The pH of the ECF is maintained in homeostatic balance by which chemical buffer system?
a. protein
b. bicarbonate
c. phosphate
d. lipid

102.35 g of ZnO contains approximately 7.565 × 10^23 atoms.

To convert grams of a substance to atoms, you need to use the concept of molar mass and Avogadro's number.

The molar mass of ZnO (zinc oxide) is calculated by adding the atomic masses of zinc (Zn) and oxygen (O):

Zn: atomic mass = 65.38 g/mol

O: atomic mass = 16.00 g/mol

Molar mass of ZnO = (1 × Zn atomic mass) + (1 × O atomic mass)

= (1 × 65.38 g/mol) + (1 × 16.00 g/mol)

= 81.38 g/mol

Now, we can calculate the number of moles of ZnO:

Number of moles = mass of ZnO / molar mass of ZnO

= 102.35 g / 81.38 g/mol

≈ 1.257 mol

Finally, we can convert moles to atoms using Avogadro's number, which states that 1 mole of any substance contains 6.022 × 10^23 particles (atoms, molecules, ions, etc.):

Number of atoms = number of moles × Avogadro's number

= 1.257 mol × (6.022 × 10^23 atoms/mol)

≈ 7.565 × 10^23 atoms

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Answer:

a.

Na2CO3 (aq) + 2 HCl (aq) → H2O (l) + CO2 (g) + 2 NaCl (aq)

b.

0.0783 mols of HCl

Explanation:

Na2CO3 (aq) + 2 HCl (aq) → H2O (l) + CO2 (g) + 2 NaCl (aq)

n= 1 n= 2

Mr = 106 Mr= 36.5

m= 106g m= 73g

106 g Na2CO3 reacts with 73 g HCl

1 g Na2CO3 will react with 73/106 g HCl

4.15 g Na2CO3 will react with (73/106)× 4.15 = 2.858 g HCl

number of moles = mass/ Mr

num of moles of HCL = 2.858/36.5

= 0.07830188678

= 0.0783 mols

a. Balanced equation with state symbols:

Solid sodium carbonate (Na₂CO₃(s)) + Aqueous hydrochloric acid (2HCl(aq)) = Aqueous sodium chloride (2NaCl(aq)) + Carbon dioxide (CO₂(g)) + Water (H₂O(l))

b. 0.05 moles of HCl is required to react with 4.15 g of sodium carbonate.

To calculate the number of moles of hydrochloric acid (HCl) required to react with 4.15 g of sodium carbonate (Na₂CO₃), we first need to determine the molar mass of Na₂CO₃.

Molar mass of Na₂CO₃:

2(Na) + 1(C) + 3(O) = 2(23.0 g/mol) + 12.0 g/mol + 3(16.0 g/mol) = 46.0 g/mol + 12.0 g/mol + 48.0 g/mol = 106.0 g/mol

Next, we can use the given mass and molar mass to calculate the number of moles of Na₂CO₃:

Number of moles = Mass / Molar mass

Number of moles = 4.15 g / 106.0 g/mol ≈ 0.0391 moles

According to the balanced equation, 1 mole of Na₂CO₃ reacts with 2 moles of HCl. Therefore, the number of moles of HCl required to react with 0.0391 moles of Na₂CO₃ is:

Number of moles of HCl = 2 × 0.0391 moles ≈ 0.0782 moles

Thus, 0.0782 moles of HCl (or approximately 0.05 moles when rounded to two decimal places) are required to react exactly with 4.15 g of sodium carbonate.

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When 12 moles of methane are burned, approximately 9600 kj of heat will be produced.

To calculate the amount of heat produced when 12 moles of methane (CH4) are burned, we first need to determine the mass of methane in grams.

One mole of methane has a molecular weight of 16 g/mol (1 carbon atom with a weight of 12 g/mol and 4 hydrogen atoms with a weight of 1 g/mol each). Therefore, 12 moles of methane would have a mass of 12 x 16 = 192 g.

Next, we can calculate the total heat produced using the heat of combustion of methane, which is 50 kj/g.

The total heat produced when 192 g of methane are burned can be calculated as follows:

Total heat = mass x heat of combustion
Total heat = 192 g x 50 kj/g
Total heat = 9600 kj

Therefore, when 12 moles of methane are burned, approximately 9600 kj of heat will be produced.

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The addition of HX to an alkyne occurs in two steps, each of which follows Markovnikov's rule so that in each step the hydrogen adds to the less substituted carbon atom and the halogen adds to the more substituted carbon atom.

