Question

Question #06d81

Answer 1

`a. 2mol"C"Cl_4`
`b. 308.0g"C"Cl_4`
`c. 1.2xx10^24"C"Cl_4 " molecules"`

Explanation:

1. Given the `etaCl_2`, this value can be the basis to find the `eta"C"Cl_4` through molar conversion. Refer to the provided balanced equation for the mole ratio.
   `=4.0cancel(molCl_2)xx(1mol"C"Cl_4)/(2cancel(molCl_2))`
   `=2mol"C"Cl_4`
2. Find the molar mass of the involved compound required in the problem. Relative atomic masses of the elements composing `"C"Cl_4` are obtainable from the periodic table; i.e.,
   `"Molar mass "C"Cl_4=(154 g)/(mol)`
3. Then, find `m"C"Cl_4"` that can be computed as
   `=2cancel(mol"C"Cl_4)xx(154g"C"Cl_4)/(1cancel(mol"C"Cl_4))`
   `=308g"C"Cl_4`
4. Lastly, find the number of molecules of `"C"Cl_4`. Knowing that the value in `eta"C"Cl_4=2mol` and from the relationship that `1mol"C"Cl_4=6.02xx10^23"C"Cl_4" molecules"`, the number of molecules can be computed as follows:
   `=2cancel(mol"C"Cl_4)xx(6.02xx10^23"C"Cl_4" molecules")/(1cancel(mol"C"Cl_4))`
   `=12.04xx10^23"C"Cl_4" molecules"`
5. Make sure to express the resulting value in the standard scientific notation. Knowing the fact that moving the decimal point to the left corresponds to a positive exponent (from the mnemonics LIP-Left Is Positive); that is,
   `=1.2xx10^24"C"Cl_4" molecules"`