The P-Block Elements (Important Compounds Of Carbon And Silicon)
Some Important Compounds Of Carbon And Silicon
Carbon and Silicon, the first two elements of Group 14, form a wide array of compounds with diverse structures and applications.
Carbon Monoxide ($CO$)
Preparation:
- Incomplete Combustion of Carbon: When carbon or carbon-containing materials burn in a limited supply of oxygen.
- Reaction of Carbon Dioxide with Hot Carbon:
- Dehydration of Formic Acid: Heating formic acid ($HCOOH$) with concentrated sulfuric acid.
$2C(s) + O_2(g) \rightarrow 2CO(g)$
$CO_2(g) + C(s) \xrightarrow{high \ T} 2CO(g)$
$HCOOH(l) \xrightarrow{conc. H_2SO_4, heat} CO(g) + H_2O(l)$
Properties:
- Colorless, odorless, and slightly less dense than air.
- Slightly soluble in water.
- Toxicity: Highly toxic gas, as it binds strongly to hemoglobin in blood, forming carboxyhemoglobin, which prevents oxygen transport.
- Reducing Agent: It is a strong reducing agent, especially at high temperatures, and is used in metallurgy to reduce metal oxides to metals.
- Forms Carbides and Carbonyls: Reacts with many metals to form carbides and with transition metals (like Ni, Fe, Cr) to form metal carbonyls (e.g., $Ni(CO)_4$).
$Fe_2O_3(s) + 3CO(g) \xrightarrow{heat} 2Fe(s) + 3CO_2(g)$
Uses:
- Reducing agent in metallurgy.
- In the synthesis of many organic compounds.
- As a fuel (though its toxicity limits its use).
Carbon Dioxide ($CO_2$)
Preparation:
- Complete Combustion of Carbon: When carbon or carbon-containing materials burn in excess oxygen.
- Reaction of Carbonates/Hydrogencarbonates with Acids:
- Heating Metal Carbonates/Hydrogencarbonates:
$C(s) + O_2(g) \rightarrow CO_2(g)$
$CaCO_3(s) + 2HCl(aq) \rightarrow CaCl_2(aq) + H_2O(l) + CO_2(g)$
$CaCO_3(s) \xrightarrow{heat} CaO(s) + CO_2(g)$
$2NaHCO_3(s) \xrightarrow{heat} Na_2CO_3(s) + H_2O(l) + CO_2(g)$
Properties:
- Colorless gas.
- Odorless.
- Non-toxic, but can cause suffocation in high concentrations.
- Slightly soluble in water, forming carbonic acid ($H_2CO_3$), which dissociates slightly to $H^+$ and $HCO_3^-$.
- Solid $CO_2$ is called dry ice and sublimes at -78.5°C.
- Acts as a mild oxidizing agent.
- Insoluble in water.
Uses:
- Photosynthesis in plants.
- Carbonated beverages.
- Fire extinguishers (as it is denser than air and non-flammable).
- Artificial respiration.
- In solid form (dry ice) as a refrigerant.
- In the Solvay process for making sodium carbonate.
Silicon Dioxide ($SiO_2$)
Formula: Silica.
Occurrence: Abundant in nature as quartz, sand, flint, and in many rocks and minerals.
Structure:
- $SiO_2$ exists in various crystalline forms (e.g., quartz, cristobalite, tridymite) and amorphous forms.
- The basic unit is the silica tetrahedron, where a silicon atom is covalently bonded to four oxygen atoms in a tetrahedral arrangement.
- These tetrahedra share oxygen atoms at their corners to form a three-dimensional network.
Properties:
- Hard, colorless crystalline solid.
- Very high melting point (around 1973 K for quartz) and boiling point (around 2500 K).
- Insoluble in water.
- Chemically inert, except reacts with strong bases (like $NaOH$) and hydrofluoric acid ($HF$).
$SiO_2(s) + 2NaOH(aq) \rightarrow Na_2SiO_3(aq) + H_2O(l)$
$SiO_2(s) + 4HF(aq) \rightarrow SiF_4(g) + 2H_2O(l)$
Uses:
- Manufacture of glass, cement, ceramics.
- Used as a filler in paints, plastics, and rubber.
- Used in semiconductor industry.
- Used in chromatography.
Silicones
Definition: Silicones are synthetic organosilicon polymers containing repeating units of the general formula $[R_2SiO]_n$, where R is an organic group (usually methyl, $-CH_3$).
Structure: They consist of a silicon-oxygen backbone ($–Si–O–Si–O–$) with organic side groups attached to the silicon atoms.
Preparation: Prepared by the hydrolysis of organochlorosilanes (e.g., $R_2SiCl_2$).
Properties:
- Generally resistant to heat and oxidation.
- Chemically inert.
- Good electrical insulators.
- Water repellent (hydrophobic).
Uses:
- Lubricants, greases, sealants.
- Electrical insulation.
- Surgical and medical implants.
- Waterproofing materials.
Silicates
Definition: Silicates are compounds containing silicon and oxygen, typically with various metal cations. They are the most abundant compounds in the Earth's crust.
Structure: The basic unit is the tetrahedral silicate ion $[SiO_4]^{4-}$, where a silicon atom is covalently bonded to four oxygen atoms at the corners of a tetrahedron. These tetrahedra can link together by sharing oxygen atoms in various ways to form different structures:
- Orthosilicates: Single $SiO_4^{4-}$ tetrahedra (e.g., $Zn_2SiO_4$, $Fe_2SiO_4$).
- Disilicates: Formed by sharing one oxygen atom between two tetrahedra, giving the ion $[Si_2O_7]^{6-}$ (e.g., $Ca_2P_2O_7$).
- Chain Silicates (Inosilicates): Formed by sharing two oxygen atoms per tetrahedron, creating linear chains of the type $[SiO_3]^{2-}$ (e.g., $BeSiO_3$, $MgSiO_3$). Can be single chains (pyroxenes) or double chains (amphiboles).
- Ring Silicates (Cyclosilicates): Formed by sharing two oxygen atoms to create rings (e.g., $[Si_3O_9]^{6-}$, $[Si_6O_{18}]^{12-}$). Example: Beryl ($Be_3Al_2Si_6O_{18}$).
- Sheet Silicates (Phyllosilicates): Formed by sharing three oxygen atoms per tetrahedron, creating sheets (e.g., $Si_2O_5^{2-}$). Example: Talc ($Mg_3Si_4O_{10}(OH)_2$), Mica.
- Three-Dimensional Silicates (Tectosilicates): All four oxygen atoms of each tetrahedron are shared, forming a 3D network. Example: Quartz ($SiO_2$). Feldspars are also important tectosilicates.
Uses: Silicates are used extensively in construction (cement, concrete), glass manufacturing, ceramics, and as fillers.
Zeolites
Definition: Zeolites are aluminosilicate minerals containing a three-dimensional network of silica tetrahedra in which some silicon atoms are replaced by aluminum atoms. The negative charge arising from aluminum substitution is balanced by cations (like $Na^+$, $K^+$, $Ca^{2+}$) incorporated into the structure.
Structure: They have a porous structure with a specific framework of cavities and channels, with molecular dimensions.
Properties:
- Ability to lose and gain water molecules reversibly without chemical change.
- Ability to exchange their cations with ions in surrounding media.
- Their porous structure allows them to act as molecular sieves.
Uses:
- Ion Exchange: Softening of hard water.
- Catalysts: Used in the petrochemical industry for cracking hydrocarbons.
- Adsorbents: Used for removing water and other molecules from gases and liquids.
- Molecular Sieves: Used for separating molecules based on size and shape.