Answers
Answer:
53.1 mL NaOH
Explanation:
Related Questions
What is the volume of 45.6g of silver if the density of silver is 10.5g/mL? A. 4.34mL B. 479mL C. 0.23mL
A proton is a very tiny particle inside an atom. The mass of a proton isestimated to be 0.00000000000000000000000167 g. What is the mass of aproton in scientific notation?
5. As a sample of matter is heated, its particles *O A are unaffectedO B. move more quicklyO C. move more slowlyD. stop moving
Soil is an essential component of the earth's crust. It enabled life to exist andprovides the services necessary for human survival. What is the effect of soilerosion? What will you do to protect the community?
Answers
2:1:1:2
Answers
Answer:
3,8×10⁻⁵ mol/L of potassium permanganate solution
Explanation:
To calculate concentration in mol/L you must convert the 3,8 umol to moles and 100 mL to liters, knowing 1 umol are 1×10⁻⁶mol and 1L are 1000 mL.
3,8 umol × (1×10⁻⁶mol / 1 umol ) = 3,8×10⁻⁶mol of potassium permanganate.
100 mL × ( 1L / 1000 mL) = 0,100 L
Thus, concentration in mol/L is:
3,8×10⁻⁶mol / 0,100 L = 3,8×10⁻⁵ mol/L of potassium permanganate solution
I hope it helps!
b. Some of the vapor initially present will condense.
c. The pressure in the container will be 100. mm Hg.
d. Only octane vapor will be present.
e. Liquid octane will be present.
Answers
Answer:
the final pressure (108.03 mmHg ) inside the container at 339 K is more than the vapor pressure of liquid octane (100 mmHg) at 339 K.
Hence,
b. Some of the vapor initially present will condense.
e. Liquid octane will be present.
Explanation:
Given that;
The vapor pressure of liquid octane, C8H18, is 100 mm Hg at 339 K
Initial volume of the container, V1 = 537 mL
Initial vapor pressure, P1 = 68.0 mmHg
Final volume of the container, V2 = 338 mL
Let us say that the final vapor pressure = P2
From Boyle's law,
P2V2 = P1V1
P2 * 338 = 68.0 * 537
338P2 = 36516
P2 = 36516 / 338
P2 = 108.03 mmHg
Thus, the final pressure (108.03 mmHg ) inside the container at 339 K is more than the vapor pressure of liquid octane (100 mmHg) at 339 K.
Hence,
b. Some of the vapor initially present will condense.
e. Liquid octane will be present.
(B) Ca3PO6
(C) Ca4P2O4
(D) Ca3P2O8 (or Ca3(PO4)2)
(E) CaPO4
Answers
Answer:
D) empirical formula is: C₃P₂O₈
Explanation:
Given:
Mass % Calcium (Ca) = 38.7%
Mass % Phosphorus (P) = 19.9%
Mass % oxygen (O) = 41.2 %
This implies that for a 100 g sample of the unknown compound:
Mass Ca = 38.7 g
Mass P = 19.9 g
Mass O = 41.2 g
Step 1: Calculate the moles of Ca, P, O
Atomic mass Ca = 40.08 g/mol
Atomic mass P = 30.97 g/mol
Atomic mass O = 16.00 g/mol
Step 2: Calculate the molar ratio
Step 3: Calculate the closest whole number ratio
C: P: O = 1.50 : 1.00 : 4.00
C : P : O = 3:2:8
Therefore, the empirical formula is: C₃P₂O₈
Final answer:
The mass percentage composition of a compound can be used to determine its empirical formula. For a compound with 38.7% calcium (Ca), 19.9% phosphorus (P), and 41.2% oxygen (O), the empirical formula is Ca3(PO4)2.
Explanation:
To solve this problem, we're going to use the atomic mass percentages to determine the empirical formula of the compound.
We do this by assuming we have a 100g sample of the compound. Therefore:
The mass of calcium (Ca) is 38.7g.
The mass of phosphorus (P) is 19.9g.
The mass of oxygen (O) is 41.2g.
Next, we calculate how many moles we have of each element:
- Ca: 38.7g / 40.08g/mol (the atomic mass of calcium) = 0.965 moles
- P: 19.9g / 30.97g/mol (the atomic mass of phosphorous) = 0.643 moles
- O: 41.2g / 16.00g/mol (the atomic mass of oxygen) = 2.575 moles
Then, we divide each of these numbers by the smallest number of moles, which is 0.643 (P):
- Ca: 0.965/0.643 = 1.5 (~1)
- P: 0.643/0.643 = 1
- O: 2.575/0.643 = 4
Learn more about Empirical Formula here:
#SPJ3
Answers
Answer: 0.1304M
Explanation: Please see the attachments below
Final answer:
The concentration of acetic acid in the solution is 0.1304 M.
Explanation:
To determine the concentration of acetic acid in solution, we can use the concept of stoichiometry and the balanced chemical equation for the reaction between acetic acid and sodium hydroxide. The balanced equation is:
CH3CO2H + NaOH -> CH3CO2Na + H2O
From the balanced equation, we can see that 1 mole of acetic acid reacts with 1 mole of sodium hydroxide. In order to calculate the moles of acetic acid, multiply the volume of NaOH used (16.3 mL) by the molarity of NaOH (0.20 M), then divide the result by 1000 to convert mL to L:
Moles of acetic acid = (16.3 mL NaOH x 0.20 M NaOH) / 1000 = 0.00326 moles
Now, to calculate the concentration of acetic acid in the solution, we divide the moles of acetic acid by the volume of the solution in litres:
Concentration of acetic acid = (0.00326 moles) / (25.0 mL x 1 L/1000 mL) = 0.1304 M
This means that the concentration of the acetic acid in the solution is 0.13M.
Learn more about Concentration of acetic acid here:
#SPJ3