).

Ionic compounds are always neutral!

• metal ion with only one charge state? • Use metal name + ion. ion

Ions

Compound

Mg2+ and FMg2+ Mg2+

Charges

MgF2

(2+) + 2(1-) = 0

and SO4

2-

MgSO4

(2+) + (2-) = 0

and PO4

3-

Mg3(PO4)2

3(2+) + 2(3-) = 0

• metal ion with multiple charge states? • Use metal name + (Roman numeral) to show charge.

Na+ sodium ion Fe2+ iron(II) ion

Ca2+ calcium ion Fe3+ iron(III) ion

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Naming Ions and Ionic Compounds

Two forms exist: –ate and –ite endings used.  More oxygen = “-ate”  Less oxygen = “-ite”

Negative ions • Monatomic ion?

Increase O

• Add “--ide ide” to the name stem.

• Polyatomic ion? • Memorize these.

P S

phosphorus sulfur

Oxoanions

P3S2SO32-

phosphide ion sulfide ion sulfite ion

Oxoanions

SO42- sulfate ion

NO3- nitrate ion

SO32- sulfite ion

NO2- nitrite ion

If they contain H, add a prefix “hydrogen” HSO4- hydrogen sulfate ion (common name=bisulfate ion)

HCO3- hydrogen carbonate ion (common name=bicarbonate ion)

Naming Ionic Compounds

When four forms exist  Add “per_____ate per_____ate” and “hypo____ite hypo____ite” names

Name the ions and add together… … cation then anion (drop “ion” from both)

Increase O

Single charge metalmetal-ion examples FO4

-

FO3

-

perfluorate fluorate

-

ClO4 perchlorate -

ClO3 chlorate

FO2- fluorite

ClO2- chlorite

FO-

ClO- hypochlorite

hypofluorite

Naming Ionic Compounds iron(II) chloride

FeCl3

iron(III) chloride

sodium chloride

KHSO4

potassium hydrogen sulfate

SrO Mg(OH)2

strontium oxide

KMnO4

potassium permanganate

magnesium carbonate

magnesium hydroxide

Naming Ionic Compounds

Multiple charge examples FeCl2

NaCl MgCO3

When are Roman numerals used? • Main block metals form one type of ion:  omit Roman numerals.  exceptions: exceptions lead (Pb2+, Pb4+), tin (Sn2+, Sn4+)…

Cu2O

copper(I) oxide

CuO

copper(II) oxide

• Transition metals form multiple ions  use Roman numerals.  exceptions: exceptions silver (Ag+), zinc (Zn2+), cadmium

Cu2O

CuO

(Cd2+)…

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Naming Compounds

Naming Compounds

Generalizations Metallic element in a formula? … the compound is usually ionic. All non-metal formula? … the compound is usually molecular. Metalloid in a formula? … no easy way to tell if ionic or molecular.

Naming Compounds

sulfur trioxide

CuSO4

copper(II) sulfate

AlCl3

aluminum chloride

AgF

silver fluoride

SF6

sulfur hexafluoride

PbO2

lead(IV) oxide

Bonding and Properties of Ionic Compounds

sodium hypochlorite

NaClO

dinitrogen pentoxide

N2O5

potassium dichromate

K2Cr2O7

ammonium perchlorate

NH4ClO4

hydrogen chloride

HCl

Ionic compounds Not individual molecules. Crystal lattices • Each ion is surrounded by many others

NaCl sodium chloride

Formula unit = smallest ratio of anions to cations

Bonding and Properties of Ionic Compounds Electrostatic forces hold ionic compounds together: F=k

SO3

Bonding and Properties of Ionic Compounds

Ionic crystals can be cleaved:

Q1Q2 d2

External force displaces layers

High melting points  strong forces.  high charge = high m.p.

Repulsion occurs Na+ Cl-

ions

Similar sized ions:

m.p. (°C)

NaF

+1 -1

993

CaO

+2 -2

2572

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Bonding and Properties of Ionic Compounds

Ionic Compounds in Aqueous Solution: Electrolytes

Ionic compounds are electrical insulators when SOLID.

If an ionic compound dissolves in water: water

• will conduct if molten. • It dissociates  breaks apart into its ions.

• It is a strong electrolyte

Many are soluble in water.

 the solution is a good

electrical conductor.

Molecular & Ionic Compounds Property Formation

Molecular Non-metal combinations

Ionic Metal/non-metal combinations

Physical state

Gases, liquids & solids. Brittle & weak or soft & waxy

Crystalline solids Hard & brittle

mp & bp

Low

High

Conductivity

Poor heat & electrical Poor heat & electrical. conductors Good electrical if molten

Solubility

Few soluble in water

Many soluble in water

In solution

Remain molecular

Dissociate

Moles of Compounds A mole of XmYn contains: m moles of atom X and n moles of atom Y 1 mol of H2O contains: 2 mol of H atoms and 1 mol of O atoms Molar mass = sum of the atomic masses

Molar Mass of Ionic Compounds

Mass of 1 water molecule: = 2(1.008 amu) + 1(15.999 amu) = 18.015 amu Molar mass of water: = 2(1.008 g/mol) + 1(15.999 g/mol) = 18.015 g/mol

Gram-Mole Conversions How many moles of Ca3(PO4)2 are in 10.0 g of the compound?

