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Hydrogen, Oxygen and Water

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Main Group Oxides 1 2 13 14 15 16 17 Li2O BeO B2O3 CO2 N2O5 Na2O MgO Al2O3 SiO2 P4O10 SO3 Cl2O7 K2O CaO Ga2O3 GeO2 As2O5 SeO3 Br2O5 ... cracking in the cooling system. – PowerPoint PPT presentation

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Title: Hydrogen, Oxygen and Water


1
Hydrogen, Oxygen and Water
  • Chapter 18

2
Hydrogen Chemistry
  • Hydrogen Greek- hydro-water and genes-forming
  • 11.0079H
  • The lightest element and has only proton and one
    electron and it has no neutron.
  • All other elements were originally made from
    hydrogen atoms or other elements that were
    originally made from hydrogen atoms.

3
Hydrogen History
  • 1671 - Robert Boyle dissolved iron fillings in
    dilute hydrochloric acid and reported that the
    fumes given off were highly flammable.
  • 1766 - Discovered and isolated by Henry Cavendish
    in 1766. 1781-H2O2 ED ? H2O
  • 1781 Named Hydrogen by Antoine Lavoisier.
  • 1789- van Troostwijk Deiman-Electrolysis of
    water-
  • 1898 - James Dewar produced the first liquid
    hydrogen.
  • 1900 - the first Zeppelin Airship made its
    flight filled with hydrogen.
  • 1909-The pH scale by P. L. Sørensen
  • 1923-J. N. Brønsted defined an acid as a proton
    donor.
  • 1931 - Harold Urey discovered deuterium.
  • 1947-LiAlH4 prepared by H. I. Schlesinger-Chicago
    University
  • 1954-Detonation of H-Bomb on Bikini Atoll
  • 1960s Super acid (BF3-HF)G. A. Olah.. Nobel 1994
  • 1978- H. C. Brown Nobel Prize, Purdue University,
    Hydroboration
  • 1984-First Stable T.M. dihydrogen compound
    discoved by G. Kubas
  • 1996 - Metallic hydrogen was prepared

Hindenburg 1937
H-Bomb 1952
1900-1930s German war machine
1891 water splitting Poul la Cour -Danish
4
Why Hydrogen?
Hydrogen is a Part of Life
H2O , NH3, MeOH .
The first hydrogen refueling station Reykjavík,
Iceland in April 2003. DaimlerChrysler fuel cell
buses went into public use in nine cities
across the European Union in 2004.
Hydrogen Economy
5
Some Uses Hydrogen
  • Selected uses of hydrogen
  • Food ... to hydrogenate liquid oils (e.g.
    soybean, fish, cottonseed and corn) converting
    them to semisolid materials such as shortenings,
    margarine and peanut butter.
  • Chemical processing ... primarily to manufacture
    ammonia (nitrogen fixation), hydrochloric acid
    and methanol, but also to hydrogenate non-edible
    oils for soaps, insulation, plastics, ointments
    and other specialty chemicals.
  • Metal production and fabrication ... to serve as
    a protective atmosphere in high-temperature
    operations such as stainless steel manufacturing
    commonly mixed with argon for welding austenitic
    stainless. Also used to support plasma welding
    and cutting operations.
  • Pharmaceuticals ... to produce sorbitol (sugar
    alcohol) used in cosmetics, adhesives,
    surfactants, and vitamins A and C.
  • Aerospace ... to fuel spacecraft, but also to
    power life-support systems and computers,
    yielding drinkable water as a by-product.
  • Electronics ... to create specially controlled
    atmospheres in the production of semiconductor
    circuits.
  • Petroleum Recovery and Refinery ... to enhance
    performance of petroleum products by removing
    organic sulfur from crude oil, as well as to
    convert heavy crude to lighter, easier to refine,
    and more marketable products. Hydrogen's use in
    reformulated gas products helps refiners meet
    Clean Air Act requirements.
  • Power Generation ... to serve as a heat transfer
    medium for cooling high speed turbine generators.
    Also used to react with oxygen in the cooling
    water system of boiling water nuclear reactors to
    suppress stress corrosion cracking in the cooling
    system.
  • Fuel Cells ... used as a fuel to power fuel cell
    generators that create electricity through an
    electrochemical process in combination with
    oxygen.