In the first step, the alkyne undergoes protonation by the hydrogen halide (HX) resulting in the formation of a vinyl carbocation intermediate. Since the vinyl carbocation is less stable than the alkyl carbocation, the hydrogen adds to the less substituted carbon atom.

In the second step, the halide ion (X-) acts as a nucleophile, attacking the vinyl carbocation. The halogen adds to the more substituted carbon atom, leading to the formation of the final product.

This two-step addition process allows for the sequential addition of hydrogen and halogen, following Markovnikov's rule.

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Answer:  1.20 × 1023 molecules

Explanation: At about 891 kJ/mol, methane's heat of combustion is lower than that of any other hydrocarbon, but the ratio of the heat of combustion (891 kJ/mol) to the molecular mass (16.0 g/mol, of which 12.0 g/mol is carbon) shows that methane, being the simplest hydrocarbon

The element with the most similar boiling point to rubidium is likely to be caesium, while the least similar is likely to be xenon.

Rubidium is a Group 1 alkali metal with a boiling point of 688°C. The Group 1 elements have similar chemical properties and boiling points that increase down the group. Therefore, the element with the most similar boiling point to rubidium is likely to be the heaviest alkali metal, caesium, which has a boiling point of 671°C, just 17°C lower than rubidium.

On the other hand, the noble gas xenon has a boiling point of -108°C, making it the least likely element to have a similar boiling point to rubidium. Noble gases have very low boiling points due to their full valence electron shells, which makes it difficult to excite their electrons and turn them into a gas. Therefore, xenon is unlikely to have a similar boiling point to rubidium.

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The hydrogen cyanide (HCN) molecule consists of three atoms: hydrogen (H), carbon (C), and nitrogen (N). It forms a linear molecular structure. In HCN, the bond between carbon and nitrogen is a triple bond (C≡N), which consists of one sigma bond and two pi bonds.

The sigma bond is formed by the overlap of one hybridized orbital from carbon and one hybridized orbital from nitrogen. The two pi bonds are formed by the overlap of unhybridized p orbitals, one from each atom.

The sigma bond provides strong and direct bonding, while the pi bonds contribute to the overall stability of the molecule. Therefore, the HCN molecule contains one sigma bond and two pi bonds.

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The temperature required to make the reaction spontaneous under standard conditions is approximately 1078 K.

Part A:

To determine if the reaction is spontaneous under standard conditions, we need to calculate the standard free energy change of the reaction (ΔG∘rxn) using the standard free energies of formation (ΔG∘f) of the reactants and products:

ΔG∘rxn = ΣnΔG∘f(products) - ΣmΔG∘f(reactants)

The values of ΔG∘f for N2O(g), NO2(g), and NO(g) are:

ΔG∘f(N2O(g)) = 104.1 kJ/mol

ΔG∘f(NO2(g)) = 51.3 kJ/mol

ΔG∘f(NO(g)) = 86.7 kJ/mol

Substituting these values into the equation, we get:

ΔG∘rxn = 3(86.7 kJ/mol) - (104.1 kJ/mol + 51.3 kJ/mol) = -39.3 kJ/mol

Since ΔG∘rxn is negative, the reaction is spontaneous under standard conditions in the reverse direction, from right to left. However, in the forward direction (from left to right), the reaction is not spontaneous.

Part B:

If a reaction mixture contains only N2O and NO2 at partial pressures of 1.0 atm each, the reaction will be spontaneous until some NO forms in the mixture. To find the maximum partial pressure of NO before the reaction ceases to be spontaneous, we can use the expression for the reaction quotient (Qc) and the equilibrium constant (Kc):

Qc = [NO]3/([N2O][NO2])

Kc = [NO]3/([N2O][NO2])

When the reaction mixture reaches equilibrium, Qc = Kc. Let x be the equilibrium partial pressure of NO. Then we have:

x3/(1.0 atm)(1.0 atm) = Kc

x3 = Kc

x = (Kc)^(1/3)

Substituting the value of Kc at 298 K, which can be calculated using the standard free energy change of the reaction (ΔG∘rxn) and the relation ΔG∘rxn = -RTlnK, where R is the gas constant and T is the temperature in kelvin, we get:

ΔG∘rxn = -RTlnKc

-39.3 kJ/mol = -(8.314 J/mol-K)(298 K)lnKc

lnKc = 16.0

Kc = e^(16.0) = 8.89 × 10^6

Therefore, the maximum partial pressure of NO that builds up before the reaction ceases to be spontaneous is:

x = (8.89 × 10^6)^(1/3) ≈ 197 atm

Part C:

