90 nitroglycerin (c3h5n3o9) is a powerful explosive. its decomposition may be represented by this reaction generates a large amount of heat and many gaseous products. it is the sudden formation of these gases, together with their rapid expansion, that produces the explosion. (a) what is the maximum amount of o2 in grams that can be obtained from 2.00 × 102 g of nitroglycerin? (b) calculate the percent yield in this reaction if the amount of o2 generated is found to be 6.55 g.

Answer 1) The maximum height at which the solvent should condense (in the condenser) during the reflux should be halfway up to the condenser.

Explanation : If the solvent molecules exceeds the maximum height of the condenser there may be loss of molecules of the solution. The maximum height is maintained during the reflux so that the volatile molecules travels back to the solution and initiate the reaction process.

Answer 2) If the solvent condenses higher than this, then the solution vapors will go back to the reaction flask and start the reaction much earlier than before.

Explanation : If this is prevented by not allowing solvent vapors to exceed the maximum height of the reflux condenser then reaction will not happen fast or will not start early. Therefore, the condensation of the solution vapors should occur at the maximum height not higher than that.

Answer:

Distillation of a mixture

Explanation:

The Final temperature of the mixture is -10.54 °C.

Heat lost by copper = heat gained by the water

Formula:

CM(z-y) = cm(y-x)................. equation 1

Where:

Make y the subject of the equation:

From the question,

Given:

Substitute these values into equation 2

Hence, The Final temperature of the mixture is -10.54 °C

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Alkali metals are the most reactive, followed by alkaline earth metals. Noble gases are the least reactive. Thus, the correct sequence from most to least reactive is alkali metals, alkaline earth metals, noble gases. Option 1

In a periodic table, the reactivity of elements tends to decrease from the left to the right. Therefore, the correct sequence from most reactive to least reactive elements would be option 1: Alkali metals, alkaline earth metals, and then noble gases.

This is because alkali metals (group 1) are the most reactive elements, followed by alkaline earth metals (group 2). Noble gases (group 18) are very stable and hence the least reactive. On the other hand, transition metals are generally less reactive than alkali and alkaline earth metals, while halogens are more reactive than noble gases but less reactive than alkali and alkaline earth metals.

Option 1

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The average atomic mass of carbon is calculated based on the relative abundances and masses of its isotopes, carbon-12, and carbon-13, which results in an average atomic mass of approximately 12.01 atomic mass units.

The average atomic mass of an element is calculated based on the masses and relative abundances of its naturally occurring isotopes. In the case of carbon, the two main isotopes are carbon-12 (with 6 protons and 6 neutrons) and carbon-13 (with 6 protons and 7 neutrons), each having different abundances. The atomic mass of carbon-12 is 12 amu (atomic mass units) and it accounts for approximately 98.89% of the carbon. The atomic mass of carbon-13 is 13 amu and it accounts for approximately 1.11% of the carbon. We can calculate the average atomic mass like this: (12 amu x 0.9889) + (13 amu x 0.0111) = 12.01 amu. Therefore the average atomic mass of carbon is approximately 12.01 amu.

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Answer:

B. that the patterns were different

Explanation:

The weekly cost of gas for driving 119 km per day in Europe, considering the car's gas mileage of 22 mi/gal and gas cost of 1.10 euros per liter, is approximately $123.45 when converted from euros.

To calculate the weekly cost of gas while driving in Europe, we need to figure out the total number of kilometers driven in a week, convert this distance to miles, and then determine how much gas would be used, taking into account the car's gas mileage, and finally convert the cost to dollars.

Firstly, the student will drive 119 km per day. Over a week, this amounts to:

119 km/day × 7 days/week = 833 km/week.

Next, we convert kilometers to miles using the conversion factor 1 km ≈ 0.621371 miles:

833 km × 0.621371 mi/km ≈ 517.781 mi/week.

Given the car's gas mileage of 22.0 mi/gal, the amount of gas needed for the week is:

517.781 mi / 22.0 mi/gal = 23.535 gal/week.

Now we convert gallons to liters since gas in Europe is sold by the liter. There are approximately 3.78541 liters in one gallon:

23.535 gal × 3.78541 liters/gal ≈ 89.071 liters/week.

With the cost of gas at 1.10 euros per liter, this totals:

89.071 liters × 1.10 euros/liter = 97.978 euros/week.

Finally, we convert euros to dollars:

97.978 euros × 1.26 dollars/euro = $123.452.

Therefore, the cost of gas for one week is approximately $123.45.

