What intermediate is believed to occur in the elimination-addition nucleophilic aromatic substitution mechanism on benzene?

Protonation of a functional group, like an alcohol or an oxygen, generally does the following:

1. Increases the acidity of the functional group: Protonation adds a hydrogen ion (H+) to the functional group, which increases its acidity by creating a positive charge on the molecule.

2. Makes the functional group more reactive: The addition of a hydrogen ion increases the reactivity of the functional group, making it more likely to participate in chemical reactions.

3. Changes the polarity of the functional group: Protonation affects the distribution of electron density within the functional group, altering its polarity and potentially affecting its solubility and other properties.

In summary, protonation of a functional group like alcohol or oxygen increases its acidity, reactivity, and changes its polarity.

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The pH of the buffer containing 0.800 molar acetic acid and 1.00 molar sodium acetate is  approximately 4.84.

To calculate the pH of a buffer containing 0.800 M acetic acid and 1.00 M sodium acetate, you can use the Henderson-Hasselbalch equation:

pH = pKa + log10([A-]/[HA])

Here, pKa is the negative logarithm of the acid dissociation constant (Ka) for acetic acid, [A-] is the concentration of the conjugate base (acetate ion from sodium acetate), and [HA] is the concentration of the weak acid (acetic acid).

The pKa of acetic acid is approximately 4.74. Plugging the concentrations into the equation:

pH = 4.74 + log10(1.00 M / 0.800 M)

pH ≈ 4.74 + 0.1

pH ≈ 4.84

So, the pH of the buffer solution is approximately 4.84.

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The correct option is a. The temperature and radius of the object.

The luminosity (or wattage) of a heated, opaque, object emitting continuous radiation (perfect ""black body"" like a star) is determined solely by its temperature and radius, according to the Stefan-Boltzmann Law. This law states that the energy radiated by a black body is proportional to the fourth power of its absolute temperature (in Kelvin) and its surface area. Specifically, the luminosity is proportional to the fourth power of the temperature multiplied by the surface area of the object.

Mass and color do not directly determine the luminosity of a black body. However, the temperature and radius of the object can indirectly affect its color, as hotter objects tend to emit bluer light while cooler objects tend to emit redder light.

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According to the forces of attraction present in water the properties of liquid water are  it has a very high boiling point when compared to other compounds of similar molecular weight and  it can dissolve polar substances, ionic substances, and even some non-polar gases.

Forces of attraction  is a force by which atoms in a molecule  combine. it is basically an attractive force in nature.  It can act between an ion  and an atom as well.It varies for different  states  of matter that is solids, liquids and gases.

The forces of attraction are maximum in solids as  the molecules present in solid are tightly held while it is minimum in gases  as the molecules are far apart . The forces of attraction in liquids is intermediate of solids and gases.

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To adjust the pH of a 1 L phosphate buffer solution from 7.6 to the desired pH of 7.2, you should:

1. Recognize that the pKa value closest to the desired pH of 7.2 is 7.2 (among the given pKa values for phosphoric acid: 2.2, 7.2, and 12.3).
2. Understand that you will be working with the second acid-base equilibrium of phosphoric acid (H2PO4- and HPO4^2-) since their pKa value is 7.2.
3. If the current pH is 7.6 and you want to lower it to 7.2, you will need to add an acid to the solution to increase the concentration of H2PO4- ions and decrease the concentration of HPO4^2- ions.
4. The best choice for an acid is a dilute solution of a strong acid, such as hydrochloric acid (HCl), as it will dissociate completely and not affect the buffer's composition significantly, other than the desired pH change.
5. Add the dilute HCl solution dropwise to the 1 L phosphate buffer while stirring and continuously monitoring the pH until it reaches the desired pH of 7.2.

So, by carefully adding a dilute strong acid like HCl to the phosphate buffer, you can adjust the pH from 7.6 to the desired 7.2, ensuring that the buffer functions correctly in your experimental procedure.