To make the reaction spontaneous under standard conditions, we need to find the temperature at which ΔG∘rxn becomes negative. Since ΔG∘rxn is a function of temperature, we can use the relation ΔG∘rxn = ΔH∘rxn - TΔS∘rxn, where ΔH∘rxn and ΔS∘rxn are the standard enthalpy and entropy changes of the reaction, respectively. At the temperature T where ΔG∘rxn becomes negative, we have:

ΔH∘rxn = TΔS∘rxn

Let's assume that ΔH∘rxn and ΔS∘rxn are temperature-independent over a small temperature range around 298 K, so we can use the values of ΔH∘rxn and ΔS∘rxn at 298 K to estimate the temperature at which ΔG∘rxn becomes negative. The values of ΔH∘rxn and ΔS∘rxn for the reaction are:

ΔH∘rxn = -190.2 kJ/mol

ΔS∘rxn = -176.6 J/mol-K

Substituting these values into the equation, we get:

-190.2 kJ/mol = T(-176.6 J/mol-K)

T ≈ 1078 K

Therefore, the temperature required to make the reaction spontaneous under standard conditions is approximately 1078 K.

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The specific heat capacity of the metal is 1.672 J/g°C.

Using the formula:

Q = m * c * ΔT

where Q is the heat transferred, m is the mass, c is the specific heat capacity, and ΔT is the change in temperature, we can solve for the specific heat capacity of the metal.

Assuming no heat is lost to the surroundings, the heat transferred from the metal to the water is equal to the heat gained by the water:

Qmetal = Qwater

(metal specific heat) x (metal mass) x (final temperature - initial temperature) = (water specific heat) x (water mass) x (final temperature - initial temperature)

Solving for the specific heat of the metal:

c = [(water specific heat) x (water mass) x (final temperature - initial temperature)] / [(metal mass) * (final temperature - initial temperature)]

Plugging in the given values:

c = [(4.18 J/g°C) x (400 g) x (22°C - 20°C)] / [(50 g) x (100°C - 20°C)]

c = 1.672 J/g°C

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The ocean sequesters carbon from dissolved carbon dioxide through a process called oceanic carbon uptake, where carbon is converted into bicarbonate and carbonate ions and stored in the ocean.

When carbon dioxide (CO₂) dissolves in ocean water, it reacts with water molecules to form carbonic acid (H₂CO₃), which then dissociates into bicarbonate ions (HCO₃⁻) and hydrogen ions (H⁺). These bicarbonate ions can further react to form carbonate ions (CO₃²⁻). These carbonate and bicarbonate ions represent a significant portion of the ocean's dissolved inorganic carbon (DIC).

This process of converting carbon dioxide into bicarbonate and carbonate ions, and storing it in the ocean, is known as carbon sequestration. The dissolved carbon dioxide becomes part of the carbon cycle in the ocean, where it can be taken up by marine organisms, such as phytoplankton, and ultimately become part of their biomass. When these organisms die, their remains sink to the ocean floor, where they can be buried and stored for long periods, effectively sequestering carbon from the atmosphere.

Oceanic carbon uptake plays a crucial role in mitigating the effects of anthropogenic carbon dioxide emissions by acting as a carbon sink, helping to regulate atmospheric carbon dioxide levels and reducing its impact on climate change.

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The reactions that follow glycolysis in a fermentation pathway primarily serve to regenerate NAD+ and produce ATP. These reactions allow glycolysis to continue in the absence of oxygen, enabling the cell to sustain its energy needs under anaerobic conditions.

Glycolysis is the initial metabolic pathway that breaks down glucose into pyruvate. In the absence of oxygen, the subsequent reactions of fermentation become essential for cells to generate energy. One of the primary functions of these reactions is to regenerate NAD+. During glycolysis, NAD+ is converted to NADH as it accepts electrons. In fermentation, NADH is then reoxidized back to NAD+ through the transfer of electrons to an organic molecule derived from pyruvate. This step is crucial because NAD+ is required as a cofactor for the continued functioning of glycolysis. By regenerating NAD+, cells can sustain the glycolytic pathway and maintain a steady supply of ATP. Additionally, fermentation pathways generate ATP through substrate-level phosphorylation. In glycolysis, two molecules of ATP are produced. In subsequent fermentation reactions, organic molecules derived from pyruvate act as electron acceptors and are reduced, generating ATP through the transfer of high-energy phosphate groups. The exact mechanism varies depending on the type of fermentation. For example, in lactic acid fermentation, pyruvate is directly converted to lactate, releasing energy that can be used to produce ATP. Similarly, in alcoholic fermentation, pyruvate is converted to ethanol and carbon dioxide, yielding ATP in the process. Overall, the reactions that follow glycolysis in a fermentation pathway serve to replenish NAD+ and generate ATP. These processes allow cells to maintain energy production when oxygen is limited, ensuring their survival under anaerobic conditions.