Reaction 2 is 3.385 times faster compared to reaction 1

The reaction rate (v) shows the change in the concentration of the substance (changes in addition to concentrations for reaction products or changes in concentration reduction for reactants) per unit time.

Can be formulated:

Reaction: aA ---> bB

[tex]\large{\boxed{\boxed{\bold{v~=~-\frac{\Delta A}{\Delta t}}}}[/tex]

or

[tex]\large{\boxed{\boxed{\bold{v~=~+\frac{\Delta B}{\Delta t}}}}[/tex]

A = reagent

B = product

v = reaction rate

t = reaction time

For A + B reactions ---> C + D

Reaction speed can be formulated:

[tex]\large{\boxed{\boxed{\bold{v~=~k.[A]^a[B]^b}}}[/tex]

where

v = reaction speed, M / s

k = constant, mol¹⁻⁽ᵃ⁺ᵇ⁾. L⁽ᵃ⁺ᵇ⁾⁻¹. S⁻¹

a = reaction order to A

b = reaction order to B

[A] = [B] = concentration of substances

Reaction 1 uses 0.130 mol / l of reactant, and reaction 2 uses 0.440 mol / l of reactant.

Assuming a reaction order is one then:

reaction rate 1 =

v₁ = k. [A]

v₁ = k. 0.130

reaction rate 2 =

v₂ = k. [B]

v₂ = k. 0.440, so that

[tex]\frac{v_2}{v_1}~=~k.\frac{0.440}{0.130}[/tex]

[tex]\frac{v_2}{v_1}~=~3,385[/tex]

v₂ = 3.385. v₁

the factor can decrease the rate of a chemical reaction

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increase the rate of a chemical reaction

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Which of the following does not influence the effectiveness of a detergent

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Keywords: reaction rate, reaction order, molar concentration, products, reactants

The rate of reaction 2 is approximately 3.38 times faster than reaction 1, assuming that it is a first-order reaction where the rate is directly proportional to the concentration of the reactant.

The student is comparing the rates of two reactions with different initial concentrations of reactants. To determine how many times faster reaction 2 is compared to reaction 1, it is essential to understand the order of the reaction. In this context, it is suggested that the reaction is first order since rates of reaction are directly proportional to the concentration of the reactant, which follows the rate law rate = k[Reactant]. Therefore, if we double the concentration of the reactant, the reaction rate doubles, which is a characteristic of a first-order reaction. Hence, without needing explicit rate constants or measurements, we can infer that if the concentration of reactant in reaction 2 is 0.440 mol/L, which is roughly 3.38 times the concentration in reaction 1 (0.130 mol/L), the rate of reaction 2 would also be 3.38 times faster than reaction 1.

The solution concentration of 0.0610 m aqueous fluoride is 0.1159% by mass and 1159 ppm. These values are calculated using the molarity and molar mass of fluoride and assuming a solution density of 1.00 g/mL.

To express the concentration of a 0.0610 m aqueous solution of fluoride (F−) in mass percentage and parts per million (ppm), given a density of 1.00 g/mL, we need to do some calculations based on the definitions of these concentration units.

First, to find the mass percentage, we use the molarity of the solution (moles of solute per liter of solution) and the molar mass of fluoride (F−, approximately 19.00 g/mol). Since the solution has a density of 1 g/mL, we assume that 1 liter of the solution weighs 1000 g.

The mass of fluoride in 1 L of 0.0610 M solution is:

0.0610 moles/L × 19.00 g/mole = 1.159 g of F−

To express this as a percentage, we divide the mass of fluoride by the total mass of the solution and multiply by 100:

(1.159 g / 1000 g) × 100 = 0.1159%

Now, to convert this to parts per million, we use the fact that 1 ppm equals 1 mg of solute per kg of solution. Considering that 1.159 g is 1159 mg, we have:

1159 mg of F− per 1000 g of solution = 1159 ppm

Therefore, the concentration of the fluoride solution is 0.1159% by mass and 1159 ppm.

Final answer:

The mass of a sugar crystal with 2.2×1017 sucrose molecules is found by calculating the number of moles and multiplying by the molar mass of sucrose (342.297 g/mol), then converting to milligrams.

Explanation:

To find the mass of a sugar crystal with approximately 2.2×1017 sucrose (C12H22O11) molecules, we need to use the molar mass of sucrose. The molar mass of sucrose is 342.297 grams per mole. Since one mole of a compound contains Avogadro's number (approximately 6.022×1023) of molecules, we can use the following steps to calculate the mass:

Performing these calculations will give us the mass of the crystal in milligrams (mg).

