Fluorine-18, which has a half-life of 110 min, is used in PET scans.

a. If 100. mg of fluorine-18 is shipped at 8:00 a.m., how many milligrams of the radioisotope are still active after 110 min?
b. If 100. mg of fluorine-18 is shipped at 8:00 a.m., how many milligrams of the radioisotope are still active when the sample arrives at the radiology laboratory at 1:30 p.m.?

Answer:

B.

Explanation:

Answer:

B) line is the correct answer.

Explanation:

When light shines on a sample, each element emits specific wavelengths producing a unique fingerprint called its line spectra.

The line spectrum is electromagnetic spectra consist of discrete spectra lines.

When the atoms are excited they emit ray of specific wavelengths that correspond to various colors. The emitted ray can be seen as a range of colored line, this range of colored lines is termed as line spectra.

lines spectra are usually utilized to recognize atoms and molecules. Each element has individual line emission spectra.

manganese The metal that is used as a sacrificial electrode to prevent the rusting of iron is manganese.

Answer:

Al → Al³⁺ + 3 e⁻,     is an oxidation process.

S²⁻ → S + 2 e⁻,        is an oxidation process.

Cu → Cu²⁺ + 2 e⁻,    is an oxidation process.

Explanation:

So,

Al loses 3 electrons and produce Al³⁺c

S²⁻ loses 2 electrons and produce S.

Cu loses 2 electrons and produce Cu²⁺.

All the given processes (Al becoming Al₃+, S₂- becoming S, and Cu becoming Cu₂+) are examples of oxidation, as each involves the loss of electrons.

To determine whether each process is oxidation or reduction, we will look at the change in electron configuration for each reaction.

Thus, all the given processes are examples of oxidation, where each element or ion loses electrons.

Answer:

A

Explanation:

Answer: Option (D) is the correct answer.

Explanation:

It is known that in a closed system there will no exchange of heat or matter from the system to the surrounding. Whereas in an open system there will be exchange of both heat and energy from the system to the surrounding and vice versa.

Therefore, in the given situation cup A is a closed system and cup B is an open system. Hence, there will be no exchange of heat or matter from cup A to system and surrounding. So, it will cool slowly that cup B.

Thus, we can conclude that the statement no molecules will be able to evaporate at the surface of cup A, best explains why cup A will cool more slowly than cup B.

Answer:

12.6.

Explanation:

no. of millimoles of KOH = (MV)KOH = (0.183 M)(45.0 mL) = 8.235 mmol.

no. of millimoles of HCl = (MV)HCl = (0.145 M)(35.0 mL) = 5.075 mmol.

So,

[OH⁻] = [(no. of millimoles of KOH) - (no. of millimoles of HCl)] / (V total) = (8.235 mmol - 5.075 mmol) / (80.0 mL) = 0.395 M.

∵ pOH = -log[OH⁻]

∴ pOH = -log(0.395 M) = 1.4.

∵ pH + pOH = 14.

∴ pH = 14 - pOH = 14 - 1.4 = 12.6.

12.6 is the pH of a solution prepared by mixing 45.0 ml of 0.183 m KOH and 35.0 ml of 0.145 m HCl.

pH of the solution can be calculated as pH = 14 - pOH.

First of all we have to calculate the concentration of OH⁻ ions as follow:

Total volume of the solution = 45ml + 35ml = 80ml

Concentration of OH⁻ in terms of mole is calculated as:

[OH⁻]=(no. of millimoles of KOH - no. of millimoles of HCl)/Total volume

Given that, concentration of KOH = 0.183m

Volume of KOH = 45ml

Concentration of HCl = 0.145m

Volume of HCl = 35ml

Millimoles can be calculated as:

millimoles = concentration × volume

No. of millimoles of KOH = 0.183 M × 45.0 mL = 8.235 mmol

No. of millimoles of HCl = 0.145 M ×35.0 mL = 5.075 mmol

Now, [OH⁻] = 8.235 mmol - 5.075 mmol / 80.0 mL = 0.395 M

pOH = -log[OH⁻]

pOH = -log(0.395)

pOH = 1.4

Therefore, pH = 14 - 1.4 = 12.6

Hence, 12.6 is the pH of the solution.

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I believe is B if not then it's A

Answer:

Option (B)

Explanation:

R-12 is known as the Dichloro-difluoro-methane and it is a colorless gas. It is was earlier used in the refrigerators, vehicles air conditioning, and aerosol spray. The use of this R-12 was found to be depleting the ozone layer which was not a positive effect on the earth. Due to this, the use of this gas was banned and alternative energy resources were used. Its products containing this R-12 gas were not expensive and they were stable enough.