6
Occurrence
  • Hydrogen (hydrogen atoms) is the most abundant
    element in the universe (90 of all atoms and ¾
    of total mass), followed by Helium.
  • Hydrogen is found in the stars and plays an
    important role in powering the Universe through
    interstellar proton-proton reaction and
    carbon-nitrogen cycle.
  • 41H?4He 2e 2ne Q 26.72 MeV _at_ T
    gt 107K
  • QEnergy evolved
  • (?e is neutrino)
  • 41H 12C?4He 12C 2e 2ne Q 26.72 MeV
    _at_ T gt1.6x107
  • Hydrogen is the third (after oxygen and silicon)
    most abundant element in earth.
  • Despite its simplicity and abundance, hydrogen
    doesn't occur naturally as a gas on the
    Earthit's always combined with other elements.

7
Hydrogen
  • 11.0079H Nuclear spin ½
  • Electron Spin ½
  • Electronic configuration
  • 1s1 (H.)
  • 1s1 - e- ? 1s0 (H)
  • 1s1 e- ? 1s2 (H-)

8
Location in the Periodic Table
1 2 2 17 18
11.008H 1s1 ? ? 11.008H 1s1 2He 1s2
3Li .2s1 4Be 9F 2s22p7 10Ne 2s2sp6
11Na.3s1 12Mg 17Cl
19K. 4s1 20Ca 35Br
37Rb 5s1 38Sr 53I
55Cs 6s1 56Ba 85At
87Fr 7s1 88Ra
9
Summary
  • Despite its position on top of Group I, it is not
    really part of this group
  • It is a gas and not a metal.
  • It does not react with water.
  • Far more electronegative than the alkali
  • Electronegativity is the tendency of an atom in a
    molecule to attract electrons.
  • Electronegativity is useful in predicting the
    general chemical behavior of an element.
  • In general large difference in electronegativity
    between two elements leads to the formation of
    ions and small difference in electronegativity
    leads to sharing of electrons.

Selected Electronegativities (Pauling Scale) Selected Electronegativities (Pauling Scale)
F 4.0
Cl 3.0
O 3.5
N 3.0
S 2.5
C 2.5
H 2.1
B 2.0
Na 0.9
10
Nuclear Properties Hydorgen Isotopes Nuclear Properties Hydorgen Isotopes Nuclear Properties Hydorgen Isotopes Nuclear Properties Hydorgen Isotopes Nuclear Properties Hydorgen Isotopes Nuclear Properties Hydorgen Isotopes
Isotope Symbol Natural Abundance, ½-life Nuclear Spin NMR Sensitivity
Protium 1H 99.985 Stable ½ 1.000
Deuterium, 12H, D 0.01 Stable 1 0.0097
Tritium 13H, T 10-17 Radio-active b-emitter 12.4 year 1/2 1.21
Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e Have the largest isotope effect of all elements because of the largest mass differences. The dominant isotope. Natural hydrogen contains 0.002 D. b-radiation ? 0-1e
11
Isotope Effects Hydorgen Isotopes Isotope Effects Hydorgen Isotopes Isotope Effects Hydorgen Isotopes Isotope Effects Hydorgen Isotopes Isotope Effects Hydorgen Isotopes Isotope Effects Hydorgen Isotopes
Isotope H2 D2 H2O D2O
Boiling point/oC -252.81 -249.7 100.00 101.42
Mean Bond Enthalpy (kJmol-1) 436.0 443.3 463.5 470.9

See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes. See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes. See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes. See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes. See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes. See Deuterium and Tritium Isotopes synthesis and applications. Major used in spectroscopy as tracers to confirm the presence or absence of certain isotopes.
12
Preparation of Hydrogen
  • Reaction of electropositive metals with water
  • e.g.
  • 2 Na 2 H2O ? H2 2 Na 2 OH-
  • Ca 2 H2O? H2 Ca2 2 OH-
  • In the lab reaction of Fe or Zn with acids
  • Zn 2 H3O ? H2 Zn2 2 H2O

13
Preparation of Hydrogen
  • Electrolysis-
  • 2H2O (l) es ? 2H2(g) O2(g) on
    inert electrode, e.g. Pt electrode
  • Write balance half-reactions for the electrolysis
    of water?
  • Show balanced half-reactions for the electrolysis
    of water.
  • 2NaCl(l) 2Hg es ? 2NaHg(l) Cl2(g)
  • 2NaHg (l) H2O(l) ? 2H2(g) 2Hg(l)

14
Reactions of Molecular Hydrogen (H2)
  • Reaction with O2
  • H2(g) O2(g) ? N.R
  • 2H2(g) O2(g) ED ? 2H2O(l)
  • Reaction with H2O
  • H2(g) H2O(l) ? N.R.
  • Reaction with Halogens
  • H2(g) F2(g) ? 2HF(g)
  • Reaction with acids
  • H2(g) H(l) ? N.R.
  • Reaction with bases
  • H2(g) OH-(l) ? N.R.

