A sample of hydrogen gas was collected over water at 21ºc and 685 mmhg. the volume of the container was 7.80 l. calculate the mass of h2(g) collected. (vapor pressure of water = 18.6 mmhg at 21c.)

Answer: The element which is most likely to form negative ion is fluorine.

Explanation:

An ion is formed when a neutral atom looses or gains electrons.

For the given options:

Aluminium is the 13th element of the periodic table having electronic configuration of [tex]1s^22s^22p^63s^23p^1[/tex]

This element will loose 3 electrons to attain stable electronic configuration and will form [tex]Al^{3+}[/tex] ion

Copper is the 29th element of the periodic table having electronic configuration of [tex]1s^22s^22p^63s^23p^64s^23d^9[/tex]

This element will loose 2 electrons to attain stable electronic configuration and will form [tex]Cu^{2+}[/tex] ion

Sodium is the 11th element of the periodic table having electronic configuration of [tex]1s^22s^22p^63s^1[/tex]

This element will loose 1 electron to attain stable electronic configuration and will form [tex]Na^{+}[/tex] ion

Fluorine is the 9th element of the periodic table having electronic configuration of [tex]1s^22s^22p^5[/tex]

This element will gain 1 electron to attain stable electronic configuration and will form [tex]F^{-}[/tex] ion

Hence, the element which is most likely to form negative ion is fluorine.

Separate a mixture of sand, salt, and iron filings by first using a magnet to remove the iron filings. Then, add water to dissolve the salt, and decant the salty water, leaving the sand behind. Finally, allow the water to evaporate to retrieve the salt.

To separate a mixture of sand, salt, and iron filings, you would first use a magnet to remove the iron filings from the mixture. This is possible because iron is a magnetic material and will be attracted to the magnet, which allows it to be separated from the non-magnetic substances (sand and salt).

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Final answer:

The empirical formula of a compound with 18.0% carbon, 2.26% hydrogen, and 79.7% chlorine can be calculated by converting the percentages to grams, assuming a 100 g sample, and then converting that to moles. The moles are then used to find the simplest whole number ratio, and after comparison and adjustment, we deduce an empirical formula of C₂H₃Cl₃.

Explanation:

To calculate the empirical formula of a compound with a given percent composition, we first convert the percentages to grams, assuming we have a 100 g sample. This means the compound contains 18.0 g of carbon (C), 2.26 g of hydrogen (H), and 79.7 g of chlorine (Cl). Next, we convert the mass of each element to moles by dividing by its atomic mass (C: approximately 12.01 g/mol, H: approximately 1.01 g/mol, Cl: approximately 35.45 g/mol).

Step-by-step:

As hydrogen and chlorine are in almost a 1:1 molar ratio and carbon seems to be in a 2:3 ratio with chlorine, the empirical formula appears to be C₂H₃Cl₃. It's important to note that slight variations in these calculations could change the final empirical formula. Thus, we must adjust our calculations accordingly to ensure the molar ratios reflect whole numbers. If necessary, we multiply each of the mole ratios by the smallest common factor to obtain whole numbers.

Answer: Bromine has the highest electronegativity in period 4 of the periodic table.

Explanation:

Electronegativity is defined as the tendency of an atom to attract the shared pair of electrons towards itself whenever a bond is formed.

This property of an atom increases as we move from left to right in a period because the number of charge on the nucleus gets increased.

But this property decreases as we move from top to bottom in a group because electrons get add up in the new shells which make them further far away from the nucleus.

For the given options:

Potassium is present in Group 1, Period 4 of the periodic table.

Calcium is present in Group 2, Period 4 of the periodic table.

Copper is present in Group 11, Period 4 of the periodic table.

Bromine is present in Group 17, Period 4 of the periodic table.

Hence, bromine will have the highest electronegativity in Period 4.

To solve this problem, let us first find for the molar mass of Fe2O3 and Fe3O4.

Fe = 55.85 g/mol and O = 16 g/mol

Therefore,

Fe2O3 = 159.7 g/mol

Fe3O4 = 231.55 g/mol

We are given that there are 29 g of Fe2O3, we calculate for the amount of Fe from this in moles:

mol Fe = 29 g Fe2O3 (1 / 159.7 g/mol) (2 mol Fe / 1 mol Fe2O3)

mol Fe = 0.363 mol

Converting this to Fe3O4:

mass Fe3O4 = 0.363 mol Fe (1 mol Fe3O4 / 3 mol Fe) (231.55 g/mol)

mass Fe3O4 = 28.03 g

Therefore there are 28.03g of Fe3O4 in the ore.