Answer:

Chlorine and Flourine

Explanation:

It is important to identify the groups in which the elements being to. The elements in each group have the same number of electrons in the outer orbital. Those outer electrons are also called valence electrons.

Since elements in a group have the same number of valence electrons, they behave similarly in chemistry.

Nitrogen - Group 5

Chlorine - Group 7

Barium - Group 2

Flourine - Group 7

Sulphur - Group 6

This means the most similar elements would be flourine and Chlorine because they are both group 7 elements.

Answer : The correct name of [tex]H_2S[/tex] compound is, Hydrogen sulfide.

Explanation :

As we know that, [tex]H_2S[/tex] is a covalent compound in which the sharing of electrons takes place between hydrogen and sulfur. Both the elements are non-metals and hence, will form covalent bond.

The nomenclature of covalent compound is given by:

The less electronegative element is written first.

The more electronegative element is written then, and a suffix is added with it. The suffix added is '-ide'.

If atoms of an element is greater than 1, then prefixes are added which are 'mono' for 1 atom, 'di' for 2 atoms, 'tri' for 3 atoms and so on..

In [tex]H_2S[/tex], hydrogen is an electropositive element and sulfur is an electronegative element.

So, the correct name for [tex]H_2S[/tex] is hydrogen sulfide.

The compound H2S is accurately named as hydrogen sulfide. It's a poisonous, colorless gas often associated with the smell of rotten eggs, seen in hot springs and during the oxidation of natural gas.

The correct name for the compound H2S is hydrogen sulfide. In the case of binary compounds like this one (compounds made of two different elements), the first element is usually named fully while the second element is named as though it is an anion, which usually ends in -ide, hence 'sulfide' in hydrogen sulfide. Hydrogen sulfide is a toxic, colorless gas that exhibits the smell of rotten eggs. Nit causes this smell in hot springs and in the process of oxidizing natural gas.

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high amounts of sunlight  cold temperature

A minimal amount of sunlight, and cold temperature is the conditions seen in an aquarium. So the correct option is B.

Aquarium, freshwater or marine receptacle for aquatic animals, or a facility where a group of aquatic organisms is shown or researched

Many of the world's major cities now feature both public and commercial aquariums. Another category includes aquariums that primarily function as research facilities. Among the most well-known are those at Naples, the Oceanographic Museum of Monaco, the Plymouth Marine Laboratory in England, and the Scripps Institution of Oceanography in La Jolla, California. Transient aquariums that have functioned as displays at world fairs and expositions are another kind.

Marineland, the first oceanarium or huge marine aquarium, was founded as a private venture near St. Augustine, Fla., in 1938, with a massive communal fish pond and trained dolphins. The Miami Seaquarium is similar. The emphasis in this form of the aquarium is really on large containers, up to 1,000,000 gallons in size, in which a wide variety of fishes are housed together with no attempt to segregate them. Most exhibits at a formal aquarium (for example, the Shedd Aquarium in Chicago) divide the different varieties of fish.

Therefore the correct option is B.

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The boiling point of a 4.5 m solution of [tex]\( Na_2SO_4 \)[/tex] in water is [tex]115.6 \( ^\circ C \).[/tex]

The boiling point of a solution is elevated in proportion to the concentration of solute particles in the solution. The relationship between the boiling point elevation [tex](\( \Delta T_b \))[/tex] and the molal concentration of the solute ([tex]m[/tex]) is given by the equation:

[tex]\[ \Delta T_b = i \cdot k_b \cdot m \][/tex]

where:

- [tex]\( \Delta T_b \)[/tex] is the boiling point elevation,

- [tex]\( i \)[/tex] is the van 't Hoff factor, which represents the number of particles the solute dissociates into,

- [tex]\( k_b \)[/tex] is the ebullioscopic constant (for water, [tex]\( k_b = 0.52 \ ^\circ C \cdot kg \cdot mol^{-1} \)),[/tex]

- [tex]\( m \)[/tex] is the molality of the solution (moles of solute per kilogram of solvent).