15
Hydrides
  • Ionic (saltlike) hydrides
  • when hydrogen combines with very active metals
    from Group I or Group II
  • the hydride ion (H-) is a strong reducing agent
  • ionic hydrides react violently in water
  • LiH H2O --gt H2 Li OH-
  • Covalent hydrides
  • when hydrogen combines with other nonmetals, e.g.
    in HCl, NH3, CH4, and H2O

16
Hydrides
  • Metallic hydrides
  • formed when transition metal crystals are treated
    with hydrogen gas
  • the hydrogen atoms migrate into the crystal
    structure to occupy holes or interstices
  • a solid solution is formed
  • when these interstitial hydrides are heated, H2
    gas is released
  • use these intersitial hydrides for hydrogen gas
    storage

17
Covalent Hydrides
  • The electrons in the bond are shared between M
    H.
  • The electronegativity of the element 2.1 and
    varies from 2.5-1.5.
  • Bond polarity depends on electronegativity
    differences between M H and varies from d (e.g.
    S-H) to d- (e.g. B-H and Ga-H)

Electronegativity Electronegativity
H 2.1
P 2.2
S 2.5
18
Hydrides
1 2 13 14 15 16 17
LiH BeH2 (BH3)2, . CH4 NH3 H2O HF
NaH MgH2 (AlH3)n SnH4 PH3 H2S HCl
KH CaH2 GaH3 GeH4 AsH3 H2Se HBr
RbH SrH2 InH3 SnH4 SbH3 H2Te HI
Ionic Hydrides EH- Ionic EdHd- Covalent E-H Covalent HdEd-
Red Blue White
19
Selected hydrides of p-block elements that contain M-H covalent Bonds, Selected hydrides of p-block elements that contain M-H covalent Bonds, Selected hydrides of p-block elements that contain M-H covalent Bonds, Selected hydrides of p-block elements that contain M-H covalent Bonds, Selected hydrides of p-block elements that contain M-H covalent Bonds,
13 14 15 16 17
B2H6 CnH2n2 NH3 H2O HF
CnH2n
CnH2n-2
(AlH3)n SinH2n2 (n ? 8) PH3 H2S HCl
P2H4 H2Sn
GenH2n2 (n ? 9) AsH3 H2Se HBr
SnH4 SbH3 H2Te HI
Polarity varies depending on electronegativity differences of M-H bond. Group 13 hydrides are electron deficient- Polarity varies depending on electronegativity differences of M-H bond. Group 13 hydrides are electron deficient- Polarity varies depending on electronegativity differences of M-H bond. Group 13 hydrides are electron deficient- Polarity varies depending on electronegativity differences of M-H bond. Group 13 hydrides are electron deficient-

20
Reaction of Ionic Hydrides with water
21
Oxygen Chemistry
  • Oxygen Greek-oxus or oxys (sharp, acid) and
    geinomai or genes (former)-acid former
  • 815.9994O 1s22s22p4
  • The most abundant element in the universe and has
    eight proton, eight electron and eight neutron.
  • Oxygen is an important component of air, produced
    by plants during photosynthesis and is necessary
    for aerobic respiration in animals.

22
History
  • lt1771- prepared by many individuals but were not
    able to isolate it or recognize it as an element.
  • In 1770, G.E. Stahl, a German physician - all
    inflammable objects contained a material
    substance that he called "phlogiston," from a
    Greek word meaning "to set on fire."
  • 1771 Carl Wilhelm Scheele (Swedish pharmacist)
    discovered Oxygen called it fire air was not
    immediately recognized.
  • 1772 - Joseph Black (Scottish chemist), and his
    student, Daniel Rutherford- a living creature
    gives up phlogiston while breathing and when
    placed in air that is already saturated with
    phlogiston, can no longer breathe and must die.
  • 1774 Joseph Priestley independent discovery
    confirmed oxygen.
  • 1774 Antoine Laurent Lavoisier oxygen.
  • 1848 - Faraday while he was investigating the
    magnetic susceptibility of matter, he discovered
    that oxygen could be drawn into a magnetic field
    (paramagnetic).
  • 1950 - Paul Hersch developed electrochemical
    oxygen sensor. 
  • Scheele Joseph Priestley Antoine L.
    Lavoisier Benjamin Franklin
    Cartoon of Priestley calling for the head
  • Radical Thinker wife
    Marie-Ann Paulze
  • (Through a conscious revolution, became the
    father of modern chemistry) of King George III.
  • (Law degree at the Collège Mazarin)

