How many TOTAL bonds are there in the CH3CH3 molecule? Count all bonds (ie C-C bonds as well as C-H bonds).

To determine the total number of bonds in the CH3CH3 molecule, we first need to identify the atoms and the type of bonds they form.

In the molecule CH3CH3, there are two carbon atoms (C) and six hydrogen atoms (H). Carbon atoms can form up to four bonds, while hydrogen can form only one bond.

Starting with the first carbon atom (C) in the molecule, it is bonded to three hydrogen atoms (H) and to the other carbon atom. This means that the first carbon atom has four bonds (three C-H bonds and one C-C bond).

Moving to the second carbon atom (C), it is bonded to three hydrogen atoms (H) and to the first carbon atom. Therefore, the second carbon atom also has four bonds (three C-H bonds and one C-C bond).

So, the CH3CH3 molecule has a total of 8 bonds: 3 C-H bonds for the first carbon atom, 1 C-C bond between the carbon atoms, and 3 C-H bonds for the second carbon atom.

Therefore, the total number of bonds in the CH3CH3 molecule is 8.

To determine the total number of bonds in the CH3CH3 molecule, we need to count all the C-C bonds and C-H bonds.

The CH3CH3 molecule consists of two carbon (C) atoms and six hydrogen (H) atoms.

Each carbon atom in this molecule is bonded to three hydrogen atoms, resulting in a total of six C-H bonds (3 C-H bonds per carbon atom).

In addition, the two carbon atoms are also bonded to each other, resulting in one C-C bond.

Therefore, the total number of bonds in the CH3CH3 molecule is the sum of the C-C bond and the C-H bonds:

Total bonds = C-H bonds + C-C bond
Total bonds = 6 C-H bonds + 1 C-C bond
Total bonds = 7 bonds

Therefore, there are a total of 7 bonds in the CH3CH3 molecule.

This is a simple counting exercise.

There are six C-H bonds

and one C-C bond

there 7 H and C bonds together