I need help figuring out how to find the molarities of each dilution. My exact mass of pure ASA was .497 g. From that and the molar mass I found that there were .00276 moles of ASA.

Data for calibration curve 1. Hydrolysis of acetylsalicylic acid a. Work in pairs for this part of experiment. Weigh 0.50 ± g of acetylsalicylic acid, ASA, (pure) and transfer it to a 125mLmenmeyer flask. ..49-. 5. -4979-ASA Add 10 mL of 1.0 ± M sodium hydroxide and 10 ml of distilled water. Heat the flask gently, with hot plate, until the contents boil, to hydrolyze the d. ASA. i1 ml Cool to room temperature and add 15-20 mL of 0.10 ± M nitric acid. 2. Dilution of salicylic acid solution a. Quantitatively transfer the contents of the flask to a 250 mL volumetric flask and bring up to volume. Important: Use 0.10 M nitric acid for rinsing the Erlenmeyer flask and making the dilution. Carefully follow the directions given by the lab instructor for correct use of a volumetric flask. b. Pipet 10 mL of the solution and transfer it to a 100 mL volumetric flask. Pre-rinse the pipet.) Make up to volume with 0.10 M nitric acid (Reminder: and mix the solution thoroughly ompleted and the solution thoroughly mixed, transfer C. half of the solu ind ean dry beaker and, continue working as an 3. Concentration Series Using a buret filled with your diluted salicylic acid solution, measure 2.4,6,8 and 10 mL of solution into your large test tubes. a. Use buret and add the volume of 0.10 M nitric acid needed to give a total sample volume of 10 ml. (8,6,4,2, and 0 mL). MIX b. Pipet 1.0 mL of the Fes color reagent (2% Fe(NO3); . 9H20 in 0.10 M nitric acid) into each 10 mL sample. Mix well. Using the most dilute solution and the spectrophotometer determine the operating wavelength for the iron complex solution. d. 139

Determinatrion of Iron in Vitamin

A. Prep of Iron Soln. from Vitamin

Weigh three vitamin tablets and place each tablet in separate 125-mL Erlenmeyer Flask. Add 25 mL of 2M HCL to each flask in the hood and boil the samples for 15 mins.

Set up Vacumm filter system and filter each sample serparetely and collect the filtrate(liquid). Transfer filtrate after each run to a 50 mL Volumetric flask. Rinse filter flask with DI water and transfer rinse to the vol. flask as well. Repeat for each solution.

After solutions cool, dilute it to the mark with DI water and Mix well. Transfer contents to a labeled beaker.

For each solution made, transfer 1.00 mL of the solution with a volumetric pipette and place it in a fresh 50 mL vol. flask. Then dilute it ot he mark with DI water.

B. Prep of sample Solutions

From each diluted vitamin solution a test solution sample will be made. Using a vol. pipette transfer 5.00 mL of the diluted vitamin solution(unknown molarity) to a large test tube. Then add 4.00 mL hydroquinone and 6 mL of o-phenanthroline to the test tube with a vol.pipettes. Note the volume of the test solutions. This dilution step is needed when calculate the mass of iron in the tablets.

C. Prep of Sample Solutions

One iron standard solution will be made for the class.

D. Prep of Calibration Solutions

Each student pair will make at least one calibration solution. Have the instructor assign you a solution 0-7. The entire lab section will make one calibration set by the following steps:

Label a 50.00 mL vol. flask with your assigned number (0-7)

Collect ~ 5 mL of hydroquinone and transfer it to a clean beaker. Then collect ~ 5 mL of phenathroline and transfer this solution to another clean beaker. Transfer 2.00mL of hydroquinone and 3.00mL of phenathroline using vol. pipettes to the labeled vol. flask

Collect ~5-10 mL of the standard solution and transfer it to a clean beaker. The amount of iron solution to transfer via vol. flask is equal to the assigned number (i.e. if your group was assigned #1, transfer 1.00 mL of the iron solution to the flask. Flask 0 will not contain any iron solution.

Once all three reagents have been added to a flask. Add ~ 20mL of DI water. Mix the solution by capping the flask and inverting it several times. Continue adding DI water to the mark on the flask and mix solution again by inversion.

What is the molarity of the iron in each calibration solution?

Given Info/Data

Mass of Iron tablets: 1.2900g 1.2991g 1.2979

Can someone please help me complete this worksheet

B. 0.036

C. 0.36

I need help answering d and e

160 g of a 0.80% sodium hydroxide solution.

The following question involves the reaction of sodium hydroxide and succinic acid. Succinic acid is diprotic: the acid (H₂C₄H₄O₄) reacts with two of its hydrogens to give C₄H₄O₄^2-. The balanced “molecular” equation for the reaction has coefficients of 2 for NaOH and 1 for succinic acid:

2 NaOH (aq) + H₂C₄H₄O₄ (aq) --> Na₂C₄H₄O₄ (aq) + 2 H₂O (l)

A student weighs 1.700 g of succinic acid and dissolves it in water in a 250.0 mL volumetric flask. A 25.00 mL sample of this solution is withdrawn and placed in a 125 mL Erlenmeyer flask, to which 5 drops of the acid-base indicator phenolphthalein is added. This solution is titrated with a sodium hydroxide solution of unknown molarity in a buret.

a) How many moles of succinic acid were weighed and dissolved in the volumetric flask?

0.0572 M

b) How many moles of succinic acid were placed in the Erlenmeyer flask?

1.43 x 10^-3 mol

c) If the unknown sodium hydroxide solution was known to be approximately 0.20 M, at approximately what buret volume would you expect the end point of the titration? Show the calculation, including the use of the appropriate coefficients, as a 2 significant figure estimate:

14.30 mL NaOH

d) If the measured volume at the end point was 13.32 mL of sodium hydroxide added, calculate the actual molarity of the sodium hydroxide solution.

0.214 M NaOH

You are going to standardize a 0.80% solution of sodium hydroxide solution for which the molarity is approximately 0.20 M. You will have dry succinic acid, a 250 mL volumetric flask, a 25.00 mL pipet, a 50.00 mL buret, a phenolphthalein indicator solution, and other standard laboratory equipment. For each titration you will withdraw a 25.00 mL sample of the succinic acid solution with a volumetric pipet. Therefore, you will deliver exactly one-tenth of your initial mass of succinic acid (to four significant figures) in each titration. In deciding the amount of succinic acid to weigh, assume that you will be using approximately 15 mL of the sodium hydroxide of approximate 0.20 M concentration for each titration, and you need enough succinic acid for ten titrations. Show how to calculate the mass of succinic acid you will need to weigh.