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a) The weight of Mg-24 atom is 3.976 x 10⁻²² g or 39.76 μg, b) The weight of the given atom is 8.399 amu c) The total mass of 10,000 atoms of 24-Mg is 3.976 x 10⁻¹⁹ kg.

a) To convert the weight of Mg-24 atom from atomic mass units (amu) to grams and micrograms, we need to multiply the given weight by the conversion factor of 1.661 x 10⁻²⁴ g/amu. Therefore,

Weight in grams = 23.985 amu x 1.661 x 10⁻²⁴ g/amu = 3.976 x 10⁻²² g

Weight in micrograms = 3.976 x 10⁻²² g x 10⁶ μg/g = 39.76 μg

b) To convert the given weight of an atom in grams to atomic mass units (amu), we need to divide the weight by the conversion factor of 1.661 x 10⁻²⁴ g/amu.

Weight in amu = 1.395 x 10⁻²² g / (1.661 x 10⁻²⁴ g/amu) = 8.399 amu

c) The total mass of 10,000 atoms of 24-Mg can be calculated by multiplying the weight of one Mg-24 atom by 10,000. Therefore,

Total mass = 23.985 amu x 1.661 x 10⁻²⁴ g/amu x 10,000 = 3.976 x 10⁻¹⁹ kg.

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Nitrogen dioxide, NO2, an air pollutant, dissolves in rainwater to form a dilute solution of nitric acid. The equation for the reaction is 3NO2(g) + H2O(l) → 2HNO3(l) + NO(g). So, the standard entropy change for the reaction is -536.0 J/K.

To calculate ∆So for the reaction, we need to determine the standard entropy change (∆So) for each of the products and reactants, and then use them in the equation:

∆So = ΣS°(products) - ΣS°(reactants)

The standard entropy values can be found in a thermodynamics table, and for this reaction they are:

S°(NO₂(g)) = 239.9 J/K
S°(H₂O(l)) = 69.9 J/K
S°(HNO₃(l)) = 146.8 J/K
S°(NO(g)) = 240.0 J/K

Substituting these values into the equation, we get:

∆So = [2(146.8 J/K) + 240.0 J/K] - [3(239.9 J/K) + 69.9 J/K]
∆So = 293.6 J/K - 829.6 J/K
∆So = -536.0 J/K

Therefore, by calculating we can say that the standard entropy change for the reaction is -536.0 J/K.

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Isotactic PMMA has a lower Tg because it is strongly influenced by its stereochemical structure and the degree of order and packing of its polymer chains.

The glass transition temperature (Tg) is the temperature at which a polymer changes from a glassy state to a more rubbery state.

The Tg is influenced by the arrangement of the monomers within the polymer chains, which is referred to as tacticity.

Isotactic PMMA has a regular arrangement of the methyl groups on the same side of the polymer chain, while syndiotactic PMMA has alternating positions of the methyl groups along the chain.

The isotactic arrangement allows for closer packing of the polymer chains due to the uniformity of the side groups.

This results in stronger van der Waals forces between the chains, which allows for more efficient packing of the polymer chains.

In contrast, syndiotactic PMMA's alternating arrangement of methyl groups leads to a more irregular packing of the polymer chains.

This reduces the strength of the van der Waals forces between the chains, making the packing less efficient.

As a result, isotactic PMMA has a lower Tg than syndiotactic PMMA due to the stronger intermolecular forces and more efficient packing of the polymer chains.

This enables isotactic PMMA to become more flexible and rubbery at lower temperatures compared to its syndiotactic counterpart.

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The groups can be ranked in order of increasing activating power as follows: -Br < -CH2CH3 < -OCH3 < -OCOCH2CH3

The activating power of a group in electrophilic aromatic substitution reactions is determined by its ability to donate electrons to the ring. The more electron-donating the group is, the more it activates the ring towards electrophilic attack.
In this case, the bromine (-Br) group is the least activating because it is electron-withdrawing due to its high electronegativity. The ethyl (-CH2CH3) group is slightly more activating than -Br because it has some electron-donating properties. The methoxy (-OCH3) group is more activating than -CH2CH3 because it has a stronger electron-donating ability through resonance. Finally, the ester (-OCOCH2CH3) group is the most activating because it has both resonance and inductive electron-donating effects.

