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2 years ago

This is an impossible formula. Pretend it is real.

Chemistry

1 answer:

abruzzese [7]2 years ago

6 0

The number of mole of Cr in 1 mole of Cr₈(PO₄)₃ is 8.00 moles

<h3>Description of Cr₈(PO₄)₃</h3>

From the formula of the compound, Cr₈(PO₄)₃, the following were obtained:

8 moles of Cr
3 moles of P
12 moles of O

<h3>How to determine the number of mole of Cr in 1 mole of Cr₈(PO₄)₃</h3>

From the formula, we can see that 8 moles of Cr are present.

Thus, 1 mole of Cr₈(PO₄)₃ will contain = 1 × 8 = 8.00 moles of Cr

Therefore, we can conclude that 1 mole of Cr₈(PO₄)₃ contains 8.00 moles of Cr

Learn more about moles of element in a compound:

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Solve,55.1 grams of tin at 90.6°C is dropped into a calorimeter with 75.4 grams of water at 21.0°C.The temperature of both the m

Lostsunrise [7]

Answer:

$C_{tin}=0.560\frac{J}{g\°C}$

Explanation:

Hello there!

In this case, for this calorimetry problem, we can notice that the heat evolved by the hot tin is gained by the cold water as the calorimeter is perfectly isolated, so we can write:

$-Q_{tin}=Q_{water}$

Thus, by defining the heats in terms of mass, specific heat and temperatures, we get:

$-m_{tin}C_{tin}(T_F-T_{tin})=m_{water}C_{water}(T_F-T_{water})$

Now, since we are asked for the specific heat of tin, we solve for it as shown below:

$C_{tin}=\frac{m_{water}C_{water}(T_F-T_{water})}{-m_{tin}(T_F-T_{tin})}$

Thus, when we plug in, we obtain:

$C_{tin}=\frac{75.4g*4.184\frac{J}{g\°C} (27.2\°C-21\°C)}{-55.1g(27.2\°C-90.6\°C)}\\\\C_{tin}=0.560\frac{J}{g\°C}$

Regards!

7 0

3 years ago

Heat 22.6 g of titanium from 1420oC to 1590oC

Sauron [17]

Answer:

Explanation:

(22.6g)(.52J/gC)(170C)

eliminate the respective variables

and you will only have Joules left

multiply it all

u get 1997.84

5 0

4 years ago

The bonds present in carbon tetrachloride (CCI) are

noname [10]

I think the answer is A

7 0

3 years ago

In the background information, it was stated that CaF2 has solubility, at room temperature, of 0.00160 g per 100 g of water. How

____ [38]

Answer:

2.05*10⁻⁵ moles of CF₂ can dissolve in 100 g of water.

12.82 moles of CaF₂ will dissolve in exactly 1.00 L of solution

Explanation:

First, by definition of solubility, in 100 g of water there are 0.0016 g of CaF₂. So, to know how many moles are 0.0016 g, you must know the molar mass of the compound. For that you know:

Ca: 40 g/mole
F: 19 g/mole

So the molar mass of CaF₂ is:

CaF₂= 40 g/mole + 2*19 g/mole= 78 g/mole

Now you can apply the following rule of three: if there are 78 grams of CaF₂ in 1 mole, in 0.0016 grams of the compound how many moles are there?

$moles=\frac{0.0016 grams*1 mole}{78 grams}$

moles=2.05*10⁻⁵

<u><em>2.05*10⁻⁵ moles of CF₂ can dissolve in 100 g of water.</em></u>

Now, to answer the following question, you can apply the following rule of three: if by definition of density in 1 mL there is 1 g of CaF₂, in 1000 mL (where 1L = 1000mL) how much mass of the compound is there?

$mass of CaF_{2}=\frac{1000 mL*1g}{1mL}$

mass of CaF₂= 1000 g

Now you can apply the following rule of three: if there are 78 grams of CaF₂ in 1 mole, in 1000 grams of the compound how many moles are there?

$moles=\frac{1000 grams*1 mole}{78 grams}$

moles=12.82

<u><em>12.82 moles of CaF₂ will dissolve in exactly 1.00 L of solution</em></u>

5 0

3 years ago

An ecosystem is a geographical area......

GrogVix [38]

The right answer for the question that is being asked and shown above is that: "where plants, animals, the landscape and the climate are all independent of each other." An ecosystem is a geographical area <span>where plants, animals, the landscape and the climate are all independent of each other.</span>

4 0

3 years ago