Based on pKa, hydride would be better (~35 vs. ~45), but there are very few reactions where either would act as a leaving group.
The volume of a methyl group would be 100. The issue of a methyl group would be known as 18.
Yes, methyl is not an electron withdrawing group.
There is no such thing as a lone 'methyl'. A methyl group is a CH3 extending off an organic compounds main carbon chain. They can be created by the Sn2 reaction on iodomethane, or by the reaction of methyl lithium or MeMgCl with a carbon atom that is substituted with a leaving group
The methyl group in a molecule is electron donating.
Methyl orange is red under a pH=3,1 and yellow over a pH=4,4; methyl orange is useful for the titrimetric determination of acids concentration.
Formaldehyde is a better hydride donor than benzaldehyde because it is a stronger reducing agent due to the presence of the aldehyde group, which can readily donate hydride ions. In contrast, benzaldehyde is less reactive as a hydride donor because the aromatic ring stabilizes the carbonyl group, making it less prone to hydride donation.
The methyl group is -CH3.
The volume of a methyl group would be 100. The issue of a methyl group would be known as 18.
Yes, methyl is not an electron withdrawing group.
There is no such thing as a lone 'methyl'. A methyl group is a CH3 extending off an organic compounds main carbon chain. They can be created by the Sn2 reaction on iodomethane, or by the reaction of methyl lithium or MeMgCl with a carbon atom that is substituted with a leaving group
The methyl group in a molecule is electron donating.
Alanine is the amino acid with a methyl group as its R group.
No, methyl is not a functional group commonly found in alcohols. The functional group that is commonly found in alcohols is the hydroxyl group (-OH). Methyl, on the other hand, is a functional group commonly found in compounds called methyl groups (-CH3).
Methyl orange is red under a pH=3,1 and yellow over a pH=4,4; methyl orange is useful for the titrimetric determination of acids concentration.
A methyl group can be added to an alkane through a process called alkylation, where a methyl halide, such as methyl iodide, reacts with the alkane in the presence of a strong base, such as sodium hydroxide. This reaction results in the substitution of a hydrogen atom in the alkane with a methyl group, forming a new alkylated compound.
CH3OH is called methyl alcohol because it is a type of alcohol compound where the hydroxyl group (-OH) is attached to a carbon atom (methyl group -CH3) in the molecule. This naming convention is based on the IUPAC system for naming organic compounds.
No it is not. Methyl is the CH3 group which is part of some covalent compounds.