The given function is:

P = 120 i / (i^2 + i + 9)

or

P = 120 i (i^2 + i + 9)^-1

The maxima point is obtained by taking the 1st derivative of the function then equating dP / di = 0:

dP / di = 120 (i^2 + i + 9)^-1 + (-1) 120 i (i^2 + i + 9)^-2 (2i + 1)

setting dP / di =0 and multiplying whole equation by (i^2 + i + 9)^2:

0 = 120 (i^2 + i + 9) – 120i (2i + 1)

Dividing further by 120 will yield:

i^2 + i + 9 – 2i^2 – i = 0

-i^2 + 9 =0

i^2 = 9

i = 3      (ANSWER)

Therefore P is a maximum when i = 3

Checking:

P = 120 * 3 / (3^2 + 3 + 9)

P = 17.14

To find the light intensity at which photosynthesis rate for a given phytoplankton species is maximal, you must differentiate the function expressing photosynthesis rate in terms of light intensity, set the derivative equal to zero, and solve for i. This equation's solutions are the critical points where the rate of photosynthesis may reach a maximum.

The question asks when photosynthesis rate (in mg carbon/m3/h) for a certain species of phytoplankton is maximal, given the function p = 120i / (i2 + i + 9) where i stands for light intensity (in 1000s of foot-candles).

To find the maximum value for any given function, you must find the derivative of that function (also referred to as the rate of change) and set it to equal zero. This can be performed using calculus, specifically the application of differentiation rules. Since the given function is a complex fraction, it's necessary to apply the Quotient Rule of differentiation, which states that the derivative of the quotient of two functions is the denominator times the derivative of the numerator minus the numerator times the derivative of the denominator all over the square of the denominator.

Once you have found the derivative, you find its roots by solving for i when the derivative equals zero. These i values provide the inflection points of the initial function which correspond to either the maximum or minimum values of p (these can be distinguished by checking a value to the left and right of each root), or where the function has a horizontal tangent.

In this way, the intensity of light at which photosynthesis rate for the phytoplankton is maximal can be derived.

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Explanation:

When we increase temperature of a substance then bond between the atoms will start to break and the molecules will move apart from each other. As a result, there will be increase in number of collisions between the molecules. Thus, reaction will occur at a faster rate.

Also,   K.E = [tex]\frac{3}{2}kT[/tex]

where          k = boltzmann constant

                    T = temperature

Hence, kinetic energy is proportional to temperature. So, more is the temperature more will be the kinetic energy. Therefore, more will be the rate of reaction.

Ans: B) Time

Rate is a measure of change of a particular property over a certain time period. The property could be concentration, volume, mass etc.

Mathematically, if x denotes a certain property and t denotes the time then:

Rate = Δx/Δt = x2-x1/t2-t1

x1 and x2 are the initial and final values of the measured property measured at time t1 and t2 respectively.

Thus, rate is related to time.

Answer: There are 1.216×10^26 protons in 20.02mole of neon

Explanation:

Using Avogadro's number

1 mole of neon contains 6.023×10^23 neon atoms.

I atm contains 10 protons

Number of protons = (6.023×10^23)×20.02×10= 1.216×10^26

Answer:

65,179.487 g/mol is the molar mass of fungal laccase.

Explanation:

Percentage of copper in Fungal laccase = 0.390

Molar mass of fungal laccase = M

Number of copper atom in 1 fungal laccase molecule = 4

Atomic mass of copper = 63.55 g/mol

Percentage of an element in a compound:

[tex]\frac{\text{Number of atoms of element}\times \text{Atomic mass of element}}{\text{molecular mass of compound}}\times 100[/tex]

Percentage of copper:

[tex]\frac{4\times 63.55 g/mol}{M}\times 100=0.390\%[/tex]

[tex]M=\frac{4\times 63.55 g/mol}{0.390}\times 100[/tex]

M = 65,179.487 g/mol

65,179.487 g/mol is the molar mass of fungal laccase.

To solve this problem, let us all convert the mass of each element into number of moles using the formula:

moles = mass / molar mass

Where,

molar mass K = 39.10 g / mol

molar mass Cl = 35.45 g / mol

molar mass O = 16 g / mol

and mass O = 13 g – 4.15 g – 3.76 g  = 5.09 g

moles K = 4.15 g / (39.10 g / mol) = 0.106 mol

moles Cl = 3.76 g / (35.45 g / mol) = 0.106 mol

moles O = 5.09 g / (16 g / mol) = 0.318 mol

The ratio becomes:

0.106 K: 0.106 Cl: 0.318 O

We divide all numbers with the smallest number, in this case 0.106. This becomes:

K: Cl: 3O

Therefore the empirical formula is:

[tex] KClO_{3} [/tex]

The pH of solution is calculated using the formula:

pH = - log [H]

where [H] is the concentration of H+ ion in molarity

H+ concentration when pH = 2:

2 = - log [H]

[H] = 0.01 M

H+ concentration when pH = 13:

13 = - log [H]

[H] = 1 x 10^-13 M

The difference is therefore:

0.01 M - 1 x 10^-13 M = 0.01 M

The concentration at pH=13 is so small that it can be considered negligible.

