SiO2 as it exists in linear and branched chains
These are giant molecular lattice structures. This implies that strong covalent bonding holds their atoms together in a highly regular extended network. The bonding between the atoms goes on and on in three dimensions. Melting requires the separation of the species comprising the soild state, and boiling the separation of the species comprising the liquid state. Because of the large amount of energy needed to break huge numbers of covalent bonds, all giant covalent network structures have high melting points and boiling points and are insoluble in water. Diamond, graphite (allotropes of carbon) and quartz (silicon(IV) oxide, SiO2) are examples.
Assuming you are referring to only two hydrogen atoms, such as in a sample of hydrogen gas, there is a covalent bond between the hydrogen atoms, as well as a small amount of dispersion forces.
O=c=o has the greatest amount of energy stored in its bonds.
The amount of heat energy required to vaporize a metal is a measure of the strength of metallic bonding.
First you need to know that a polar bond is formed when electrons are unequally shared between two atoms. Polar covalent bonding occurs because one atom has a stronger affinity for electrons than the other (yet not enough to pull the electrons away completely and form an ion). In a polar covalent bond , the bonding electrons will spend a greater amount of time around the atom that has the stronger affinity for electrons.An unequal relationship creates a polar covalent bond such as with H-Cl.
These are giant molecular lattice structures. This implies that strong covalent bonding holds their atoms together in a highly regular extended network. The bonding between the atoms goes on and on in three dimensions. Melting requires the separation of the species comprising the soild state, and boiling the separation of the species comprising the liquid state. Because of the large amount of energy needed to break huge numbers of covalent bonds, all giant covalent network structures have high melting points and boiling points and are insoluble in water. Diamond, graphite (allotropes of carbon) and quartz (silicon(IV) oxide, SiO2) are examples.
Ionic bonding takes place between ions. So, it can be said that it has most amount of ionic character
Eventhough we classify chemical bonds as ionic and covalent,when we get deeper into nature of bonds, we find that what we call an ionic bond has some amount of covalent character and vice versa.So theoritically speaking there's no such thing like nonpolar covalent bond.But if we consider cases of homonuclear diatomic molecules like O2,H2 etc. the electronegativity difference between the two bonded atoms is almost zero and hence there would be an ideal case of equal sharing of electrons by the two atoms in those molecules.Hence it may be called as a nonpolar covalent bond.
Assuming you are referring to only two hydrogen atoms, such as in a sample of hydrogen gas, there is a covalent bond between the hydrogen atoms, as well as a small amount of dispersion forces.
That would be the Nobel gasses, 8A, because they have an octet of 8 electrons fully filling their valance shells so that they naturally do not react with other elements is either ionic or covalent bonding.
Sandstone. It is the softest most absorbent "Stone" that I know of that is found in enough abundance to form large structures (Mtns, hills) that would readily exhibit erosion.
Liquid water molecules exhibit a greater amount of motion than ice molecules.
an infinite amount
yes, we can get the greatest amount of energy at the producer level.
The greatest amount of socialized learning most likely occurs in a classroom.
the Utilitarians they said - something is morally right when the maximum amount of happiness is produced for the greatest amount of people
The two gospels with the greatest amount of discourse are Matthew and John.