What is the distance from and object’s top to its bottom?
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Answer:
2000 L
General Formulas and Concepts:
<u>Atomic Structure</u>
- Moles
- Temperature Conversion: K = °C + 273.15
<u>Gas Laws</u>
Ideal Gas Law: PV = nRT
- P is pressure
- V is volume (in L)
- n is number of moles
- R is gas constant
- T is temperature (in K)
Explanation:
<u>Step 1: Define</u>
[Given] 8.8 moles gas
[Given] 0.12 atm
[Given] 56 °C = 329.15 K
<u>Step 2: Solve for </u><em><u>V</u></em>
- Substitute in variables [Ideal Gas Law Formula]:
- Isolate <em>V</em>:
- Multiply/Divide [Cancel out units]:
<u>Step 3: Check</u>
<em>Follow sig fig rules and round. We are given 2 sig figs.</em>
1981.7 L ≈ 2000 L
In 250 mL of volumetric flask add 0.975875 grams of and dissolve it in the 250 mL of water.
Given:
The solid of calcium fluoride.
To prepare:
The 250 mL solution of 0.100 M of fluoride ions from solid calcium fluoride.
Method:
Molarity of the fluoride ion solution needed = M = 0.100 M
The volume of the fluoride ion solution needed = V = 250 mL
The moles of fluoride ion needed = n
According to the definition of molarity:
Moles of fluoride ion = 0.025 mol
We know that solid calcium fluoride dissolves in water to give calcium ions and fluoride ions.
According to reaction, 2 moles of fluoride ions are obtained from 1 mole of calcium fluoride, then 0.025 moles of fluoride ions will be obtained from:
Moles of calcium fluoride = 0.0125 mol
Mass of calcium fluoride needed to prepare the solution :
Preparation:
- Weight 0.975875 grams of calcium fluoride
- Add weighed calcium fluoride to a volumetric flask of the labeled volume of 250 mL.
- Now add a small amount of water to dissolve the calcium fluoride completely.
- After this add more water up to the mark of the volumetric flask of volume 250 mL.
Learn more about molarity of solution ere: