A 108 49in source emits a 633-kev gamma photon and a 606-kev internal-conversion electron from the k shell. what is the binding energy of the electron in the k shell?

first we calculate the mass percent composition of three elements carbon hydrogen and oxygen.
Mass of CO₂ = 44.0096 g/mol

Mass of H₂O = 8.0153 g/mol

percent composition of carbon = (57.30 g CO2) / (44.0096 g CO2/mol) x (1/1) x (12.0108 g C/mol) / (30.00 g) = 0.521264 = 52.1264% C 

Percent composition of hydrogen = (35.22 g H2O) / (18.0153 g H2O/mol) x (2/1) x (1.0079 g H/mol) / (30.00 g) = 0.131363 = 13.1363% H 

percent composition of oxygen = 100% - 52.1264% C 13.1363% H = 34.7373% O 

Now calculate the number of moles in the compound; 
(52.1264 g C) / (12.0108 g C/mol) = 4.33996 mol C 
(13.1363 g H) / (1.0079 g H/mol) = 13.0333 mol H 
(34.7373 g O) / (15.9994 g O/mol) = 2.17116 mol O 

Now divide by the smallest number of moles: 
(4.33996 mol C) / (2.17116 mol) = 1.999 = 2
(13.0333 mol H) / (2.17116 mol) = 6.003 = 6
(2.17116 mol O)/ (2.17116 mol) = 1.000  = 1

So,  the empirical formula is : 
C₂H₆O

The empirical formula of the alcohol cannot be determined with the given information.

The empirical formula of the alcohol can be determined by analyzing the masses of carbon dioxide (CO₂) and water (H₂O) produced during combustion. From the given information, 57.30 grams of CO₂ and 35.22 grams of H₂O were produced. To find the empirical formula, we need to calculate the moles of carbon, hydrogen, and oxygen in the sample.

First, calculate the moles of CO₂ and H₂O produced:

Next, calculate the moles of carbon and hydrogen:

Finally, divide the moles of each element by the smallest number of moles to get the mole ratio:

Based on these calculations, it is not possible to determine the empirical formula of the alcohol using the given information. Further information is needed to calculate the empirical formula.

In Period 3 of the Periodic Table, the most active nonmetal is Chlorine, due to its high electronegativity and electron affinity which results from its electron configuration.

The most active nonmetal in Period 3 (third period) of the Periodic Table is Chlorine (Cl). Period 3 includes the elements Sodium (Na) to Argon (Ar). Among these, the nonmetals are Silicon (Si), Phosphorus (P), Sulfur (S), and Chlorine (Cl). Among these nonmetals, Chlorine is the most active because it has the highest electronegativity and affinity for electrons. Its high reactivity is due to its electron configuration, with it needing just one more electron to achieve a stable, full outer shell.

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Answer:  [tex]HNO_3(aq)+NaOH(aq)\rightarrow NaNO_3(aq)+H_2O(l)[/tex]

Explanation:

Neutralization is a chemical reaction in which an acid and a base reacts to form salt and water.

A double displacement reaction is one in which exchange of ions take place. The salts which are soluble in water are designated by symbol (aq) and those which are insoluble in water and remain in solid form are represented by (s) after their chemical formulas. Liquids are represented by (l) and gases are represented by (g).

The balanced chemical equation for the neutralization reaction:

[tex]HNO_3(aq)+NaOH(aq)\rightarrow NaNO_3(aq)+H_2O(l)[/tex]

According to research, protons and neutrons are the particles that make up an atom involved in nuclear reactions.

It is a procedure that leads to combine and modify the nuclei of atoms and subatomic particles.

Protons and neutrons are concentrated in the atomic nucleus, in response to the absorption of these particles, many types of nuclear reactions take place.

Therefore, we can conclude that according to research, protons and neutrons are the particles that make up an atom involved in nuclear reactions.

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The units that express heat capacity are J/ °C; J/K; and cal/ °C

Heat capacity is the amount of heat required to increase the temperature of a determined amount of substance.