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The volume of the unit cell of metallic strontium in picometers cubed is approximately 1.93 x 10⁶ pm³ and in cubic centimeters is approximately 1.93 x 10⁻¹⁸cm³

we first need to understand what a face-centered cubic lattice is. In this type of lattice, there is one atom at each corner of a cube and one atom in the center of each face of the cube.

Given that metallic strontium has a metallic radius of 215 pm, we can use this value to calculate the edge length of the unit cell.

The diagonal of a face-centered cubic unit cell can be found using the formula d = a√2, where a is the edge length.

Since the diagonal of a cube is equal to the square root of three times the edge length, we can set up the equation:

d = a√2 = √3a

Solving for a, we get:

a = d/√3 = 215 pm/√3 ≈ 124 pm

Now that we know the edge length of the unit cell, we can calculate the volume.

The volume of a cube is given by the formula V = a³. Therefore, the volume of the unit cell is:

V = (124 pm)³ = 1.93 x 10^6 pm³

Converting this to cubic centimeters (cm³) by dividing by 10²⁴, we get:

V = 1.93 x 10¹⁸ cm³

So the volume of the unit cell of metallic strontium in picometers cubed is approximately 1.93 x 10⁶ pm³ and in cubic centimeters is approximately 1.93 x 10⁻¹⁸cm³

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The reaction involved in preparing margarine from corn oil is the hydrogenation of unsaturated fatty acids present in corn oil.

This process converts the double bonds in the fatty acids into single bonds, resulting in a more solid and saturated fat consistency suitable for margarine production. Margarine is a semi-solid fat commonly made from vegetable oils. To convert a liquid vegetable oil like corn oil into margarine, the process of hydrogenation is employed. Hydrogenation involves the addition of hydrogen gas (H2) to the unsaturated fatty acids present in the oil. Corn oil contains unsaturated fatty acids with double bonds in their carbon chains. These double bonds can be broken through a catalytic hydrogenation reaction, where hydrogen gas is added in the presence of a catalyst, typically nickel or palladium. The double bonds are converted into single bonds, resulting in a more saturated fat composition. This hydrogenation process increases the melting point of the oil, transforming it into a semi-solid consistency suitable for margarine. By controlling the degree of hydrogenation, the texture and consistency of the final product can be adjusted to meet the desired properties of margarine.

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Answer: The hydroxide ion concentration of a solution with a pH of 4 is 10−10 M which is equivalent to pOH of 10.

Explanation:

The pressure of the gas inside the sealed bottle would double if the volume of the gas is reduced by half.

The pressure and volume of a gas are inversely proportional to each other according to Boyle's law. This means that if the volume of a gas is reduced while its temperature remains constant, the pressure of the gas will increase. In this case, squeezing the bottle tightly will reduce the volume of the gas inside by half, which means that the pressure of the gas will double.

This is because the same amount of gas molecules will now occupy half the volume, resulting in the molecules colliding with the walls of the bottle more frequently and with greater force, hence increasing the pressure. This is a fundamental concept in physics and has important applications in fields such as chemistry and engineering.

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The reactant is an Alkene due to the C = C double bond.

So the homologues series is Alkenes.

The volume of NaOH solution needed to reach the equivalence point is 0.0385 times the unknown concentration of the HCl solution.

The concentration of the HCl solution is 1.001 M.

To solve this problem, use the concept of stoichiometry and the balanced chemical equation for the reaction between HCl and NaOH:

HCl + NaOH → NaCl + H₂O

(a) To find the volume of NaOH solution needed to reach the equivalence point, know the number of moles of HCl present in the 25 mL solution:

moles of solute = concentration × volume (in liters)

Since the volume is given in milliliters, convert it to liters by dividing by 1000:

moles of HCl = concentration of HCl × volume of HCl (in liters)

= unknown concentration × 25/1000

= 0.025 × unknown concentration

The balanced chemical equation shows that the stoichiometric ratio of HCl to NaOH is 1:1. Therefore, the number of moles of NaOH needed to react with the HCl is also 0.025 × unknown concentration.

