Firstly ammonia forms a coordinate bond with H+ of water. Forming a conjugate acid then it react with OH- to form NH4OH. I.e. it shows acid base reaction
Ammonia can form four hydrogen bonds per molecule. The lone pair on nitrogen can accept one hydrogen to form a hydrogen bond, and the three hydrogen atoms can bond to lone pairs to form three additional hydrogen bonds. However, if ammonia is the only molecule present, this bonding pattern is problematic because each molecule only has one lone pair per three hydrogen atoms. Thus, an average molecule would likely only have two hydrogen bonds, out of the maximum of four.
The asker added, "I am looking to destroy SO2 accumulation in a gas system". In my opinion, you'd be likely to get a reaction between the ammonia (NH3) and the peroxide (H2O2). I'm not sure whether the sulfur dioxide (SO2) would be preferentially affected by the peroxide, but if it were, you'd likely get sulfur trioxide (SO3), which dissolves in H2O to produce H2SO4 -- sulfuric acid. As for a reaction between the peroxide and the ammonia -- based on limited experience, I believe there are several possibilities, and that the products you got would be dependent upon temperatures.
This protein molecule is likely an enzyme, which facilitates the chemical reaction by lowering the activation energy required for the reaction to occur. Enzymes remain unchanged after the reaction and can be reused to catalyze multiple reactions. They are specific to the reaction they catalyze and are essential for the proper functioning of the cell.
Sunlight wouldn't be enough energy to carry out the reaction between n-hexane and bromine. The energy source, however, may have been written has "hv" as a way to describe the radiation or high-wavelength energy for the reaction, which is possible in a more controlled environment. In this scenario, the reaction between n-hexane and bromine is a bromination reaction--generation of a bromine radical and attaching one or more bromine molecules to hexane. It is more likely that it will attach to a secondary carbon rather its primary, and its location of attachment between the available secondary carbons would be a mixture.
The white residue that forms on the bottles is likely ammonium chloride (NH4Cl), which is formed by the reaction between hydrochloric acid (HCl) and ammonia (NH3) vapors in the air. This reaction produces ammonium chloride as a result of the combination of the two gases.
D
Ammonia can form four hydrogen bonds per molecule. The lone pair on nitrogen can accept one hydrogen to form a hydrogen bond, and the three hydrogen atoms can bond to lone pairs to form three additional hydrogen bonds. However, if ammonia is the only molecule present, this bonding pattern is problematic because each molecule only has one lone pair per three hydrogen atoms. Thus, an average molecule would likely only have two hydrogen bonds, out of the maximum of four.
Lye and vinegar would likely neutralize each other. Vinegar is an acid, and lye is a base, so when mixed, they undergo a neutralization reaction to form water and a salt.
The asker added, "I am looking to destroy SO2 accumulation in a gas system". In my opinion, you'd be likely to get a reaction between the ammonia (NH3) and the peroxide (H2O2). I'm not sure whether the sulfur dioxide (SO2) would be preferentially affected by the peroxide, but if it were, you'd likely get sulfur trioxide (SO3), which dissolves in H2O to produce H2SO4 -- sulfuric acid. As for a reaction between the peroxide and the ammonia -- based on limited experience, I believe there are several possibilities, and that the products you got would be dependent upon temperatures.
When an atom, ion, or molecule of a reactant switches places with an unpaired reactant, it is most likely a single displacement reaction. In this type of reaction, one element replaces another element in a compound.
A diatomic molecule is most likely to have a covalent bond. This type of bond involves the sharing of electron pairs between the two atoms in the molecule.
This protein molecule is likely an enzyme, which facilitates the chemical reaction by lowering the activation energy required for the reaction to occur. Enzymes remain unchanged after the reaction and can be reused to catalyze multiple reactions. They are specific to the reaction they catalyze and are essential for the proper functioning of the cell.
Electronegativity is the measure of an atom's ability to attract electrons in a chemical bond. In a chemical reaction, leaving groups are atoms or groups of atoms that depart from a molecule. The relationship between electronegativity and the ability of leaving groups to depart is that leaving groups with lower electronegativity are more likely to depart easily in a reaction, as they are less likely to hold onto the shared electrons tightly.
The presence of more substituted carbon in a molecule generally decreases its reactivity in a chemical reaction. This is because the additional substituents can stabilize the molecule, making it less likely to undergo reactions compared to less substituted carbon atoms.
Meso compounds in a chemical reaction can be determined by looking for molecules with a plane of symmetry. If a molecule has a plane of symmetry, it is likely a meso compound.
The difference between curve A and curve B on an energy diagram is most likely due to the activation energy required for the reaction. Curve A likely represents a reaction with a higher activation energy, resulting in a slower reaction rate compared to curve B, which represents a reaction with a lower activation energy and a faster reaction rate.
Sunlight wouldn't be enough energy to carry out the reaction between n-hexane and bromine. The energy source, however, may have been written has "hv" as a way to describe the radiation or high-wavelength energy for the reaction, which is possible in a more controlled environment. In this scenario, the reaction between n-hexane and bromine is a bromination reaction--generation of a bromine radical and attaching one or more bromine molecules to hexane. It is more likely that it will attach to a secondary carbon rather its primary, and its location of attachment between the available secondary carbons would be a mixture.