As the heat capacity increases, more heat will need to be given to the substance to increase its temperature.

Heat capacity is expressed mathematically as:

[tex]\lim_{\Delta T \to 0} \frac{Heat}{\Delta Temperature}[/tex]

So that means that Heat capacity will have units of Heat (in J or cal) over temperature (in °C or K).

Have a nice day!

its a or J/°C, J/K, cal/°C, cal/K

Explanation:

It strengthens tendons and supports the skin and internal organs.

Collagen makes up about 25 percent of protein in the body. Bones and teeth are made by adding minerals to it.

The pH of Marco's saliva indicates its acidity, and with a pH of 6.1, the hydrogen ion concentration, [H3O+], is approximately 0.0000008 M.

The subject of your question is related to the concentration of hydrogen ions in a solution, which comes under the field of chemistry. The pH of a solution is a way to measure the acidity or alkalinity of a liquid and is calculated by the formula pH = -log[H3O+]. If Marco's saliva has a pH of 6.1, we can use this formula to calculate the concentration of hydrogen ions, or [H3O+], in his saliva.

To find [H3O+], simply reverse the formula: [H3O+] = 10^-pH. So for Marco's saliva with a pH of 6.1, [H3O+] = 10^-6.1. This gives a hydrogen ion concentration of approximately 0.0000001 M or to seven decimal places, 0.0000008 M.

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The hydrogen ion concentration of Marco's saliva, determined from its pH of 6.1 using the formula [H+] = 10^(-pH), is approximately 7.943 × 10^(-7) Molar. This implies a relatively low concentration of hydrogen ions, indicative of a slightly acidic environment.

The pH of a solution is a measure of its acidity or alkalinity and is defined as the negative logarithm (base 10) of the hydrogen ion concentration. The formula for pH is given by pH = -log[H+], where [H+] is the hydrogen ion concentration.

In the case of Marco's saliva with a pH of 6.1, we can use the formula to find the hydrogen ion concentration.

pH = -log[H+]

6.1 = -log[H+]

To find [H+], we can rewrite the equation as:

[H+] = 10^(-pH)

Substituting the pH value:

[H+] = 10^(-6.1)

Calculating this gives the hydrogen ion concentration:

[H+] = 7.943 × 10^(-7)

Rounded to seven decimal places, the hydrogen ion concentration of Marco's saliva is approximately 0.0000008. Therefore, the hydrogen ion concentration is 7.943 × 10^(-7).

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To calculate the grams of silane gas, SiH4, formed when 34.9 g of Mg2Si reacts with excess H2O, you need to use the balanced chemical equation and molar ratios. Determine the moles of Mg2Si, then use the molar ratio to find the moles of SiH4. Finally, convert the moles of SiH4 to grams using its molar mass.

To calculate the number of grams of silane gas (SiH4) formed when 34.9 g of Mg2Si reacts with excess H2O, we need to consider the molar ratios between Mg2Si and SiH4 in the balanced chemical equation:

2Mg2Si + 4H2O → 4Mg(OH)2 + SiH4

From the balanced equation, we can see that 2 moles of Mg2Si react to produce 1 mole of SiH4. First, calculate the number of moles of Mg2Si:

Moles of Mg2Si = 34.9 g / (2 * molar mass of Mg2Si)

Then, use the molar ratio to calculate the moles of SiH4 produced:

Moles of SiH4 = Moles of Mg2Si * (1 mole of SiH4 / 2 moles of Mg2Si)

Finally, convert the moles of SiH4 to grams using its molar mass:

Grams of SiH4 = Moles of SiH4 * molar mass of SiH4

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 the answer is that high energy photons are what gamma rays consist of

Final answer:

To compare the heights of Peter and Paul, we convert their heights to the same unit. Peter is taller with a height of 71 inches compared to Paul's height of approximately 69.29 inches.