Use the formula for moles of solute again, this time for NaOH, to find the volume needed to reach the equivalence point:

moles of NaOH = concentration of NaOH × volume of NaOH (in liters)

0.025 × unknown concentration = 0.65 × volume of NaOH (in liters)

Solving for the volume of NaOH:

volume of NaOH = (0.025 × unknown concentration) / 0.65

= 0.0385 × unknown concentration

Therefore, the volume of NaOH solution needed to reach the equivalence point is 0.0385 times the unknown concentration of the HCl solution.

(b) To find the concentration of the HCl solution, use the volume of NaOH solution needed to reach the equivalence point, which is found in part (a). At the equivalence point, the number of moles of NaOH added is equal to the number of moles of HCl in the original solution:

moles of NaOH added = moles of HCl in original solution

0.025 × unknown concentration = 0.65 × volume of NaOH (in liters)

Substituting the expression found for volume of NaOH in terms of the unknown concentration:

0.025 × unknown concentration = 0.65 × 0.0385 × unknown concentration

Solving for the unknown concentration:

unknown concentration = (0.65 × 0.0385) / 0.025

= 1.001 M

Therefore, the concentration of the HCl solution is 1.001 M.

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After 3.96 seconds, 0.549 mol/l of the compound is left. The rate constant of a reaction indicates how quickly reactants are being converted into products.

In this case, a rate constant of 0.0735 sec-1 means that 0.0735 moles of the compound react per second. To determine how much of the compound is left after 3.96 seconds, we can use the following equation:

ln([A]/[A]₀) = -kt

Where [A] is the concentration of the compound at time t, [A]₀ is the initial concentration (0.969 mol/l), k is the rate constant (0.0735 sec-1), and t is time (3.96 seconds).

Solving for [A], we get:

[A] = [A]₀ e^(-kt)

Plugging in the values, we get:

[A] = 0.969 mol/l e^(-0.0735 sec-1 * 3.96 sec)

[A] = 0.549 mol/l

Therefore, after 3.96 seconds, 0.549 mol/l of the compound is left.

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Explanation:

During the three hours, a heat flow took place from the boiling water to both the copper and aluminum cubes, as the water was at a higher temperature than the room-temperature cubes. However, the direction of heat flow between the two cubes depends on their respective thermal conductivities, specific heat capacities, and initial temperatures, which are not provided in the question. Therefore, the correct answer cannot be determined based on the information given.

Answer:

from the boiling water to the aluminum cube

Explanation:

: )

The critical feature determining whether a substance is a resource is whether it has economic value and can be used to satisfy human wants and needs.

Without this ability to fulfill a demand, a substance cannot be considered a resource. Additionally, the availability and accessibility of the substance can also play a role in determining its status as a resource.

For something to be considered a resource, it must have some economic value and be able to satisfy human needs or wants in some way. Resources can take many different forms, including natural resources like oil, gas, minerals, and timber, as well as human-made resources like technology, knowledge, and skills.

However, it's worth noting that just because something has economic value doesn't necessarily mean it is a resource in the broader sense of the word. For example, something might have economic value as a luxury item or status symbol, but it might not be essential to meeting human needs or satisfying basic wants.

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The answer is (e) negative negative negative. The process of freezing ice at 263K involves the conversion of water from a liquid to a solid phase.

Enthalpy (ΔH) is the heat energy absorbed or released during a process. In the case of freezing, water molecules lose kinetic energy as they form solid ice, so the process releases heat energy. Therefore, ΔH is negative.

Entropy (ΔS) is a measure of the degree of disorder or randomness of a system. When water freezes, the molecules become more ordered and less random, resulting in a decrease in entropy. Therefore, ΔS is negative.

Gibbs free energy (ΔG) is a measure of the spontaneity of a process. The formula for ΔG is ΔG = ΔH - TΔS, where T is the temperature in Kelvin. In the case of freezing, ΔH is negative and ΔS is negative, meaning that the second term in the formula (TΔS) is positive. At temperatures below the freezing point of water, TΔS is larger in magnitude than ΔH, so ΔG is negative, indicating that the process is spontaneous. Therefore, ΔG is negative.

Therefore, the signs of ΔH, ΔS, and ΔG for the freezing of ice at 263K are:

ΔH = negative

ΔS = negative

ΔG = negative

The answer is (e) negative negative negative.