Hence, the correct answer is option (B).

Answer: pH scale

Explanation:

Answer:

8.0 M.

Explanation:

∴ (MV) of KNO₃ before dilution = (MV) of KNO₃ before dilution.

M = 12.0 M, V = 500.0 mL.

M = ??? M, V = 500.0 mL + 250.0 mL = 750.0 mL.

∴ M after dilution = (MV) before dilution / (V) after dilution = (12.0 M)(500.0 mL)/(750.0 mL) = 8.0 M.

Answer:

delta G = -ve.. This means the rxn is spontaneous

Explanation:

For spontaneous rxn

Delta H = - ve

Delta S = +ve

And no. Of moles at product side should be less than tha reactant side.

I wrote all i know.. Hope this helps you

Answer:

This question is incomplete but the completed question is below

Under which set of conditions is ΔGrxn for the reaction A(g)→B(g) most likely to be negative?

Under which set of conditions is for the reaction most likely to be negative?

(a) PA=0.010 atm; PB=0.010 atm

(b) PA=0.010 atm; PB=10.0 atm

(c) PA=10.0 atm; PB =0.010 atm

(d) PA=10.0 atm; PB =10.0 atm

The correct option is (c)

Explanation:

The Gibb's free energy (ΔG) of the reaction will be negative when the reaction is spontaneous and a reaction is said to be spontaneous when more products are been formed.

When you consider the reaction provided in the question, the "g" in bracket means gas while A represent reactant(s) and B represents product(s)

When a reaction involves gases, an increase in pressure causes more products to be formed hence the pressure on the reactant side (PA) will most likely be more than the pressure on the product side (PB). The only option that has more pressure on the reactant side (PA = 10.0 atm) than on the product side (PB = 0.010 atm) is option c.

Answer:

c. palisade layer  

Answer:

Explanation:

The total energy required to convert 1 mole of liquid from 5°C below its boiling point to 1 mole of gaseous Ar at 5° above its boiling point may be calcualted in three stages:

1) Energy to heat the liquid Ar from 5°C below its boling point to the boiling point:

2) Energy to vaporize the liquid Ar:

3) Energy to heat the gaseous Ar 5°C above its boiling point:

4) Total energy (E)

The total energy required to convert 1 mole of liquid Argon from 5°C below its boiling point to 1 mole of gaseous Ar at 5°C above its boiling point is calculated through a multi-step process. The steps involve increasing the temperature of the liquid to its boiling point, vaporizing at the boiling point, and further heating the gas above the boiling point. The sum of these three steps yields a total required energy of 6735 J.

This is a multi-step thermodynamics problem in chemistry that requires the use of specific heat, change in temperature, and enthalpy of vaporization. The energy required to convert 1 mole of liquid Argon from 5°C below its boiling point to 1 mole of gaseous Ar at 5°C above its boiling point can be found through the equation: q = m*c*ΔT, where q is the heat energy, m is the amount of Argon in moles, c is the specific heat, and ΔT is the change in temperature.

First, we need to raise the temperature of the liquid argon from 5°C below the boiling point to the boiling point. Using the specific heat for liquid argon, this gives us q1 = (1 mol)(25.0 J/mol·°C)(5°C) = 125 J.

Next, we have to provide the heat of vaporization to convert the liquid to gas at the boiling point, which gives us q2 = 6506 J/mol. Then we have to further heat the gas from the boiling point to 5°C above it. Using the specific heat for gaseous argon, this gives us q3 = (1 mol)(20.8 J/mol·°C)(5°C) = 104 J.

Adding these three energy amounts together, we find that total energy required is q_tot = q1 + q2 + q3 = 125 J + 6506 J + 104 J = 6735 J.

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Answer:

Keq = [CO][Cl₂]/[COCl₂].

Explanation:

For the balanced reaction:

COCl₂(g) ⇄ CO(g) + Cl₂(g).

The equilibrium constant can be expressed as concentration equilibrium constant (Kc) or pressure equilibrium constant (Kp).

The equilibrium constant is the ratio of the product of products concentrations to the product of the reactants concentrations.

Keq = [CO][Cl₂]/[COCl].

Answer:

Explanation:

The coefficients of a chemical equation are the numbers that you put in front of each reactant and product. They are used to balance the equation and comply with the law of mass conservation.

