The molecular geometry of the oxygens in hydrogen peroxide (H2O2) is bent or angular.
No, hydrogen peroxide is two hydroxyl groups (OH) with bounded oxygens. Hydroperoxide is a deprotonated version (one of the OH's is an O- instead). However they usually exist together as the deprotonation occurs easily in the presence of water.
Hydrogen peroxide is a compound made of hydrogen and oxygen atoms bonded in a specific way, giving it different chemical and physical properties than the individual elements. The presence of an extra oxygen atom in hydrogen peroxide results in different intermolecular forces and reactivity compared to pure hydrogen or oxygen molecules.
Total valence electons = 26. Bonding electrons = 6. Place the Phosphorus in the center with the three Oxygens bonded to it. Use 20 (26-6) electrons to fill the octets of the oxygens... you have 2 electons left over to put on the phosphorus to fill its octet. 3 bonds plus 1 lone pair gives a steric number of 4. With one lone pair, the molecular geometry is trigonal pyramidal.
The peroxide ion is '-O-O-H^(-)'. Note the two oxygens are singly bonded together. There are peroxiy acids. e.g. CH3C(=O)-O-O-H ( Ethanperoxy acid). Peroxy's are often used to initiate a polymerisation process.
For 100g of sugar, approximately 42.1g are carbon, 6.4g are hydrogen, and 51.4g are oxygen. These are based on the molecular weights of C, H and O and the sucrose molecule.
No, hydrogen peroxide is two hydroxyl groups (OH) with bounded oxygens. Hydroperoxide is a deprotonated version (one of the OH's is an O- instead). However they usually exist together as the deprotonation occurs easily in the presence of water.
Hydrogen peroxide is a compound made of hydrogen and oxygen atoms bonded in a specific way, giving it different chemical and physical properties than the individual elements. The presence of an extra oxygen atom in hydrogen peroxide results in different intermolecular forces and reactivity compared to pure hydrogen or oxygen molecules.
The density of a hydrogen peroxide solution will vary slightly based on the exact concentration of hydrogen peroxide. Solutions with higher concentrations will be slightly more dense. However, the density at lower concentrations is around the density of water, 1g/cm3.
As the name suggests, hydrogen peroxide has in it ,hydrogen and oxygen. Its formula is H2O2. Structurally, it is ' H-O-O-H '. The 'per---' in the formul/structure means that the two oxygens are singly bonded together. This type of bond is rather unstable and makes 'peroxides' in general a reactive species.
Hydrogen peroxide is H2O2, so each molecule is composed of two hydrogens and two oxygens. It is somewhat unstable, and left to its own devices will dissociate into water (or H2O) and hydrogen ions (H+); as such, it won't be an effective cleaning agent any longer.
hydrogen and 2 oxygens
hydrogen, nitrogen, 3 oxygens
Total valence electons = 26. Bonding electrons = 6. Place the Phosphorus in the center with the three Oxygens bonded to it. Use 20 (26-6) electrons to fill the octets of the oxygens... you have 2 electons left over to put on the phosphorus to fill its octet. 3 bonds plus 1 lone pair gives a steric number of 4. With one lone pair, the molecular geometry is trigonal pyramidal.
Most acne washes have salicylic acid or benzoyl peroxide. Salicylic Acid has 7 carbons, 6 Hydrogens, and 3 Oxygens. Salicylic Acid is also called 2-Hydroxybenzoic Acid. Benzoyl Peroxide has 14 Carbons, 10 Hydrogens, and 4 Oxygens. Benzoyl Peroxide is also called dibenzoyl peroxide. I hope this is what your looking for.
Yes
XeO4 is tetrahedral. The total number of valence electrons in the molecule is 32 (6 x 4 oxygens and 8 from the Xe) which when divided equally among the oxygens with a double bond to the Xe gives every O molecule a full outer shell, and the Xe an extended shell. If XeO4 (4-), then each O would be single-bonded to the Xe.
The peroxide ion is '-O-O-H^(-)'. Note the two oxygens are singly bonded together. There are peroxiy acids. e.g. CH3C(=O)-O-O-H ( Ethanperoxy acid). Peroxy's are often used to initiate a polymerisation process.