arsenic trihydride
It is a trigonal planar molecule; this resembles a 2D equilateral traingle with an Aluminium atom in the middle and the 3 chlorine atoms situated at each of the 3 points on the triangle. The bond angles are 120 degrees. Other examples of trigonal planar molecules are boron trifluoride (BF3) or boron trichloride (BCl3). It is a trigonal planar molecule; this resembles a 2D equilateral traingle with an Aluminium atom in the middle and the 3 chlorine atoms situated at each of the 3 points on the triangle. The bond angles are 120 degrees. Other examples of trigonal planar molecules are boron trifluoride (BF3) or boron trichloride (BCl3).
BaF2 would be the best conductor in the pure liquid or molten state due to its ionic nature and ability to dissociate into ions. Other compounds listed are covalent in nature and do not dissociate into ions easily in the liquid or molten state, resulting in poor conductivity.
That IS its real name. Are you thinking that a name has to sound English or otherwise familiar in order to be real?
Another name for shale is mudstone
Another name is satellite
The name of the binary compound with the formula AsH3 is arsine.
AsH3 stands for arsine, which is a toxic and flammable gas with the chemical formula AsH3. It is composed of one arsenic atom and three hydrogen atoms.
No, AsH3 does not follow the octet rule. Arsenic, the central atom in AsH3, can expand its valence shell to hold more than eight electrons in bonding.
The oxidation number of hydrogen is almost always 1 and should be so in AsH3.
The Arsenic in AsH3 typically has a plus one charge. Therefore the H must have a -1 charge to create the compound.
AsH3, also known as arsine, is a polar molecule. This is due to the asymmetrical arrangement of the hydrogen atoms around the central arsenic atom, creating an uneven distribution of charge within the molecule.
In AsH3, arsenic (As) has an oxidation number of -3 since hydrogen (H) is always assigned an oxidation number of +1 in compounds.
3 because that is the number of bonds it has already
The boiling point of a compound is influenced by its molecular weight and intermolecular forces. AsH3 has a lower boiling point than NH3 because it is a lighter molecule (lower molecular weight) and has weaker hydrogen bonding interactions between its molecules compared to NH3, which has stronger hydrogen bonding.
HCN will diffuse faster due to its lower molecular weight.
The boiling point of AsH3 (Arsine) is higher than that of PH3 (Phosphine) due to the higher molecular weight of AsH3 compared to PH3. Stronger Van der Waals forces of attraction between molecules in AsH3 result in higher boiling point.
The bonding in AsH3 involves the hybridization of the arsenic atom. Arsenic in AsH3 uses sp3 hybridization, where the 3p orbital and all three 3d orbitals combine with the 4s orbital to form four equivalent sp3 hybrid orbitals. These hybrid orbitals overlap with the 1s orbitals of the three hydrogen atoms to form three sigma bonds, resulting in a trigonal pyramidal molecular geometry.