For [tex]\( Na_2SO_4 \)[/tex], the van 't Hoff factor [tex]i[/tex] is 3, because one mole of [tex]\( Na_2SO_4 \)[/tex] dissociates into three moles of ions (2 moles of [tex]\( Na^+ \)[/tex] and 1 mole of [tex]\( SO_4^{2-} \))[/tex]

Given:

- [tex]\( m = 4.5 \ m \)[/tex] (where 1 m = 1 mol/kg),

- [tex]\( k_b = 0.52 \ ^\circ C \cdot kg \cdot mol^{-1} \),[/tex]

- [tex]\( i = 3 \).[/tex]

We can calculate the boiling point elevation as follows:

[tex]\[ \Delta T_b = i \cdot k_b \cdot m \][/tex]

[tex]\[ \Delta T_b = 3 \cdot 0.52 \ ^\circ C \cdot kg \cdot mol^{-1} \cdot 4.5 \ mol/kg \][/tex]

[tex]\[ \Delta T_b = 3 \cdot 0.52 \cdot 4.5 \][/tex]

[tex]\[ \Delta T_b = 15.6 \ ^\circ C \][/tex]

To find the boiling point of the solution, we add the boiling point elevation to the normal boiling point of water ([tex]100 \( ^\circ C \)[/tex]):

[tex]\[ T_b = T_{b(water)} + \Delta T_b \][/tex]

[tex]\[ T_b = 100 \ ^\circ C + 15.6 \ ^\circ C \][/tex]

[tex]\[ T_b = 115.6 \ ^\circ C \][/tex]

First calculate the number of moles. Molar mass of Calcium = 40.08 g/mol

Number of moles = 169 g / (40.08 g / mol) = 4.217 moles

Using Avogadros number, we can get the number of atoms:

Number of atoms = 4.217 moles * (6.022 x 10^23 atoms / moles) = 2.54 x 10^24 atoms

Final answer:

Here are each alkane and heir structures:

1. Propane (C₃H₈):

CH₃ - CHH₂ - CH₃

2. Butane (C₄H₁₀):

CH₃ - CHH₂ - CHH₂ - CH₃

3. Pentane (C₅H₁₂):

CH₃ - CHH₂ - CHH₂ - CHH₂ - CH₃

4. Hexane (C₆H₁₄):

CH₃ - CHH₂ - CHH₂ - CHH₂ - CH₂ - CH₃

Explanation:

In all of these alkanes, there are no secondary or tertiary carbons, as they have a linear structure without any branching. These structures follow the general formula CnH₂ₙ₊₂, where n is the number of carbon atoms.

Remember that these are just a few examples of alkanes with 3-6 carbons. There can be multiple isomers and variations of these alkanes based on different arrangements of the carbon atoms.

An alkane is a saturated hydrocarbon composed of carbon and hydrogen atoms, with only single covalent bonds between carbon atoms.

To draw the structures of alkanes with 3-6 carbon atoms and no secondary or tertiary carbon atoms, we need to consider the straight-chain (normal) isomers.

1.00 quart of mercury weight approximately 28.4 pounds.

To find the weight of 1.00 quart of mercury, given its density of 13.6 g/mL, follow these steps:

1. Convert quarts to milliliters:

2. Calculate the mass using density:

3. Convert grams to pounds:

The mass of fluorine in 36.5 g of SnF2 is approximately 8.85 g, calculated by finding the fraction of the mass due to fluorine in tin(II) fluoride based on its molar mass and multiplying it by the total mass of the compound.

To calculate the mass of fluorine (F) in grams in 36.5 g of tin(II) fluoride (SnF2), we need to consider the molar mass of SnF2 and the proportion of fluorine within the compound. The molecular weight of SnF2 is approximately 156.7 g/mol (119.7 for Sn and 37.0 for the two fluorine atoms). To find the amount of F in SnF2, we can set up a ratio based on the molar masses:

Next, calculate the fraction of the mass that is due to fluorine:

(38.0 g/mol F) / (156.7 g/mol SnF2) = 0.2426 (fraction of F in SnF2)

Finally, multiply the fraction by the total mass of SnF2 to obtain the mass of F:

36.5 g × 0.2426 = 8.8549 g F

Therefore, the mass of fluorine in 36.5 g of SnF2 is approximately 8.85 g.

The density of the metal would be equal to 277/38 = 7.28 g/cm^3

The ratio of an object's matter content to its volume is compared using the concept of density. High density describes an entity that contains a lot of matter in a small space. The density of a substance demonstrates the substance's density in a certain region.

Mass per unit volume is the definition of density for a substance. In essence, density is an indicator of how closely together matter is arranged. It is one of an object's special physical characteristics. Greek scientist Archimedes was the first to understand the density principle.

Knowing the formula and the corresponding units will make calculating density simple. Density can be symbolized by the letter D.

Therefore, the density of the metal is 7.28 g/cm^3.

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