Ionic compounds do not contain molecules. Don’t use “molecular weight” to describe mass.

Formula mass = 3 40.08

Formula weight (or molar mass) should be used

g mol

+ 8 16.00 Compound

atomic wts amu

NaCl

22.99 + 35.45

Ca(NO3)2 40.08+2(14.01)+6(16.00)

Formula wt. amu

Molar mass g/mol

58.44

58.44

164.10

164.10

= 310.18

+ 2 30.97

g mol

g mol

g mol

Moles of Ca3(PO4)2 = 10.0 g

1 mol = 0.0322 mol 310.2 g

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Gram-Mole Conversions

Moles of Ionic Hydrates

Find the mass of cobalt in 3.49 g of cobalt(II) sulfate.

Ionic hydrate: ionic compound with water trapped in the crystal. • the water of hydration. • use “hydrate” with a Greek prefix for the number. • heat can remove some, or all, of this water.

Formula wt CoSO4 = 58.93 + 32.07 + 4(16.00) = 155.00 g 3.49 g CoSO4

1 mol CoSO4 1 Co 155.0 g CoSO4 1 CoSO4 = 0.02252 mol Co

0.02252 mol Co

58.93 g Co 1 mol Co

= 1.33 g Co

Percent Composition

Examples MgSO4•7H2O magnesium sulfate heptahydrate (Epsom salt). CuSO4•5H2O copper(II) sulfate pentahydrate.

Percent Composition

Two names used: • percent composition by mass, mass or

%Na =

• mass percent of the compound.

Example What is the mass percent of each element in sodium chlorite, NaClO2? molar mass = (22.990 g) + (35.453 g) + 2(15.999 g) = 90.441 g

Percent Composition %Cl =

mass of Cl … x 100 % mass of NaClO2 …

= 35.453 g x 100 % = 39.20% 90.441 g

mass of Na in 1 mol NaClO2 x 100 % mass of NaClO2 in 1 mol NaClO2 = 22.990 g x 100 % = 25.42% 90.441 g

%O =

mass of O … x 100 % mass of NaClO2 … = 2(15.999) g x 100 % = 35.38% 90.441 g

Determining Empirical and Molecular Formulas Last example: molecular formula

percent composition

The process can be reversed: percent composition empirical formula Not molecular formula

Check your work: %Na + %O + %Cl = 25.42 + 35.38 + 39.20 = 100%

Empirical formula = the simplest ratio of atoms in a compound.

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Determining Empirical and Molecular Formulas Examples Compound

mol. formula

emp. formula

Determining Empirical and Molecular Formulas Example An orange compound was 26.6% K, 35.4% Cr and 38.0% O. Determine its empirical formula.

hydrogen peroxide

H2 O 2

HO

borane (boron trihydride)

BH3

BH3

diborane (diboron hexahydride)

B2H6

BH3

octene

C8H16

CH2

• Divide each mass by its atomic mass.  Gives the number of moles of each (in 100 g).

butene

C4 H8

CH2

• Divide each by the smallest answer found.

• Assume a 100.0 g sample.  % becomes mass in grams

 The smallest integer ratio = empirical formula.

Determining Empirical and Molecular Formulas Unknown: 26.6% K

35.4% Cr

38.0% O

Determining Empirical and Molecular Formulas Empirical formula = smallest integer ratio. Divide by the smallest value (ratios stay the same!)

In 100.0 g 26.6 g K

35.4 g Cr

38.0 g O

1 mol K 39.10 g K

= 0.6803 mol K

1 mol Cr 52.00 g Cr

= 0.6808 mol Cr

1 mol O 16.00 g O

= 2.375 mol O

K

0.6803 mol = 1.000 0.6803 mol

x2

2

Cr

0.6808 mol = 1.001 0.6803 mol

x2

2

O

2.375 mol = 3.491 0.6803 mol

x2

7

Choose a multiplier to make integer

Determining Empirical and Molecular Formulas The molecular formula can be determined if the molecular mass is known. Example Vitamin C has the empirical formula C3H4O3 and molecular mass = 175 g/mol.

The empirical formula is K2Cr2O7

The Biological Periodic Table Element in the body

Symbol

Abundance atoms/106 atoms

Hydrogen

H

630,000

Oxygen

O

255,000

Carbon

C

94,500

Nitrogen

N

13,500

Calcium

Ca

3,100

Phosphorus

P

2,200

Empirical mass: 3(12.01) + 4(1.008) + 3(15.99) = 88.03 g/mol

Chlorine

Cl

570

Sulfur

S

490

Na

410

Empirical mass ≈ ½(molecular mass) Mol. formula = 2(emp. formula) = C6H8O6

Potassium

K

260

Magnesium

Mg

130

Sodium

98.0% 99.3%

0.7%

9

The Biological Periodic Table

10