23
Why Oxygen?
  • Oxygen is a part of life - supports all life on
    this planet and is essential to combustion as
    well as respiration
  • Photosynthesis Respiration Agriculture Environmen
    t
  • Chemicals, H2O2 Zeolites

Electronegativity
Electronegativity
24
Oxides
  • Binary Oxygen compounds are generally referred
    to as
  • oxides
  • With metals the compounds may be
  • (a) oxides O2- - oxidation number (2)
  • (b) peroxides O22- - oxidation number (1)
  • (c) superoxides O2- - oxidation number (- ½ )
  • Oxides may be acidic, basic, neutral or
    Amphoteric

25
Selected Uses of Oxygen
  • Essential for many important industrial and
    biological processes that may include
  • Oxidizer (only fluorine having a higher
    electronegativity) used in rocket propulsion and
    manufacturing disinfectant, pharmaceuticals,
    etc.
  • Medicine Biological life support- Respiration -
    oxygen supplementation, gas poisoning, and
    anesthetic when mixed with nitrous oxide, ether
    vapor, etc..
  • Oxygen is essential for life takes part in
    processes of combustion respiration.
  • Oxygen is used in welding.
  • Metalloragy- melting, mining, refining and
    manufacture of steel, other metals and
    manufacture of stone and glass products.
  • Recreational - mild euphoric, has a history of
    recreational use often mixed with nitrous oxide
    to promote a kind of analgesic effect.
  • Manufacture of chemicals by controlled oxidation

26
Occurrence
  • Oxygen is the most abundant element in the
    Universe originated by green-plant
    photosynthesis.
  • chlorophyl/enzyme
  • H2O CO2 hv ? O2 CH2O DH /-
    469 kJmol-1
  • Oxygen comprises about 46.7 of earths crust,
    87 by weight of the oceans (as H2O) and 20 of
    the atmosphere of Earth (as O2, molecular oxygen,
    or O3, ozone).
  • Oxygen compounds, particularly metal oxides,
    silicates (SiO44-), and carbonates (CO32-), are
    commonly found in rocks and soil.
  • Frozen water is a common solid on the outer
    planets and comets. The ice caps of Mars are made
    of frozen carbon dioxide.
  • Oxygen compounds are found throughout the
    universe and the spectrum of oxygen is often seen
    in stars (see carbon-nitrogen-oxygen cycle in
    1H-1H fusion.

27
Forms of oxygen
  • Molecular O2, O3 and O4 (allotropes)
  • Atomic- highly reactive
  • Ionic- oxides O2-, peroxides O22-, superoxides
    O2-, . (see group I and II oxides).
  • Molecular (covalent) compound of oxygen neutral
    (e.g. SiO2, OsO4, CO2..) ionic (e.g. SO42-,
    CO32-, NO3-, )

28
Molecular oxygen
  • Oxygen is a colorless, odorless gas and at
    standard pressure, oxygen liquefies to a pale
    blue liquid which boils at -183.0 ºC. Solid
    oxygen melts at -218.8 ºC. Oxygen is sparingly
    soluble in water slightly heavier than air.
  • Liquid O2

29
Chemical Synthesis of O2
  • From water
  • Electrolysis (see synthesis of hydrogen).
  • Chemical oxidation of water
  • 2H2O 2Cl2 ? 4HCl O2
  • From oxides
  • Thermal decomposition
  • e.g. 2HgO ? 2Hg O2
  • 2BaO2 ? 2 BaO O2
  • 2KMnO4 ? K2MnO4 MnO2 O2
  • chemical decomposition
  • e.g. MnO2 2H2SO4 ? 2MnSO4 2H2O O2
  • Catalytic decomposition of peroxides

30
Industrial Production
  • Fractional distillation of liquefied air _at_-183 C
    (O2) and _at_ -196 C .

Air
Gas Volume
N2 78.1
O2 20.9
Ar 0.93
CO2 0.035
31
O2 Haemoglobin
  • Active site metalloprophyrin

