you wish to combine two samples, one sample contains is solid water at 0 degree celsius.The other sample contains liquid water at 100 degree celsius,you want to combine both raise the temperature to 100 but boil off only 50 ml to gas phase keep the rest as liquid.How much energy is neededfor this?

I would like to know how much ice and how much liquid water @ 100 C you have? I haven't thought through the problem and that info may or may no be needed; however, it would make me feel better to have that info.

ELASTICITY, LIKE YOUR SOCKS (10/10 points)

The crystal structure of graphite is shown below. Use the figure to answer the following questions.

Compare the Young's moduli for the directions indicated in the figure. Fill in the blank.

The modulus along a is _________ that along b

equal to - correct
The modulus along a is _________ that along c

greater than - correct
The modulus along b is _________ that along c

greater than - correct
Which of the following reasons best explain your reasoning when comparing the moduli of b and c?

The Poisson ratio is greater than 0.3 in graphite.
The two directions are crystallographically identical
Fundamental bending and stretching of bonds is different in the two directions
Van der Waals bonding has a lower bond strength than colavent bonding - correct <--
Stretching of covalent bonds requires greater force than bending such bonds
The opportunity to stetch rings in one direction gives one direction a lower modulus

Which of the following reasons best explain your reasoning when comparing the moduli of a and b?

Stretching of covalent bonds requires greater force than bending such bonds
The Poisson ratio is greater than 0.3 in graphite.
The two directions are crystallographically identical - correct <---
Fundamental bending and stretching of bonds is different in the two directions
The opportunity to stetch rings in one direction gives one direction a lower modulus
Van der Waals bonding has a lower bond strength than colavent bonding

To determine the amount of energy needed to raise the temperature of the samples and boil off 50 mL of water, we need to break down the process into two steps:

Step 1: Raising the temperature of the two samples to 100 degrees Celsius
Step 2: Boiling off 50 mL of water from the combined sample

Step 1: Raising the temperature
To calculate the energy required to raise the temperature of the solid water from 0 to 100 degrees Celsius, we can use the specific heat capacity formula:

Q = mcΔT

Where:
Q is the energy required in joules
m is the mass of the solid water sample in grams
c is the specific heat capacity of water (4.18 J/g°C)
ΔT is the change in temperature (100°C - 0°C)

Let's assume the mass of the solid water sample is 'm1' grams. The energy required for this step is given by:

Q1 = m1 * c * ΔT1

where ΔT1 = 100°C - 0°C = 100°

Step 2: Boiling off 50 mL of water
To calculate the energy required to boil off the 50 mL of water, we can use the heat of vaporization formula:

Q = mL

Where:
Q is the energy required in joules
m is the mass of the liquid water sample in grams
L is the heat of vaporization of water (40.7 kJ/mol or 40.7 J/g)

Since we want to boil off 50 mL of water, we first need to convert it to grams. The density of water is 1 g/mL. Therefore, the mass of water is 50 grams. The energy required for this step is given by:

Q2 = m2 * L

where m2 = 50 grams

Finally, to find the total energy required, we add the energy required in both steps:

Total energy = Q1 + Q2

Please provide the value of 'm1' (mass of solid water sample) in grams to complete the calculation.