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We would need 15 moles of H2 to react with 5 moles of Cr2O3 and convert it to pure chromium.

The balanced chemical equation for the reaction between chromium(III) oxide (Cr2O3) and hydrogen gas (H2) is:

Cr2O3 + 3H2 → 2Cr + 3H2O

This equation tells us that 1 mole of Cr2O3 reacts with 3 moles of H2 to produce 2 moles of Cr and 3 moles of H2O.

If we want to know how many moles of H2 are needed to react with 5 moles of Cr2O3, we can use a proportion:

1 mole Cr2O3 : 3 moles H2 = 5 moles Cr2O3 : x moles H2

Solving for x, we get:

x = (3 moles H2 / 1 mole Cr2O3) * 5 moles Cr2O3

x = 15 moles H2

So, we would need 15 moles of H2 to react with 5 moles of Cr2O3 and convert it to pure chromium.

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True. In an endothermic reaction, thermal energy is absorbed from the surroundings and flows into the reaction, making the surroundings cooler.

The thermal energy flows into the reaction and out of the surroundings in an endothermic reaction. In an endothermic reaction, energy is absorbed from the surroundings, causing the temperature of the surroundings to decrease. This energy transfer results in an increase in the internal energy of the system undergoing the reaction. This results in an increase in the internal energy of the system, which is why endothermic reactions often feel cold.

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The correct name for Mg3(PO4)2 is C) magnesium phosphate.

First, we need to determine the charge of the magnesium ion (Mg2+) and the phosphate ion (PO43-) in the compound.

The magnesium ion has a 2+ charge, since it is a group 2 metal and typically loses two electrons to form a cation.

The phosphate ion has a 3- charge, since it has one phosphorus atom with a 5+ charge and four oxygen atoms with a 2- charge each.

To balance the charges in the compound, we need three magnesium ions (3 x 2+ = 6+) and two phosphate ions (2 x 3- = 6-). This gives us the formula Mg3(PO4)2.

Now we can use the rules for naming ionic compounds to arrive at the correct name.

First, we name the cation (Mg2+) and then the anion (PO43-). Since phosphate is a polyatomic ion, we do not change the name, so it remains as "phosphate".

Next, we need to indicate the charge on the phosphate ion using a Roman numeral in parentheses. Since we have two phosphate ions in the formula, the charge on each ion must be 3- / 2 = 1.5-. This is not a whole number, so we round to the nearest whole number, which is 2-. Therefore, the correct name for the phosphate ion is "phosphate (II)".

Finally, we put the two parts together to get the full name: "magnesium phosphate dibasic".

So the correct answer is C) magnesium phosphate dibasic.

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The boiling point of liquid hydrogen is (a) -252.85°C on the Celsius scale and (b) -423.13°F on the Fahrenheit scale.

To convert the boiling point of liquid hydrogen, which is 20.3 K, to (a) the Celsius scale and (b) the Fahrenheit scale, follow these steps:
(a) Celsius scale:
1. Subtract 273.15 from the Kelvin temperature.
2. The result is the temperature in Celsius.

20.3 K - 273.15 = -252.85°C

(b) Fahrenheit scale:
1. Convert the Celsius temperature to Fahrenheit using the formula: F = (C × 9/5) + 32
2. The result is the temperature in Fahrenheit.

-252.85°C × 9/5 + 32 = -423.13°F

In conclusion, the boiling point of liquid hydrogen is (a) -252.85°C on the Celsius scale and (b) -423.13°F on the Fahrenheit scale.