Explanation:

In order to compare the heights of Peter and Paul, we need to convert their heights to the same unit. Peter's height is given in feet and inches, so we need to convert it to inches. Since there are 12 inches in a foot, Peter's height is 5 ft * 12 inches/ft + 11 inches = 60 inches + 11 inches = 71 inches.

Now we can compare Peter's height of 71 inches with Paul's height of 176 cm. In order to convert centimeters to inches, we need to know that 1 inch is approximately equal to 2.54 centimeters. So, Paul's height is 176 cm * 1 inch/2.54 cm = 69.29 inches (approximately).

Comparing the heights, we can see that Peter is taller with a height of 71 inches compared to Paul's height of approximately 69.29 inches.

Answer: Option (d) is the correct answer.

Explanation:

When cool, dense air from over the water flows inland, it's called a sea breeze.

Any wind that travels from large body of water towards the inland is known as sea breeze. Land absorbs heat from the sun more readily as compared to water in the sea.

Therefore, the wind above the land is warm whereas the wind above the sea is cooler and dense.

 The  partial  pressure of  gas C  is 0.902  atm

  calculation

partial pressure of gas c  =[( percent by volume of  gas   C /  total  percent)   x total pressure]

percent  by  volume of gas C= 22%

Total   percent  = 36% +42%  + 22%  = 100 %

Total  pressure  =  4.1 atm

partial  pressure  of gas C  is therefore =  22/100 x 4.1 atm = 0.902  atm

To calculate ΔH for a reaction, bond energies and Hess's law are used. The sum of bond energies is equivalent to the standard enthalpy change. Energy required for bond breakage and energy released in bond formation are central to these computations.

The calculation of delta H (ΔH) for a reaction requires the consideration of bond energies. In this case, the bond energy of a pure covalent H-H bond, for instance, is 436 kJ/mol. For reactions involving more molecules, the sum of all bond energies in the molecule equals the standard enthalpy change.

Let's consider a reaction where H-H bonds and Cl-Cl bonds form H-Cl. The energy required to break these bonds is the sum of the bond energy of the H-H bond (436 kJ/mol) and the Cl-Cl bond (243 kJ/mol). During the reaction, two moles of H-Cl bonds are formed, releasing energy. The enthalpy change can be calculated using the Hess's law.

The average C-H bond energy is another example, computed as 1660/4 = 415 kJ/mol, considering there are four moles of C-H bonds broken per mole of the reaction. Overall, determining ΔH involves understanding bond energies and applying principles such as Hess's law.

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Final answer:

To find the pressure at an altitude of 2500 m, set up a proportion using the given pressures at sea level and 1000 m altitude.

Explanation:

The question asks for the pressure at an altitude of 2500 m. We are given that the pressure at sea level is 102.2 kPa and 87.9 kPa at h = 1000 m. Since the rate of change of pressure with respect to altitude is proportional to the pressure itself, we can set up a proportion. Let p be the pressure at 2500 m:

(102.2 kPa - 87.9 kPa) / (0 m - 1000 m) = (p - 87.9 kPa) / (2500 m - 1000 m)

Find the value of p, which gives the pressure at an altitude of 2500 m.

Environmental scientists and specialists are expected to be in demand as public awareness of environmental threats grows. These professionals will still be required to analyze environmental issues and create solutions that protect community health.

Due to the increased effects of climate change we have witnessed over the past ten years, employment opportunities in environmental science are more in demand than ever. Environmental scientists study problems like pollution and deforestation that concern us all.

Environmental scientists are expected to be in greater demand due to the growing need for environmental protection and responsible land and water resource management.

In their research, environmental scientists frequently employ scientific techniques and data analysis. Their conclusions are based on a careful examination of scientific evidence. In their analyses, they must take into account all potential strategies, interactions, and solutions.

Thus, Environmental scientists and specialists are expected to be in demand as public awareness of environmental threats grows.

To learn more about the environmental scientists, follow the link;

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Metals lose electrons to become cations, and nonmetals gain those electrons to become anions, with the electrostatic attraction between these oppositely charged ions forming an ionic compound.