By adjusting the coefficients you obtain the relative amounts (moles) of each product and reactant, i.e. the mole ratios.

Here an example.

The first information is what is called a word equation. E.g. nitrogen and hydrogen react to form ammonia:

        This equation shows the chemical formulae but it is not balanced. The law of mass conservation is not observed.

So, in order to comply with the law of mass conservation you adjust the coefficients as follow.

        As you see, it was necessary to modify the coefficients. Now the law of conservation of mass is observed and you get the mole ratios:

There are five significant figures

Hope this helps and have a fabulous day :)

It’s five significant figures

Answer:

The reduced atom is Br.

Explanation:

2Na + Br₂ → 2NaBr,

Na loses 1 electrons and is oxidized to Na⁺. (Na → Na⁺ + e).

Br₂ gains 2 electrons and is reduced to 2Br⁻. (Br₂ + 2e → 2Br⁻).

So, the reduced atom is Br.

Answer:

137.6 mL.

Explanation:

where, P is the pressure of the gas in atm.

V is the volume of the gas in L.

n is the no. of moles of the gas in mol.

R  is the general gas constant,

T is the temperature of the gas in K.

(V₁T₂) = (V₂T₁)

V₁ = 125.0 mL, T₁ = 25°C + 273 = 298 K,

V₂ = ??? mL, T₂ = 55°C + 273 = 328 K,

(V₁T₂) = (V₂T₁)

∴ V₂ = (V₁T₂)/(T₁) = (125.0 mL)(328 K)/(298 K) = 137.6 mL.

Final answer:

To find the volume of the gas at a different temperature, we can use Charles's Law. By using the formula V1/T1 = V2/T2 and substituting the known values, we can determine that the volume of the gas at 55°C is 275 mL.

Explanation:

To solve this problem, we can use Charles's Law, which states that the volume of a gas is directly proportional to its temperature, assuming the pressure remains constant. We can use the formula:

V1/T1 = V2/T2

Given that the initial volume (V1) is 125 mL and the initial temperature (T1) is 25.0°C, we can substitute these values into the formula. Rearranging the formula to solve for V2, we get:

V2 = (V1*T2)/T1

Substituting the known values, we have:

V2 = (125 mL * 55 °C) / 25.0 °C = 275 mL

Therefore, the volume of the gas at 55°C is 275 mL.

Answer:

chemical change

Answer:dispersed state

dispersed medium

colloid

Answer:

Label A points to the solid particles of pigment that give the paint its color. The solid particles are the (dispersed state.)

Label B represents the liquid surrounding the solid particles. This liquid is called the (Dispersed Medium)

This paint does not settle over time, so it is an example of a (Colloid)

Explanation:

Fernanda looked at a sample of paint under a microscope. At right is the sketch she made of what she saw.

Answer:

Organic compound is the correct answer

Explanation:

Answer:

Explanation:

Hemoglobin removes excess protons from the red blood cells so that they can be excreted through the kidneys.  

Hemoglobin binds some of the excess protons released by carbonic acid.  

Subsequent binding of oxygen is drastically reduced after the first one is bound.  

Hemoglobin produces protons or hydroxide ions as needed to alter the blood pH.

Answer:

Excess acids in the red blood cells are removed by the hemoglobin

Explanation:

In what way does hemoglobin act as a buffer against changes in blood ph?

Excess acids in the red blood cells are removed by the hemoglobin . it is a good receptor of excess proton released by carbonic acid.

It helps to remove acids before it affects the PH of the blood. deoxygenated hemoglobin are better receptor of proton than the oxygenated one.

If hemoglobin does not act as a buffer, there will be changes  in the blood's PH and can poison the blood.

Answer:

By using a screen

Answer:

Use a screen

Explanation:

Answer:

D.Maximum internal cooking temperature

Explanation:

According to the Storage Ladder Protocol, food storage in refrigerator should have a proper rules to store them. On the top most shelf, Prepared foods should be kept. On the second shelf, Fruits and Vegetable are kept. Fish and Sea foods are kept on the third shelf. The fourth shelf is reserved for the Beef and Porks. The next shelf is for Ground Meat. The last shelf is for Poultry items. So, this proves that the Ground Beef should be stored above the Chicken. A diagram is attached below to explain the storage order in a more appropriate manner.

According to the Storage Ladder Protocol, raw meat should be stored on shelves based on its Minimum internal cooking temperature

The storage ladder protocol is a sets of rules created to make sure that varieties of unprepared and prepared food are properly stored in a refrigerator.