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1.4 moles. of calcium chloride are theoretically produced for the following reaction given we have 2.6 moles of HCl and 1.4 moles of [tex]Ca(OH)$_2$[/tex].option (c)

To determine the number of moles of calcium chloride [tex]CaCl$_2$[/tex] produced in the reaction, we first need to identify the limiting reactant, which we determined in the previous question to be [tex]Ca(OH)$_2$[/tex].

Using the stoichiometry of the balanced chemical equation, we can see that for every 1 mole of [tex]Ca(OH)$_2$[/tex], 1 mole of [tex]CaCl$_2$[/tex]is produced. Therefore, if 1.4 moles of [tex]Ca(OH)$_2$[/tex] is used up, then 1.4 moles of [tex]CaCl$_2$[/tex] would be produced.

Therefore, the answer is C) 1.4 moles.

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The value of ∆Go373 in kJ for the following reaction at 100 C using data in the Table of Standard Enthalpies and Table of Standard Entropies is  -91.7 kJ (approx.)

To calculate the value of ΔGₒ373 in kJ for the reaction C₂H₄(g) + H₂(g) → C₂H₆(g) at 100°C using the given data, we will use the equation:

ΔGₒ373 = ΔHₒ - (373K)ΔSₒ

First, calculate ΔHₒ:
ΔHₒ = [(1 mol)(-84.667 kJ/mol)] - [(1 mol)(52.284 kJ/mol) + (1 mol)(0 kJ/mol)] = -137.0 kJ

Next, calculate ΔSₒ:
ΔSₒ = [(1 mol)(229 J/molK)] - [(1 mol)(219.8 J/molK) + (1 mol)(130.6 J/molK)] = -121.4 J/molK

Now, plug these values into the equation:
ΔGₒ373 ≈ (-137 x 10³ J/mol) - (373K)(-121.4 J/molK) = -91.7 kJ

So, the value of ΔGₒ373 for this reaction at 100°C is approximately -91.7 kJ.

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The process you are referring to is called Fractional distillation.

Fractional distillation is a process used to separate two or more components from a solution when their boiling points have a difference of 25°C or greater. This method works by heating the mixture to a temperature between the boiling points of the two components, causing the component with the lower boiling point to evaporate first. The vapor is then condensed and collected separately from the remaining component in the solution.

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The length of the object below with accuracy and to the correct degree of precision is 12.5 cm. So, the correct answer is B).

The scale shows a reading that falls between the mark of 12 cm and its adjacent division. As each unit on the scale is equal to 1 mm, the length between two sub units is equal to 0.5 mm.

Therefore, since the scale reading falls somewhere between 1 mm unit of length, it can be taken as half of it, which is 0.05 mm. Thus, the total length of the object is 12.5 cm or 12.05 mm.

This calculation demonstrates the importance of precision in measurements and the need to take into account the scale's increments to ensure accurate results. So, the correct option is B).

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--The given question is incomplete, the complete question is given

" Determine the length of the object below with accuracy and to the correct degree of precision.

Use this media to help you complete the question.

12.48 cm

12.5 cm

12.10 cm

12 cm "--

LiAlH4 (lithium aluminum hydride) and NaBH4 (sodium borohydride) are both reducing agents commonly used in organic chemistry to reduce carbonyl compounds (such as aldehydes, ketones, and carboxylic acids) to alcohols.

The main difference in strength between these two reducing agents is related to the nature of the hydride (H-) ion that is involved in the reduction.

LiAlH4 is a stronger reducing agent than NaBH4 due to the fact that the Al-H bond is stronger and more polar than the B-H bond.

This means that LiAlH4 is a more powerful hydride donor and can reduce a wider range of functional groups than NaBH4, including esters, amides, nitriles, and even carboxylic acids.

NaBH4, on the other hand, is a milder reducing agent that is most commonly used for the reduction of aldehydes and ketones. It is less reactive than LiAlH4 because the B-H bond is weaker and less polar than the Al-H bond. As a result, NaBH4 is less likely to reduce other functional groups and is generally considered a more selective reducing agent.