When metals bond with nonmetals, electrons are indeed transferred from the metal to the nonmetal, resulting in the formation of an ionic compound. This process involves a metal atom losing electrons to become a cation, which is a positively charged ion, while a nonmetal atom gains those electrons to become an anion, which is a negatively charged ion. The electrostatic attraction between the opposite charges of these ions holds the compound together.

For example, in the formation of sodium fluoride (NaF), sodium (Na) loses one electron to form a Na+ cation while fluorine (F) gains one electron to form an F- anion. The resulting compound, NaF, is stabilized by the strong attractions between the positively charged sodium ions and the negatively charged fluoride ions.

The correct answer is C) of the scientists and ideas that came before him.

Explanation:

Isaac Newton was a prominent physicist mainly known for his theories and ideas regarding gravity, motion, mechanics, among others that are still used today due to their relevance and accuracy. Despite this, Newton recognized in a letter "If I have seen further it is by standing on the shoulders of giants" which suggests Newton felt his theories and ideas were only possible due to previous theories and scientists that build the basis Newton used. Indeed, Newton's predecessors such as Kepler or Galilei were necessary for Newton and also he had the support of contemporary scientists. Thus, in this quote, Newton said that his advances were only possible because of the scientists and ideas that came before him.

Precipitation is higher on the windward side of a mountain due to orographic precipitation, where rising air cools and water vapor condenses, leading to rain or snow. This creates a rain shadow effect and drier conditions on the leeward side.

Precipitation tends to be higher on the windward side of a mountain because water vapor condenses as it rises there. This phenomenon is known as orographic precipitation. As the moist air from the ocean encounters a mountain range, it rises and cools, leading to the condensation of water vapor which then precipitates as rain or snow on the windward side. This results in a rain shadow on the leeward side, where the air, now dry, descends and warms up, creating drier conditions.

Final answer:

The molarity of acetic acid in the vinegar sample is determined by calculating the moles of NaOH used in the titration, which are equivalent to the moles of acetic acid, and then dividing by the volume of the vinegar sample.

Explanation:

The student's question pertains to the calculation of the molarity of acetic acid (HOAc) in a vinegar sample based on a titration experiment with sodium hydroxide (NaOH). To determine the molarity, we use the volume of NaOH added and the molarity of NaOH to calculate the moles of NaOH, which equals the moles of acetic acid due to the 1:1 stoichiometry in the reaction. The equation is:

Given that the volume of NaOH used is (19.35 mL - 0.15 mL) and the molarity of NaOH is 0.317 M, the calculation is as follows:

Moles of NaOH = (19.35 mL - 0.15 mL) × 0.317 M × (1 L / 1000 mL)

Moles of HOAc = Moles of NaOH

Molarity of HOAc = Moles of HOAc / 0.025 L

NaOH = 19.35 - 0.15 = 19.2 mL 19.2 mL x 0.317 M = 6.086 millimoles NaOH 6.086 mmol NaOH neutralized 6.086 mmol acetic acid 6.086 mmol acetic acid / 25.0 mL = 0.2435 mmol/mL = 0.2435 mol/L Acetic acid was 0.2435 M

The strength of intermolecular forces from the strongest to the weakest is:-

Hydrogen Bonds > Dipole-Dipole interactions > Dipole-induced dipole > London dispersion forces

Hence, London dispersion forces are the weakest. This arises due to the unsymmetrical distribution of electrons around the nucleus which tends to create an instantaneous temporary dipole. When a second molecule come in contact, the dipole from the first distorts the charge distribution in the later which leads to weak electrostatic attraction between the two atoms/molecules.