The storage ladder protocol is meant to determine which shelf each variety of food should be stored on and also provides a guide as to which food should be below or above.

For example, prepared food must be stored on the top shelf, Foods and vegetables are stored on the second shelf, fish and seafood should be stored on the third shelf, beef and pork should be kept on the fourth shelf, Ground meat should be stored on the fifth shelve while poultry items should be kept on the bottom shelf.

Also, to ensure proper food hygiene, make sure that the temperature of your fridge is set between 0 and 5 degrees Celsius. If the temperature is maintained within that range, it will slow down the rate at which the food gets to spoil and also prevent harmful bacteria from multiplying.

Also, do not consume any food that has passed its expiry date because it will be easy for bacteria to grow on such food.

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KEYWORDS:

A. More neutrons than protons

it would likely include more neutrons than protons.

Answer:

b. The shorter the half-life, the more dangerous the radioisotope.

The shorter the half-life, the more dangerous the radioisotope. Therefore, the correct option is option B.

The half-life is the length of time required for a single quantity (of substance) to drop to half its initial value (symbol t12). The phrase is widely used in nuclear physics to describe how quickly unstable atoms dissolve radioactively or how long stable atoms endure.

The term is often used more generally to indicate any type involving exponentially decaying. In the medical sciences, for example, the biological ½ of drugs and other chemicals in the human body is a word. Half-opposite life's in exponential growth is time's doubling. The shorter the half-life, the more dangerous the radioisotope.

Therefore, the correct option is option B

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Answer:

14.77 mol.

Explanation:

Using cross multiplication:

1.0 mole of He contains → 6.022 x 10²³ atoms.

??? mole of He contains → 8.84 x 10²⁴ atoms.

∴ The no. of moles of He contains (8.84 x 10²⁴ atoms) = (1.0 mol)(8.84 x 10²⁴ atoms)/(6.022 x 10²³ atoms) = 14.77 mol.

Answer:

Explanation:

1) Data:

a) Experimental value, m₁ = 105.2 amu

b) Known value, m = 107.5 amu

b) % error = ?

2) Formulae:

a) absolute error = | experimental value - known value|

b) % error = [ absolute value / known value ] × 100

3) Solution:

a) absolute error = | m₁ - m | = | 105.2 amu - 107.5 amu | = 2.3 amu

b) % error = [ 2.3 amu / 107.5 amu ] × 100 = 2.1% ← answer

Answer:

ultraviolet light is the shortest wavelength

Explanation:

Answer:

The correct answer is the first option: Ultraviolet light.

Explanation:

Hello!

Let's solve this!

The ultraviolet light is the one with the shortest wavelength. It is between visible light and x-rays. The place where this is seen is in the electromagnetic spectrum, which is the set of all electromagnetic waves.

Therefore, we conclude that the correct answer is the first option: Ultraviolet light.

Answer:

Explanation:

A solution in general is a homogeneous mixture in which a substance, named solute, is dissolved, in other substance, name solvent.

Solutions may be in solid, liquid or gas state. There are many kind of solvents. Usually, in a lab you work with liquid solutions. Some liquid solvents are: ethanol, glycerin, hexane, benzene, and water, among many others.

Aqueous solution is a solution where the solvent is water. Of course, the solute may be any one: NaCl, sugar, ethanol, an acid, a base, a salt.

What distinguish a solution in general and an aqueous solution is the solvent.

The statement provided is false; the basic structural unit of a compound is the molecule, not the atom. Molecules consist of atoms from different elements bonded in fixed ratios, forming the substance known as a compound.

The statement 'For compounds, the basic structural unit representing the compound is the atom.' is false. The smallest particle of most compounds is called a molecule. For instance, a water molecule (H₂O) is always made up of one atom of oxygen and two atoms of hydrogen. This molecule is the basic unit that represents the compound water, not a single atom. Compounds are characterized by atoms of different elements bonded together, and these atoms are in fixed, whole-number ratios.

Isomers are molecules that have the same number and type of atoms but arranged differently. For example, molecules with the formulas CH₃CH₂COOH and C₃H₆O₂ could indeed be structural isomers since they have the same molecular formula but could have a different arrangement of the atoms within the molecule.

Most elements exist as individual atoms as their basic unit. When combined in specific ways, these atoms form molecules, which are the basic units of compounds. A single atom by itself cannot represent a compound; it is the molecule, composed of two or more atoms, that does so.