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The name for PI3 is phosphorus triiodide. The correct option is A.

PI3 is a covalent compound composed of phosphorus and iodine, with the molecular formula PI3. The compound is a dark red solid with a pungent odor and is highly reactive, decomposing rapidly in water and air.

The name "phosphorus triiodide" follows the standard naming convention for covalent compounds, where the prefix "tri-" indicates that the compound contains three iodine atoms bonded to one phosphorus atom.

The prefix "phosphorus" indicates the presence of a phosphorus atom, while the suffix "-ide" indicates that iodine is in its anionic form.

It is important to note that the other options listed (potassium triiodide, phosphorus(III) iodide, phosphorus(II) iodide, and phosphorus iodide) are all valid compounds with different chemical formulas and properties.

The correct name for each of these compounds is as follows:

B) Potassium triiodide is KI3

C) Phosphorus(III) iodide is PI3

D) Phosphorus(II) iodide is not a valid compound.

E) Phosphorus iodide is not a specific compound and can refer to several different phosphorus-iodine compounds with varying formulas and properties.

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The GBU-12 is a laser-guided bomb used by the military for precision strikes on targets, often in conflict zones. The GP bomb used as the warhead for the GBU-12 is the Mk 82, a 500-pound general-purpose bomb.

The "GP" in your question refers to "General Purpose," which is a type of bomb employed for various applications in warfare.

The Mk 82 warhead is designed to be versatile and effective against a range of targets, such as vehicles, buildings, and infrastructure. Its destructive power comes from the high-explosive filler, which typically consists of Tritonal or H6. This filler ensures a significant impact upon detonation, enabling the bomb to achieve its intended objective.

When paired with the GBU-12 guidance system, the Mk 82 becomes a highly accurate and lethal weapon. The guidance system utilizes a laser seeker and fins to steer the bomb towards a laser-designated target, ensuring precision strikes with minimal collateral damage. This makes the GBU-12 a valuable asset in modern warfare, as it allows for the effective elimination of specific targets while reducing the risk to civilians and friendly forces.

In summary, the GP bomb used as the warhead for the GBU-12 is the Mk 82, a 500-pound general-purpose bomb. When combined with the GBU-12's laser-guidance system, the resulting weapon is highly precise and effective for various military applications.

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Reducing SDS-PAGE is exactly like SDS-PAGE but with the addition of a reducing agent, like β-mercaptoethanol, that will reduce disulfide bridges and result in a completely denatured protein.

In this technique, proteins are separated based on their molecular weight. The process starts with denaturing the proteins using SDS, a detergent that binds to and unfolds the proteins.

The reducing agent, β-mercaptoethanol, is then added to the sample, which breaks the disulfide bridges holding the protein's structure together. This results in completely linear, denatured proteins. The proteins are then loaded into a polyacrylamide gel and subjected to an electric field.

As the proteins move through the gel, smaller proteins travel faster, creating a separation based on size. Reducing SDS-PAGE is useful for the accurate determination of molecular weights and analysis of protein structure.

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An increase in temperature affects the reaction rate by increasing the velocities of particles that collide in the reaction, as well as increasing the number of collisions.

Here's a step-by-step methodology:
1. As temperature increases, particles gain more kinetic energy.
2. This increase in kinetic energy results in higher velocities for the particles involved in the reaction.
3. The higher velocities lead to more frequent collisions between particles.
4. More frequent collisions increase the probability of successful reactions, which in turn increases the reaction rate.

So, an increase in temperature leads to an increase in both the velocities of particles and the number of collisions, ultimately resulting in a higher reaction rate.

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When calcium ions (Ca2+) are electrolytically reduced to calcium metal, each calcium ion gains two electrons to form one mole of calcium metal (Ca(s)). Therefore, the relationship between the moles of electrons transferred and the moles of Ca (s) produced is a 2:1 ratio.