Answer:

The pH of solution is calculated using the formula:

pH = - log [H]

where [H] is the concentration of H+ ion in molarity

H+ concentration when pH = 2:

2 = - log [H]

[H] = 0.01 M

H+ concentration when pH = 13:

13 = - log [H]

[H] = 1 x 10^-13 M

The difference is therefore:

0.01 M - 1 x 10^-13 M = 0.01 M

The concentration at pH=13 is so small that it can be considered negligible.

Explanation:

Did your response contain the following points? You may have discussed additional points that are not listed here.  

Both carbohydrate and fat molecules release energy when cells break them down.

Many carbohydrates contain fiber, which the body cannot break down but which can help the digestive system function.

Sterols are important lipids that cells can convert into compounds the body needs, such as vitamins, some hormones, and bile salts.

Phospholipids are important structural components of cells.

The correct answer is 'a'. In covalent bonds, two atoms share electrons, while in ionic bonds, two atoms of opposite charge are attracted to each other.

In a covalent bond, two atoms share electrons to achieve a stable electron configuration. This sharing of electrons allows both atoms to fill their outermost energy levels and become more stable. An example of a covalent bond is the bond between two hydrogen atoms in a hydrogen molecule . In this case, both hydrogen atoms share their single electron to form a stable molecule.

On the other hand, in an ionic bond, two atoms of opposite charge are attracted to each other due to the transfer of electrons. One atom loses electrons to become positively charged (cation), while the other atom gains electrons to become negatively charged (anion). These oppositely charged ions are then attracted to each other, forming an ionic bond.Thus, the correct option is 'A'.

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The coefficient in front of CO2 in the reaction: C5H12 + 8O2 → 5CO2 + 6H2O is 5.

BALANCING A CHEMICAL EQUATION:

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Final answer:

The coefficient in front of carbon dioxide (CO2) when balancing the reaction C5H12 + O2 → CO2 + H2O is 5, as we need 5 CO2 molecules to match the 5 carbon atoms in C5H12.

Explanation:

To find the coefficient in front of carbon dioxide (CO2) when the given reaction C5H12 + O2 → CO2 + H2O is balanced, we first balance carbon (C) and hydrogen (H) atoms, since they appear in only one reactant and one product each. Then we adjust the oxygen (O) atoms. For the given reaction:

The balanced chemical equation is:

1 C5H12 + 8 O2 → 5 CO2 + 6 H2O

Checking the balanced equation: There are 5 carbon atoms, 12 hydrogen atoms, and 16 oxygen atoms on both sides of the equation, thus confirming the reaction is balanced.

Answer:

the number of solute particles

Explanation:

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The rate of the forward reaction where dinitrogen tetroxide decomposes to nitrogen dioxide starts high and gradually decreases until it levels out above zero, due to reaching a state of dynamic equilibrium.

In the reaction where dinitrogen tetroxide decomposes to produce nitrogen dioxide, the graph of the rate of the forward reaction over time would start high and gradually decrease until it levels out above zero. This is because when the reaction begins, the concentration of reactant (dinitrogen tetroxide in this case) is at its maximum, thus the rate of the forward reaction is high. However, as the reaction progresses and more product (nitrogen dioxide) is generated, the concentration of dinitrogen tetroxide decreases and thus the rate of the forward reaction also decreases. This continues until a dynamic equilibrium is reached where the rate of the forward reaction equals the rate of the reverse reaction and the concentrations of reactant and product are constant.

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The rate of the forward reaction in the decomposition of N₂O₄ to NO₂ starts at zero, increases as the reaction proceeds, and levels out above zero once dynamic equilibrium is reached, where it becomes equal to the reverse reaction rate.

When dinitrogen tetroxide (N₂O₄) decomposes to produce nitrogen dioxide (NO₂), we observe the concept of chemical equilibrium in a closed system. Initially, the rate of the forward reaction, which is the decomposition of N₂O₄ to 2NO₂, starts at zero because there is no NO₂ to decompose. As the decomposition proceeds, this rate increases as more N₂O₄ is converted to NO₂. Over time, the forward reaction rate gradually increases and then levels out above zero when dynamic equilibrium is reached. At equilibrium, the rate of the forward reaction becomes equal to the rate of the reverse reaction, which is the dimerization of NO₂ to reform N₂O₄.

The ions present in the solution of [tex]\rm Na_3PO_4[/tex] will be [tex]\rm Na^+\,,\;PO_4^-\;,\;H_2PO_4^-\;,\;HPO_4^2^-[/tex].

The solution of [tex]\rm Na_3PO_4[/tex] will results in the dissociation of the molecule.

The dissociation will be:

[tex]\rm Na_3PO_4\;\rightarrow\;3\;Na_+\;+\;PO_4^-[/tex]

Thus the dissociation will result in the 3 sodium ions and 1 phosphate ion. The phosphate ion in the water solution will form phosphonium ions as well.

Thus the ions in the solution will be:

[tex]\rm Na^+\,,\;PO_4^-\;,\;H_2PO_4^-\;,\;HPO_4^2^-[/tex].

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