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This article was co-written by Bess Ruff, MA. Bess Ruff is a graduate student in geography at Florida. She received her Master’s degree in Environmental Science and Management from the Bren School of Environmental Science & Management, UC Santa Barbara in 2016. She has conducted survey work for marine spatial planning projects in the coastal area. Caribbean and support research as a contributor to the Sustainable Fisheries Group.
There are 12 references cited in this article that you can view at the bottom of the page.
This article has been viewed 43,172 times.
In chemistry, “partial pressure” is the pressure each gas in a gas mixture exerts on its surroundings, such as a laboratory sample gas cylinder, a diver’s supply tank, or the surrounding space. atmosphere. You can calculate the pressure of each gas in a mixture if you know its mass, volume, and temperature. You then add up the partial pressures to get the total pressure of the gas mixture, or you find the total pressure first and then find the partial pressure.
Steps
Understand the properties of gases
- The pressure of an ideal gas increases as it is compressed into a smaller space and decreases as it disperses into a larger space. This relationship is known as Boyle’s Law (named after scientist Robert Boyle). The mathematical formula for this relationship is k = P x V, or more simply k = PV, where k is the constant relationship between pressure and volume, P is pressure and V is volume. accumulate. [2] X Research Source
- The problem can give pressure in one of many different units. In which pascal (Pa) is defined as the force of one newton acting on one square meter. Another unit is the atmosphere (atm) which is defined as the pressure of the earth’s atmosphere at an altitude equal to sea level. A pressure of 1 atm is equal to 101.325 Pa. [3] X Research Sources
- The temperature of an ideal gas increases as the volume increases and decreases as the volume decreases. This relationship is known as Charles’ Law (named after scientist Jacques Charles). The mathematical formula for this relationship is k = V/T, where k is the constant relationship between volume and temperature, V is volume, and T is temperature. [4] X Research Sources[5] X Research Sources
- The temperature of the gas in this equation is given in degrees Kelvin, and degrees Kelvin is calculated by adding degrees Celsius by 273.
- These two relationships can be combined into a single equation: k = PV / T, or PV = kT.
- Conventional mass is measured in grams, or, if the mass is large enough, in kilograms.
- Since most gases are usually so light, they are also measured in another form of mass called molecular mass or mp mass. The mass mp is defined as the total atomic mass of each atom in the composition of that gas, with the mass of each atom compared with the mass of carbon (which has a value of 12). [6] X Research Source
- Since atoms and molecules are too small to calculate, the mass of a gas is defined in mp. The number of mp in a gas can be calculated by dividing the mass of the gas by the mass mp, and is denoted by the letter n.
- We can replace any constant k in the gas equation with the product of n, the number of mps, and a new constant R. We now have the equation nR = PV/T or PV = nRT. [7] X Research Sources
- The R value depends on the units used to measure the pressure, volume, and temperature of the gas. If the volume is in liters, the temperature is in Kelvin, and the pressure is in atmospheres, this value is 0.0821 L atm/K mp. You can also write 0.0821 L atm K -1 mp -1 to avoid having to use slashes of division in units of measure. [8] X Research Sources
- Dalton’s law can be written as the following equation P sum = P 1 + P 2 + P 3 … with the amount of pressure P equal to the number of gases in the mixture.
- The Dalton Law equation can be expanded when the problem is for gases whose partial pressure is unknown, but whose volume and temperature are known. The partial pressure of a gas is the pressure exerted by the same mass of gas in a vessel containing it alone. [11] X Research Source
- For each partial pressure, we can rewrite the ideal gas equation PV = nRT to the form with only P on the left side of the equal sign. So we have to divide both sides by V: PV/V = nRT/V. The two Vs on the left side are eliminated, and in the end, P = nRT/V remains.
- Then you substitute this formula for each P in the right hand side of the partial pressure equation: P sum =(nRT/V) 1 + (nRT/V) 2 + (nRT/V) 3 …
Calculate the partial pressure, then calculate the total pressure
- The partial pressure equation is written as P total = P nitrogen + P oxygen + P carbon dioxide .
- Since we are finding the pressure of each gas, given the volume and temperature, and can find the mp of each gas based on their mass, the equation can be rewritten as: P sum =(nRT/ V) nitrogen + (nRT/V) oxygen + (nRT/V) carbon dioxide
- For the first gas, nitrogen has the molecular formula ( N2 ), each atom has a mass of 14. Since the nitrogen molecule has two atoms, we have to multiply 14 by 2 to get the mass. molecular weight of nitrogen is 28. Then divide the gram mass of 10g by 28 to get mp, rounding the result to approximately 0.4 mp of nitrogen gas.