When calcium ions (Ca2+) are electrolytically reduced to calcium metal, the relationship between the moles of electrons transferred and the moles of Ca(s) produced is that 2 moles of electrons are required to produce 1 mole of calcium metal. This is because the reduction of Ca2+ to Ca(s) involves a 2-electron transfer, as represented by the following half-reaction:

Ca2+ + 2e- → Ca(s)

In this reaction, each calcium ion gains 2 electrons to become a calcium atom in the solid form. Therefore, the ratio of moles of electrons transferred to moles of Ca(s) produced is 2:1.

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The number of the different fin configurations that are used for the B83 is 10.

The B83 was the 12 feet long, that had the fins and the packed that is explosive force through the roughly 80 times greater as compared to that of the Hiroshima bomb. The job of this was to obliterate the hardened military sites and the command bunkers, that is including the Moscow's.

The Blast bombs is the light cases and the  poorer penetration. The Penetration bombs is the cases that is  hard enough to the penetrate concrete and the armor plating. The B83 pales as compared to others the most powerful bomb that is ever made.

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An illustration of a combination reaction is the one that follows:

[tex]3H_2+N_2 - > 2NH_3[/tex].

When two or more compounds (reactants) combine to form a single substance (product), this is referred to as a combination reaction. This reaction also generates a large amount of energy in the form of heat in addition to the formation of new bonds and the products that arise.

Two reactants combine to produce one product in a combination reaction. Oxygen and halogens are very reactive, making them likely to mix with other elements to create new compounds. When two or more reactants combine to produce a single product, this is referred to as a combination reaction.

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The theoretical yield of AgCl is 85.10% when in the reaction 35.50 g AgCl is produced with 15.50 g of [tex]NH_4Cl[/tex] reacting with an excess of [tex]AgNO_3[/tex].

To find the theoretical yield of AgCl, we need to first calculate the number of moles of [tex]NH_4Cl[/tex] and AgCl involved in the reaction. Molar mass of [tex]NH_4Cl[/tex] = 53.49 g/mol, Number of moles of [tex]NH_4Cl[/tex] = 15.50 g / 53.49 g/mol = 0.290 mol, Molar mass of AgCl = 143.32 g/mol and Number of moles of AgCl = 35.50 g / 143.32 g/mol = 0.248 mol. The balanced chemical equation tells us that 1 mole of [tex]NH_4Cl[/tex] reacts with 1 mole of [tex]AgNO_3[/tex] to produce 1 mole of AgCl.

Therefore, the limiting reactant in this reaction is [tex]NH_4Cl[/tex], and the theoretical yield of AgCl can be calculated based on the number of moles of [tex]NH_4Cl[/tex]: Theoretical yield of AgCl = 0.290 mol [tex]NH_4Cl[/tex] x 1 mol AgCl / 1 mol [tex]NH_4Cl[/tex] x 143.32 g AgCl / 1 mol AgCl = 41.60 g AgCl. To calculate the percent yield of AgCl, we can use the formula: % yield = (actual yield / theoretical yield) x 100%. The actual yield of AgCl is given as 35.50 g. Therefore, % yield = (35.50 g / 41.60 g) x 100% = 85.10%

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The electron reached the higher energy level of 6 after absorbing the photon of wavelength 91.53 nm.

A ground-state hydrogen atom absorbs a photon of wavelength 91.53 nm. Using the Balmer formula and Rydberg constant, we can determine the higher energy level the electron reached.

The Balmer formula is:

1/λ = R_H * (1/n1² - 1/n2²)

where λ is the wavelength (91.53 nm), R_H is the Rydberg constant for hydrogen (approximately 1.097 x 10^7 m^-1), n1 and n2 are the principal quantum numbers of the initial and final energy levels.

In the ground-state, n1 = 1, as the electron is in the first energy level. Substituting the given values, we get:

1/91.53 x 10^-9 = 1.097 x 10^7 * (1/1² - 1/n2²)

Solving for n2, we find that n2 ≈ 6.

