Calculate the maximum moles of CO2 that can be dissolved in it. Use data that can only be found in the textbook. 1000 g / 44 g/mol = 2.27 g/mol (b) Calculate the % m/v of CO2 in this carbonated drink. 1 x 100 g = 100 g (c) What is the concentration of CO2 in ppm? 10^3 mg / 10^-3 L --> 10^6 mg/L = 10^6 ppm (d) If some of the 1-L carbonated drink is consumed, leaving 700 mL drink in the bottle. What is the concentration of CO2 in ppm in the drink that’s left in the bottle?
It's a four part question a b and c are answered, I'm having trouble with d. I have no idea if a-c are correct.
Consider a 1-L bottle of carbonated drink. The liquid is mostly water, and it can be assumed that its density is 1.00 g/mL.
(a) Calculate the maximum moles of CO2 that can be dissolved in it. Use data that can only be found in the textbook.
1000 g / 44 g/mol = 2.27 g/mol
(b) Calculate the % m/v of CO2 in this carbonated drink.
1 x 100 g = 100 g
(c) What is the concentration of CO2 in ppm?
10^3 mg / 10^-3 L --> 10^6 mg/L = 10^6 ppm
(d) If some of the 1-L carbonated drink is consumed, leaving 700 mL drink in the bottle. What is the concentration of CO2 in ppm in the drink that’s left in the bottle?
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