Trigonal pyramidal
in water there are two bond pairs and two lone pairs where as in CH4 there are are four bond pairs nad no lone pair. in ch4 there is only bond pair to bond pair repulsion but in water there are three types of repulsions, lone to lone (greatest repulsion), lone to bond ( lesser repulsion ) and bond to bond ( the least repulsion) , therefore due to the presence of two lone pairs in water the bond pairs are repelled with greater force and they get compressed, reducing the ideal bond angle from 109.5 to 104.5 on the other hand, ch4 has only bond pairs and they dont repel each other that strongly so its angle is greater n its 109.5..
The carbon is attached to three atoms and has a bond angle of 120 degrees.
Know the bond's face value, then, find the bond's coupon interest rate at the time the bond was issued or bought, then, multiply the bond's face value by the coupon interest rate it had when issued, then, know when your bond's interest payments are made, finally, multiply the product of the bond's face value and interest rate by the number of months in between payments.
it is calucated on the face value of the bond
The result is called a diamond structure. Diamond consists of tetrahedrally bonded carbon atoms arranged in a three-dimensional network structure, making it one of the hardest known materials.
A network covalent bond is a type of chemical bond where atoms are linked together in a continuous network structure via covalent bonds. This leads to a strong and stable three-dimensional network, such as in diamond or quartz.
Diamond is an example of a material that uses covalent bonds. In diamond, each carbon atom forms strong covalent bonds with four neighboring carbon atoms in a three-dimensional network structure. This results in a very hard and stable material.
Weak hydrogen bond that form between some amino acids help to determine the three-dimensional shape.
A diamond is made up of carbon atoms that are bonded together through strong covalent bonds known as sp3 hybridized bonds. These bonds involve the sharing of electrons between the carbon atoms in a three-dimensional network structure, giving diamond its exceptional hardness and transparency.
Diamond has a higher melting point than silicon carbide because diamond has strong covalent bonds between its carbon atoms in a three-dimensional lattice structure, making it harder to break apart compared to the bonds in silicon carbide. This results in diamond requiring more energy to overcome these strong bonds and melt.
A disulfide bond forms between two cysteine residues in a protein and helps maintain its specific three-dimensional shape by providing structural stability. It is a strong covalent bond that can resist disruption by changes in pH or temperature.
This structure is called a large lattice.
A diamond consists of covalent bonds between carbon atoms, where each carbon atom shares electrons with four neighboring carbon atoms to form a strong, three-dimensional network. This results in the diamond's hardness and durability.
No, a diamond is not a molecule. It is a crystalline form of carbon where each carbon atom is bonded to four other carbon atoms in a repeating pattern. Each carbon-carbon bond is a covalent bond formed by sharing electrons.
This structure is called a large lattice.
This structure is called a large lattice.