So, the electron reached the higher energy level of 6 after absorbing the photon of wavelength 91.53 nm.

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Two step strategy to determine percent composition from experimental data are to calculate the moles of each element and Calculate the percent composition.

To determine the percent composition from experimental data, we have to follow this two-step strategy:

1. Calculate the moles of each element: Divide the mass of each element obtained from the experimental data by its respective atomic weight (found on the periodic table). This will give you the moles of each element in the sample.

2. Calculate the percent composition: Divide the moles of each element by the total moles of all elements in the sample, then multiply the result by 100 to obtain the percentage. This will give you the percent composition of each element in the compound.

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Methane, being a gas, would have a lower boiling point than aluminum chloride, and is likely to be in a gaseous state at room temperature.

Methane (CH4) is a simple hydrocarbon gas that is typically known to have a boiling point lower than 25°C at standard atmospheric pressure (1 atm).

Aluminum chloride (AlCl3), on the other hand, is a solid compound at 25°C. It has a high melting and boiling point, and it is typically known to be a solid at room temperature (25°C) and atmospheric pressure.

Based on these properties, we can infer that the boiling point of methane (CH4) is lower than 25°C. This is because aluminum chloride (AlCl3), which is a solid at 25°C, would not be in a liquid state at or below 25°C, and therefore cannot have a boiling point higher than 25°C.

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The percentage composition of ethane is 39.99% carbon

60.01% hydrogen and that of sodium hydrogen sulfate is 19.15% sodium 0.84% hydrogen 26.71% sulfur 53.30% oxygen

A. Ethane (C2H6)

To calculate the percent composition of ethane, we need to determine the molar mass of the compound, which is the sum of the atomic masses of all the atoms in the molecule.

Molar mass of ethane = (2 × molar mass of carbon) + (6 × molar mass of hydrogen)

= (2 × 12.011 g/mol) + (6 × 1.008 g/mol)

= 30.07 g/mol

Now we can calculate the percent composition of each element in ethane:

% composition of carbon = (2 × molar mass of carbon ÷ molar mass of ethane) × 100%

= (2 × 12.011 g/mol ÷ 30.07 g/mol) × 100%

= 39.99%

% composition of hydrogen = (6 × molar mass of hydrogen ÷ molar mass of ethane) × 100%

= (6 × 1.008 g/mol ÷ 30.07 g/mol) × 100%

= 60.01%

Therefore, the percent composition of ethane is:

39.99% carbon

60.01% hydrogen

B. Sodium hydrogen sulfate (NaHSO4)

To calculate the percent composition of sodium hydrogen sulfate, we need to determine the molar mass of the compound.

Molar mass of NaHSO4 = molar mass of Na + molar mass of H + molar mass of S + 4 × molar mass of O

= 22.99 g/mol + 1.008 g/mol + 32.06 g/mol + 4 × 16.00 g/mol

= 120.06 g/mol

Now we can calculate the percent composition of each element in sodium hydrogen sulfate:

% composition of sodium = (molar mass of Na ÷ molar mass of NaHSO4) × 100%

= (22.99 g/mol ÷ 120.06 g/mol) × 100%

= 19.15%

% composition of hydrogen = (molar mass of H ÷ molar mass of NaHSO4) × 100%

= (1.008 g/mol ÷ 120.06 g/mol) × 100%

= 0.84%

% composition of sulfur = (molar mass of S ÷ molar mass of NaHSO4) × 100%

= (32.06 g/mol ÷ 120.06 g/mol) × 100%

= 26.71%

% composition of oxygen = (4 × molar mass of O ÷ molar mass of NaHSO4) × 100%

= (4 × 16.00 g/mol ÷ 120.06 g/mol) × 100%

= 53.30%

Therefore, the percent composition of sodium hydrogen sulfate is:

19.15% sodium

0.84% hydrogen

26.71% sulfur

53.30% oxygen

learn more about oxygen here:

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