Question

Is 3 -chloro-3-methylhexane chiral?

Short answer

3-chloro-3-methylhexane is not chiral because it lacks a chiral center with four unique groups attached. The carbon atom in question (C3) has three different groups attached to it (hydrogen, chlorine, and methyl) but the fourth group is not unique, as it is part of the hexane chain.

Step-by-step solution

Determine the structure of the molecule

First, we'll draw the structure of 3-chloro-3-methylhexane. The name tells us that we have a six-carbon chain (hexane) with a chlorine atom and a methyl group attached at the third carbon. The structure will look like this: CH3 | CH3-CH2-C-CH2-CH2-CH3 | Cl

Identify the chiral center

Now that we have the structure, we need to find out if there's any carbon atom with four different groups attached to it. As we can see, the carbon atom in question (C3, to which the chlorine and the methyl group are attached) has three different groups attached to it (one hydrogen, one chlorine, and one methyl group). However, there is a fourth carbon group attached to C3, which is not unique (it is part of the hexane chain).

Determine chirality

Since the carbon atom in question (C3) does not have four different groups attached to it, it is not a chiral center. Therefore, 3-chloro-3-methylhexane is not a chiral molecule. In conclusion, 3-chloro-3-methylhexane is not chiral as it lacks a chiral center with four unique groups attached.

Key concepts

Chiral Center

A chiral center, also known as a stereocenter, is a carbon atom bonded to four different groups. This structure allows for two non-superimposable mirror image forms, called enantiomers, to exist. These enantiomers are essential in determining the chirality of a molecule.
Chiral centers are vital in chemistry because they influence how molecules interact with biological systems. For example, two enantiomers of a molecule might taste different or act differently in a biological context. To identify a chiral center in a molecule, you look for a carbon atom with four distinct substituents attached to it.
In the case of 3-chloro-3-methylhexane, the carbon atom C3 is examined to see if it qualifies as a chiral center. For a molecule to be chiral, C3 would need four different groups attached. However, C3 has three distinct groups: chlorine, a methyl group, and a hydrogen atom. The fourth group is part of another carbon chain, which is not unique. Therefore, C3 lacks four distinct groups, and the molecule is not chiral.

Organic Chemistry

Organic chemistry is the study of carbon-containing compounds and their structures, properties, and reactions. Most of these compounds feature complex molecular structures that can exhibit a wide variety of chemical behaviors.
It's a vast field, covering everything from simple molecules like methane to complex structures like proteins and DNA. In organic chemistry, understanding chirality is crucial, as it affects a molecule's interaction with other substances, particularly in living organisms.
In 3-chloro-3-methylhexane, a basic understanding of organic chemistry helps us deduce the structure and identify possible chiral centers. Drawing from knowledge of functional groups and hydrocarbon chains, one can predict molecular behavior and reactivity.

Molecular Structure

The molecular structure refers to the three-dimensional arrangements of atoms within a molecule. This structure determines how molecules interact, dictate reactivity, and impacts their physical and chemical properties.
For 3-chloro-3-methylhexane, understanding the molecular structure involves recognizing the main carbon chain (hexane) and noting where substituents like chlorine and methyl groups attach. In this molecule, we don't find all four groups around a carbon atom being unique, hence no chiral center.
Knowing a molecule's molecular structure, chemists can predict not only reactivity and interaction with other molecules but also properties like boiling points and solubility. Molecular structure is key in understanding a molecule's overall behavior in various chemical contexts.