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Sodium (Na) has a smaller radius than Cesium (Cs) due to the increase in number of electron shells in Cs compared to Na.

The atomic radius of an element is determined by the number of electron shells it has. As you move down a group in the periodic table, the number of electron shells increases, resulting in larger atomic radius. Sodium and Cesium belong to the same group in the periodic table, but Cesium has one additional electron shell than Sodium.

This increase in the number of electron shells leads to an increase in atomic radius, making Cesium have a larger atomic radius than Sodium. Therefore, Sodium has a smaller radius than Cesium.

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Answer:

Will the volume of a gas increase or decrease if the temperature increased and the pressure increased

Answer:

The molecular formula of fructose is C6H12O6

Explanation:

The molecular formula isthe actual whole number ratio of atoms of each element.

When soda is exposed to room temperature, the carbon dioxide molecules that give it its fizziness start to escape. This process is known as carbonation loss.

As carbon dioxide escapes, the soda becomes less carbonated and loses its characteristic fizziness. This change in carbonation levels affects the taste of the soda, making it taste flat and less refreshing. The loss of carbon dioxide also affects the texture of the drink, making it feel less bubbly in the mouth. To prevent carbonation loss, it is recommended to store soda in a cool, dark place, such as a refrigerator, to keep it fresh and maintain its carbonation levels.

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The atomic size generally decreases from left to right across a period in the periodic table and increases from top to bottom within a group.

Fluorine (F) is located on the right side of the periodic table and has a small atomic radius due to the strong attraction between the valence electrons and the nucleus. Neon (Ne) is located to the left of fluorine, in the noble gases group, and has a larger atomic radius than fluorine due to its additional electron shell. Sodium (Na) is located to the left of neon, in the alkali metals group, and has a much larger atomic radius due to its much larger atomic size.

Therefore, the correct order of the given elements in decreasing atomic size is:

Na > Ne > F

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Chromium(III) chlorate (Cr(ClO3)3) is a solid (s) that dissolves in water to form aqueous chromium(III) ions (Cr^3+, aq) and 3 aqueous chlorate ions (ClO3^-, aq). The coefficients represent the lowest possible whole numbers to balance the equation.

When Cr(ClO3)3 is dissolved in water, it dissociates into its respective ions. The balanced chemical equation for the dissolution of Cr(ClO3)3 can be written as:

Cr(ClO3)3(s) → Cr3+(aq) + 3ClO3-(aq)

This equation shows that one molecule of solid Cr(ClO3)3 dissociates into one Cr3+ ion and three ClO3- ions in aqueous solution. The state-of-matter for Cr(ClO3)3 is solid (s), while the state-of-matter for Cr3+ ion and ClO3- ions is aqueous (aq). The coefficients in the equation are already in their lowest possible whole number form.

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The new volume of the gas at a pressure of 0.800atm is 99.44 m. To solve this problem, we need to use Boyle's Law which states that the volume of a gas is inversely proportional to its pressure, at constant temperature. So, we can use the following formula:

P1V1 = P2V2

Where P1 is the initial pressure (795.5 mm. hg.), V1 is the initial volume (100.0ml), P2 is the final pressure (0.800atm) and V2 is the final volume (unknown).

Substituting the given values, we get:

795.5 mm. hg. x 100.0ml = 0.800atm x V2

Simplifying the equation, we get:

V2 = (795.5 mm. hg. x 100.0ml) / (0.800atm)

V2 = 99437.5 ml/atm or 99.44 ml (rounded to two decimal places)

Therefore, the new volume of the gas at a pressure of 0.800atm is 99.44 ml.

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If Planck's constant were approximately 50% bigger, atoms would be smaller. This is because Planck's constant plays a role in determining the energy levels and wavelengths of electrons in an atom.

With a larger Planck's constant, the energy levels and wavelengths would be smaller, meaning the electron orbits would be smaller and closer to the nucleus. This would result in a smaller overall size for the atom.

Planck's constant, denoted as "h," is a fundamental constant of nature that relates the energy of a photon to its frequency. It was first introduced by German physicist Max Planck in 1900 to explain the behavior of electromagnetic radiation emitted by heated objects, known as blackbody radiation.

The value of Planck's constant is approximately 6.626 x 10^-34 joule-second (J s). It is a key parameter in quantum mechanics and plays a critical role in determining the energy levels of atoms and molecules, the behavior of electrons in solids, and the functioning of many modern technologies, such as lasers, LEDs, and solar cells.

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