The [α] of a pure chiral compound A is +30°, Calculate the ee of a solution...

A) assume you synthesized a molecule with a single chiral center. The known specific rotation for...

A) assume you synthesized a molecule with a single chiral center. The known specific rotation for the pure R enentiomer of this compound is +20 degrees. After you synthesis, you measure a specific rotation of +4 degrees. What is the ee of your compound ? Answer is 20% ee of R B) the S of a certain alcohol has a specific rotation (of a plane polarized light) of +8 degrees. What is the specific rotation of a solution of this...

An aqueous solution containing 8.65 g of an optically pure compound was diluted to 600.0 mL...

An aqueous solution containing 8.65 g of an optically pure compound was diluted to 600.0 mL with water and placed in a polarimeter tube 20.0 cm long. The measured rotation was –2.05° at 25 °C. Calculate the specific rotation of the compound.

An aqueous solution containing 6.83 g of an optically pure compound was diluted to 200.0 mL...

An aqueous solution containing 6.83 g of an optically pure compound was diluted to 200.0 mL with water and placed in a polarimeter tube 15.0 cm long. The measured rotation was –4.89° at 25 °C. Calculate the specific rotation of the compound.

An aqueous solution containing 4.69 g of an optically pure compound was diluted to 300.0 mL...

An aqueous solution containing 4.69 g of an optically pure compound was diluted to 300.0 mL with water and placed in a polarimeter tube 15.0 cm long. The measured rotation was –3.17° at 25 °C. Calculate the specific rotation of the compound.

Be sure to answer all parts. An aqueous solution containing 10g of an optically pure compound...

Be sure to answer all parts. An aqueous solution containing 10g of an optically pure compound was dilluted to 500mL with water and was found to have a specific rotation of -123 degrees. If this solution were mixed with 500mL of a solution containing 3g of a racemic mixture of the compound, what would be the specific rotation of the resulting mixture of the compound? What would be its optical purity? Specific rotation = ____________ Optical purity = ___________

Calculate the solubility at 25°C of CoOH2 in pure water and in a 0.0050M CoCl2 solution....

Calculate the solubility at 25°C of CoOH2 in pure water and in a 0.0050M CoCl2 solution. (Ksp = 5.92 x 10^-15) Round both of your answers to 2 significant digits Solubility in pure water? g/L Solubility in 0.0050 M CoCl2 solution? g/L

The (S)-enantiomer of a compound was measured to have a specific rotation, []D, of -100. What...

The (S)-enantiomer of a compound was measured to have a specific rotation, []D, of -100. What is the enantiomeric composition of a sample that is measured to have a specific rotation of +50? A) 50% (R); 50% (S) B) 65% (R); 35% (S) C) 35% (R); 65% (S) D) 75% (R); 25% (S) E) 25% (R); 75% (S) F) 85% (R); 15% (S)

Pour 30 grams of salt into a solution. Calculate the weight percentage concentration of this solution...

Pour 30 grams of salt into a solution. Calculate the weight percentage concentration of this solution if the solution weighed 250. g. Dilute this solution 7 times. Calculate the concentration of each solution, assuming that each dilution represents a 10:1 decrease in concentration. Record this in the Table. How many grams of salt are in each solution? Record this in the Table. How many NaCl formula units are there in each of the solutions? Hint: 58.5 g of NaCl contains...

4. Calculate the compound amount. Use the compound amount formula and a calculator. (Round your answer...

4. Calculate the compound amount. Use the compound amount formula and a calculator. (Round your answer to two decimal places.) P = $9700, r = 4% compounded daily, t = 4 years 5.Calculate the present value. (Round your answer to two decimal places.) A = $47,000, r = 7.5% compounded annually, t = 39 years 6. Calculate the present value. (Round your answer to two decimal places.) A = $30,000, r = 6% compounded monthly, t = 3 years 7....

Assume that α-D-glucose and β-D-glucose are levorotatory and dextrorotatory respectively. The specific rotation Z of an...

Assume that α-D-glucose and β-D-glucose are levorotatory and dextrorotatory respectively. The specific rotation Z of an optically active compound in a set of conditions of temperature and wavelength is give by the equation: Z = observed optical rotation (°)/optical length (dm) and concentration (g/mL) A freshly prepared solution of α-D-glucose shows a specific rotation of =122°. Over time, the rotation of the solution gradually decreases and reaches equilibrium of 52.5°. In contrast a freshly prepared solution of β-D-glucose has a...