First, we calculate the mass of oxygen in each compound using the given mass of the sample and the given mass of carbon. For compound 1: Mass of carbon: \(27.2 \mathrm{g}\) Mass of sample: \(100.0 \mathrm{g}\) Mass of oxygen = (Mass of sample) - (Mass of carbon) \(= 100.0 \mathrm{g} - 27.2 \mathrm{g}\) \(= 72.8 \mathrm{g}\) For compound 2: Mass of carbon: \(42.9 \mathrm{g}\) Mass of sample: \(100.0 \mathrm{g}\) Mass of oxygen = (Mass of sample) - (Mass of carbon) \(= 100.0 \mathrm{g} - 42.9 \mathrm{g}\) \(= 57.1 \mathrm{g}\)

Next, find the mass ratios between carbon (C) and oxygen (O) for each compound. For compound 1: Ratio: \(\frac{\text{mass of carbon}}{\text{mass of oxygen}}\) \(= \frac{27.2 \mathrm{g}}{72.8 \mathrm{g}}\) For compound 2: Ratio: \(\frac{\text{mass of carbon}}{\text{mass of oxygen}}\) \(= \frac{42.9 \mathrm{g}}{57.1 \mathrm{g}}\)

The data support the law of multiple proportions if the ratio between the mass ratios in both compounds is a simple whole-number multiple. \(\frac{\text{Ratio in compound 2}}{\text{Ratio in compound 1}}\) \(= \frac{\frac{42.9 \mathrm{g}}{57.1 \mathrm{g}}}{\frac{27.2 \mathrm{g}}{72.8 \mathrm{g}}}\) Now, cancel the units and simplify the fraction to see if it is a simple whole-number multiple. \(= \frac{\frac{42.9}{57.1}}{\frac{27.2}{72.8}}\) \(= \frac{42.9}{57.1} \times \frac{72.8}{27.2}\) \(= \frac{3083.32}{1547.32}\) The ratio is approximately equal to 2, indicating the data support the law of multiple proportions. Since the ratio between the mass ratios in both compounds is a simple whole-number multiple, the data provided supports the law of multiple proportions.