32
Di-oxygen metal compounds
  • Metal-dioxygen compounds
  • http//www.res.titech.ac.jp/smart/research/subjec
    t(e).html
  • http//www.iuac.org/publications/pac/1995/pdf/670
    2x0241.pdf

33
Main Group Oxides Ionic vs Covalent
  • With the exception of a few Nobel gas elements
    such as Xe, oxygen forms oxides with all elements
    in the periodic table.
  • If D Electronegativity gt 1.5
  • the oxide is ionic.
  • If D Electronegativity lt 1.5
  • the oxide is covalent.

Selected Electronegativities (Pauling Scale) Selected Electronegativities (Pauling Scale)
F 4.0
Cl 3.0
O 3.5
N 3.0
S 2.5
C 2.5
H 2.1
B 2.0
Na 0.9
34
Main Group Oxides
Increasing covalent acidic character
1 2 13 14 15 16 17
Li2O BeO B2O3 CO2 N2O5
Na2O MgO Al2O3 SiO2 P4O10 SO3 Cl2O7
K2O CaO Ga2O3 GeO2 As2O5 SeO3 Br2O5
Rb2O SrO In2O3 SnO2 Sb2O5 TeO3 I2O5
Cs2O BaO2 Th2O3 PbO2 Bi2O5
Ionic Basic Amphtoeric Covalent Acidic
Red Blue White
Increasing ionic basic character
35
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36
Hydrolysis of goup I II oxides
  • M2O H2O ? 2M 2OH- oxides (O2-)
  • M2O2 2H2O ? 2M 2OH- H2O2
  • peroxide (O22-)
  • 2MO2 2H2O ? O2 2M 2OH- H2O2
  • superoxide (O2-1)
  • M Group I metal in this case

37
Reaction of Oxides and Superoxides with water
38
Hydrogen Peroxides
  • Why Hydrogen Peroxide?

39
Selected Uses of Hydrogen Peroxides
  • Multipurpose Disinfectant - Kills mold, mildew,
    fungi, viruses, bacteria and other harmful
    biological contaminants.
  • Health toothpaste, mouthwash, shower, facial
  • Agriculture - Sprouting Seeds, House and Garden
    Plants, Vegetable Soak
  • Powerful Oxidizer for a variety of organic and
    inorganic compounds 
  • "green" bleaching agents for the paper and
    textile industries.
  • Wastewater treatment.
  • Hydrometallurgical processes (for example, the
    extraction of uranium by oxidation)
  • Bleaching agent - paper, textile, teeth and hair

40
Synthesis of Hydrogen Peroxides
  • Hydrolysis of Group I and II peroxides
  • e.g. BaO2 2H2O ? H2O2 Ba(OH)2
  • Nature photolysis acid-base conversion of O3
  • O3 H2O ? H2O2 O2 hn
  • O3 HO- ? HO2- O2 _at_ high pH
  • HO2- H2O ? H2O2 HO-
  • Electrolysis aqueous solutions of sulfuric
    acids, of potassium bisulfate, or of ammonium
    bisulfate
  • 2HSO4-(aq) -2e- ? HSO3OOSO3H
  • HSO3OOSO3H H2O ? 2HSO4- H2O2
  • Describe the synthesis of D2O2.

41
Reactions of Hydrogen Peroxide
  • H2O2 is metastable and decomposes as shown below
  • 2H2O2 ? 2H2O O2 DH0 -98.2 kJmol-1
  • DG0 -119.2 kJmol-1
  • (Heterogeneous (e.g. MnO2, Ag, Au or Pt) and
    homogenous (e.g. OH-, I-, Cu2 or Fe3) enhance
    decomposition)
  • H2O2 ? 2HO. (in cold, dark catalyzed at high
    T and hn)
  • (HO. highly reactive . chain reactions )

42
Determing Formula of Hydrate,x.
  1. Get mass of sample.
  2. Heat sample up to release water.
  3. Get mass again. This will be mass of anhdrous
    salt mass of water is found by subtraction.
  4. From mass of water and anhdrous salt determine
    moles of each.

43
Determining Formula of Hydrate,x.
  • Determine x in Empirical Formula Hydrate. (_CuSO4
    .xH2O)
  • X moles H2O / moles CuSO4
  • Mass H2O (mass H2O/ mass unknown hydrate)100
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