The complete balanced chemical reaction is:

2 AgNO3 + Na2S --> 2 NaNO3 + Ag2S

First let us calculate the number of moles of AgNO3.

moles AgNO3 = 0.315 M * 0.035 L

moles AgNO3 = 0.011025 mol

From the reaction, 1 mole of Na2S is needed for every 2 moles of AgNO3 hence:

moles Na2S required = 0.011025 mol AgNO3 * (1 mol Na2S / 2 mol AgNO3)

moles Na2S required = 5.5125 x 10^-3 mol

Therefore volume required is:

volume Na2S = 5.5125 x 10^-3 mol / 0.260 M

volume Na2S = 0.0212 L = 21.2 mL

21.20 mL of 0.260 M [tex]\(\text{Na}_2\text{S}\)[/tex] is needed to react with 35.00 mL of 0.315 M [tex]\(\text{AgNO}_3\).[/tex]

To determine the volume of 0.260 M [tex]\(\text{Na}_2\text{S}\)[/tex] needed to react with 35.00 mL of 0.315 M [tex]\(\text{AgNO}_3\)[/tex], we need to use the stoichiometry of the reaction between [tex]\(\text{Na}_2\text{S}\) and \(\text{AgNO}_3\).[/tex]

The balanced chemical equation for the reaction is:

[tex]\[ \text{Na}_2\text{S} + 2\text{AgNO}_3 \rightarrow \text{Ag}_2\text{S} + 2\text{NaNO}_3 \][/tex]

From the balanced equation, we see that 1 mole of [tex]\(\text{Na}_2\text{S}\)[/tex] reacts with 2 moles of [tex]\(\text{AgNO}_3\).[/tex]

Step 1: Calculate moles of [tex]\(\text{AgNO}_3\)[/tex]

First, we calculate the moles of [tex]\(\text{AgNO}_3\)[/tex] in the 35.00 mL solution.

[tex]\[ \text{Moles of AgNO}_3 = \text{Molarity} \times \text{Volume (in L)} \][/tex]

[tex]\[ \text{Moles of AgNO}_3 = 0.315 \, \text{M} \times 0.03500 \, \text{L} \][/tex]

[tex]\[ \text{Moles of AgNO}_3 = 0.011025 \, \text{moles} \][/tex]

Step 2: Determine moles of [tex]\(\text{Na}_2\text{S}\)[/tex] needed

From the balanced equation, 1 mole of [tex]\(\text{Na}_2\text{S}\)[/tex] reacts with 2 moles of [tex]\(\text{AgNO}_3\).[/tex]

[tex]\[ \text{Moles of Na}_2\text{S} = \frac{\text{Moles of AgNO}_3}{2} \][/tex]

[tex]\[ \text{Moles of Na}_2\text{S} = \frac{0.011025 \, \text{moles}}{2} \][/tex]

[tex]\[ \text{Moles of Na}_2\text{S} = 0.0055125 \, \text{moles} \][/tex]

Step 3: Calculate the volume of 0.260 M [tex]\(\text{Na}_2\text{S}\)[/tex] solution needed

Now, we need to find the volume of 0.260 M [tex]\(\text{Na}_2\text{S}\)[/tex] that contains 0.0055125 moles of [tex]\(\text{Na}_2\text{S}\).[/tex]

[tex]\[ \text{Volume (in L)} = \frac{\text{Moles of Na}_2\text{S}}{\text{Molarity}} \][/tex]

[tex]\[ \text{Volume (in L)} = \frac{0.0055125 \, \text{moles}}{0.260 \, \text{M}} \][/tex]

[tex]\[ \text{Volume (in L)} = 0.0212019 \, \text{L} \][/tex]

Convert the volume from liters to milliliters:

[tex]\[ \text{Volume (in mL)} = 0.0212019 \, \text{L} \times 1000 \, \text{mL/L} \][/tex]

[tex]\[ \text{Volume (in mL)} = 21.20 \, \text{mL} \][/tex]

Therefore, 21.20 mL of 0.260 M [tex]\(\text{Na}_2\text{S}\)[/tex] is needed to react with 35.00 mL of 0.315 M [tex]\(\text{AgNO}_3\).[/tex]