tetrahedral
Indeed they can. A common example of Carbon covalently bonding with carbon is in what we refer to as Giant Covalent Structures, which are multiple of an atom bonded together in a set, lattice-like shape. Examples of giant covalent structures made from carbon are diamond where the atoms are arranged in a pyramid shape, and graphite, where they are arranged in flat layers.
The initial statement in this question is false, carbon atoms do share electrons with other carbon atoms. An example of when they do share electrons can be found in diamond, where the carbon atoms form a tetrahedral shape to form one of the strongest naturally occurring substances..
The number of bonds the atoms in the molecule can form.
Carbon occurs in various elemental forms in nature, each with different physical properties.Graphite- Each carbon atom is bonded to three other carbon atoms in the same plane giving long a hexagonal array. One of these bonds is a double-bond, and thus two single and one double bonds satisfy the valency of carbon. Graphite structure is formed by the hexagonal arrays placed one over the other in layers and held together by van der Waals force.Diamond- Each carbon atom is bonded to four other carbon atoms forming a rigid three-dimensional structure.Buckminsterfullerene- Its molecular formula is C-60 and it is in the shape of a football.
CCl4 shape is circular. This is determined by the Valence Shell Electron Pair Repulsion theory (VSEPR). The repulsion of the molecule determines the shape of it. CCl4 has a tetrahedral shape, owing to four bond pairs of electrons repelling each other to positions of maximum separation and minimum repulsion. The angle between bonds is 109.5 degrees.
Carbon atoms are arranged in a tetrahedral fashion. Four carbon atoms will form single covalent bonds around the central atom all at the maximum angle away from each other (approx 109 degrees). These four are then joined by a further three carbon atoms again all having single covalent bonds. These bonds just keep forming. Use this link, below, to get a view of it: the black dots represent carbon atoms and the lines are single covalent bonds.In a diamond, the carbon atoms are arranged tetrahedrally.
Indeed they can. A common example of Carbon covalently bonding with carbon is in what we refer to as Giant Covalent Structures, which are multiple of an atom bonded together in a set, lattice-like shape. Examples of giant covalent structures made from carbon are diamond where the atoms are arranged in a pyramid shape, and graphite, where they are arranged in flat layers.
carbon atoms are tetrahedrally bonded with one another. The crystal structure of a diamond is a face-centered cubic or FCC lattice.
carbon-carbon doble bonds.
The initial statement in this question is false, carbon atoms do share electrons with other carbon atoms. An example of when they do share electrons can be found in diamond, where the carbon atoms form a tetrahedral shape to form one of the strongest naturally occurring substances..
The number of bonds the atoms in the molecule can form.
A saturated fatty acid chain is composed of a carbon chain with only single covalent bonds. This creates a tetrahedral geometry of the atoms. An unsaturated fatty acid chain is composed of a carbon chain with one or more double covalent bonds. This creates a trigonal geometry of the atoms at the double covalent bond.
Carbon occurs in various elemental forms in nature, each with different physical properties.Graphite- Each carbon atom is bonded to three other carbon atoms in the same plane giving long a hexagonal array. One of these bonds is a double-bond, and thus two single and one double bonds satisfy the valency of carbon. Graphite structure is formed by the hexagonal arrays placed one over the other in layers and held together by van der Waals force.Diamond- Each carbon atom is bonded to four other carbon atoms forming a rigid three-dimensional structure.Buckminsterfullerene- Its molecular formula is C-60 and it is in the shape of a football.
Tetrahedral, assuming you mean the shape when a nitrogen or phosphorus atom is bonded to fpur other atoms.
tetrahedral
CCl4 shape is circular. This is determined by the Valence Shell Electron Pair Repulsion theory (VSEPR). The repulsion of the molecule determines the shape of it. CCl4 has a tetrahedral shape, owing to four bond pairs of electrons repelling each other to positions of maximum separation and minimum repulsion. The angle between bonds is 109.5 degrees.
The number of carbon-carbon double bonds.