- For the second gas, oxygen has the molecular formula (O 2 ), each atom has a mass of 16. The oxygen molecule also has two atoms, we have to multiply 16 by 2 to get the mass. The molecular weight of oxygen is 32. Dividing 10g by 32 gives approximately 0.3 mp of oxygen in the bottle.
- The third gas is carbon dioxide with the formula (CO 2 ), which has 3 atoms: one carbon atom with mass 12, two oxygen atoms with mass 16 each. We add the mass of three atoms: 12 + 16 + 16 = 44 is the molecular mass. Dividing 10g by 44 gives approximately 0.2 mp of carbon dioxide.
- For simplicity we omit the unit of measure following the values. These units will be canceled out after you solve the equation, leaving only the measurement unit of the result, which is pressure.
- For the partial pressure of nitrogen, you multiply 0.4 mp by the constant 0.0821 and the temperature of 310 degrees K, then divide by 2 liters: 0.4 * 0.0821 * 310/2 = 5 .09 atm (approx.).
- For the partial pressure of oxygen, you multiply 0.3 mp by the constant 0.0821 and the temperature of 310 degrees K, then divide by 2 liters: 0.3 * 0.0821 * 310/2 = 3 .82 atm (approx.).
- For the partial pressure of carbon dioxide, you multiply 0.2 mp by the constant 0.0821 and the temperature of 310 degrees K, then divide by 2 liters: 0.2 * 0.0821 * 310/ 2 = 2.54 atm (approx.).
- Now you add these pressures to find the total pressure: P sum = 5.09 + 3.82 + 2.54 = 11.45 atm (approximately).
Calculate the total pressure, then calculate the partial pressure
- The Kelvin temperature is still 310 degrees, and as above, we have approximately 0.4 mp of nitrogen, 0.3 mp of oxygen and 0.2 mp of carbon dioxide.
- Similarly, we will calculate the resulting pressure in atmospheres so we will use an R value of 0.0821 L atm/K mp.
- So far the partial pressure equation is still: P total =(0.4 * 0.0821 * 310/2) nitrogen + (0.3 *0.0821 * 310/2) oxygen + (0.2) * 0.0821 * 310/2) carbon dioxide .
- Add 0.4 + 0.3 + 0.2 = 0.9 mp of gas mixture. The equation is further reduced to P sum = 0.9 * 0.0821 * 310/2.
- We have 0.4 mp of nitrogen so 0.4/0.9 = 0.44 (44%) in the gas mixture (approximately).
- We have 0.3 mp of oxygen so 0.3/0.9 = 0.33 (33%) in the gas mixture (approximately).
- We have 0.2 mp of carbon dioxide so take 0.2/0.9 = 0.22 (22%) in the gas mixture (approximately).
- Although the approximate percentage values above add up to only 0.99, in reality the decimals repeat themselves, with the sum being a series of 9s followed by a comma. By definition, this is equivalent to 1 or 100 percent.
- Take 0.44 * 11.45 = 5.04 atm (approx.).
- Take 0.33 * 11.45 = 3.78 atm (approx.).
- Take 0.22 * 11.45 = 2.52 atm (approximately).
Advice
- You will find there is a slight difference between calculating the partial pressure first and then calculating the total pressure and calculating the total pressure first and then calculating the partial pressure. Remember that the calculated values are only approximations as we round to 1 or 2 decimal places to make them simpler. If we use the calculator to do the calculations without rounding, the difference between the two methods is even smaller, even without bias.
Warning
- For divers, knowledge of the partial pressure of a gas is especially important as it concerns their lives. A partial pressure of oxygen that is too low can cause unconsciousness or death, while a partial pressure of nitrogen or oxygen that is too high can cause poisoning. [13] X Research Source[14] X Research Source
Things you need
- Laptop
- Atomic mass/mp mass reference book
This article was co-written by Bess Ruff, MA. Bess Ruff is a graduate student in geography at Florida. She received her Master’s degree in Environmental Science and Management from the Bren School of Environmental Science & Management, UC Santa Barbara in 2016. She has conducted survey work for marine spatial planning projects in the coastal area. Caribbean and support research as a contributor to the Sustainable Fisheries Group.
There are 12 references cited in this article that you can view at the bottom of the page.
This article has been viewed 43,172 times.
In chemistry, “partial pressure” is the pressure each gas in a gas mixture exerts on its surroundings, such as a laboratory sample gas cylinder, a diver’s supply tank, or the surrounding space. atmosphere. You can calculate the pressure of each gas in a mixture if you know its mass, volume, and temperature. You then add up the partial pressures to get the total pressure of the gas mixture, or you find the total pressure first and then find the partial pressure.
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