What are the three most abundant elements found on the earths crust that combine to form minerals?
A. Silicon, Iron, Aluminum
B. Oxygen, Silicon, Aluminum
C. Iron, Aluminum, Magnesium
D. Oxygen, Silicon, Iron

Asking a question is the answer

As shown in scheme attached below, Limonene (C₁₀H₁₆) contains two double bond one within the six membered ring and another outside the ring.

Hence, it is an unsaturated compound. As we know an Addition reaction takes place in unsaturated compounds. Therefore, an addition reaction called as Halogenation reation or more specifically Bromination reaction takes place when Limonene is treated with Bromine in the presence of inert solvent like tetrachloromethane.

The reaction is shown below, two moles of Br₂ are added across two double bonds of Limonene yielding a product with chemical formula C₁₀H₁₆Br₂.

The progress of this reaction can be easily be monitored as the color of Bromine discharges with the formation of tetrabromo product.

The major product formed when limonene reacts with bromine is tetra brominated limonene and that is attached in the image.

Further Explanation:

Electrophilic addition reaction is defined as an organic reaction in which an electrophile attacks on the electron-rich pi bond and add across the double bonds forming two new sigma bonds. An electrophile is an electron deficient species.

The reaction of alkene with bromine is an electrophilic addition reaction. The mechanism of addition can be illustrated in two steps. In the first step, [tex]{\text{B}}{{\text{r}}_{\text{2}}}[/tex] comes in the vicinity of olefin bond and being electrophilic it attacks on the electron-rich olefinic bond, forming a sigma bond to each of the olefinic bond. Such interaction results in formation of a bromonium ion intermediate that is three-membered intermediate rings.

In the second step, the strained three-membered ring then opens up such that the other bromine atom can attack at the electron-deficient carbon atom.

The limonene is a terpenoid that has olefinic bonds present inside the ring as well as on the side chain. The reaction of limonene with bromine is an electrophilic addition reaction

The mechanistic pathway and the stereospecific anti-addition of bromine to alkenes is described in the attached image.

This attack proceeds in a stereospecific manner such that only anti addition is allowed and the addition product has the trans stereochemistry.

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Answer details:

Grade: College

Subject: Chemistry

Chapter: Electrophilic addition reaction

Keywords: limonene, electrophilic addition, major product, olefin, anti-addition, anti-addition, stereospecific.

Answer: Option (2) is the correct answer.

Explanation:

In solid state, substances or elements that contain unpaired electrons are able to conduct heat and electricity.

This is because for conducting heat and electricity availability of free or unpaired electrons is necessary.

For example, atomic number of copper is 29 and its electronic distribution is 2, 8, 18, 1.

Whereas ionic compounds can only conduct heat and electricity when they are present in aqueous solution.

This is because then they are dissociated into ions.

Thus, we can conclude that Cu is the solid which most easily conduct electricity.

The alkene that would undergo acid-catalyzed hydration without rearrangement to give 1-methylcyclohexanol is 1-methylcyclohexene. During hydration, one of the carbon-carbon double bonds breaks, binds with hydrogen, and the other hydrogen forms a bond with the oxygen to form an alcohol.

The major product of the acid-catalyzed hydration of an alkene without rearrangement is 1-methylcyclohexanol. This suggests that the initial alkene contains a double bond which would shift to form the alcohol after the reaction. By adding water and acid to an alkene, we have the general reaction mechanism:

Therefore, the structural formula of the alkene that would produce 1-methylcyclohexanol through an acid-catalyzed hydration reaction without rearrangement is 1-methylcyclohexene.

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Let us say that R is the major enantiomer, while S is the minor enantiomer, therefore the formula for enantiomeric excess (ee) is:

ee = (R – S) * 100%

Let us further say that the fraction of R is x (R = x), and therefore fraction of S is 1 – x (S = 1 – x), therefore:

75 = (x – (1 – x)) * 100

75 = 100 x – 100 + 100 x

200 x = 175

x = 0.875

Summary of answers:

R = major enantiomer = 0.875 or 87.5%

S = minor enantiomer = (1 – 0.875) = 0.125 or 12.5%

Answer:

here u go all the anser to the qustion

Marcia is given an incomplete chemical equation that includes the number of nitrogen atoms present in the products of the reaction. How can she conclude that the reaction started with three nitrogen atoms?

There would have to be three nitrogen atoms in the products. The law of conservation of matter states that the amount of substance before a reaction occurs should be the same as the amount of substance after the reaction.

Sample Response: There would have to be three nitrogen atoms in the products. The law of conservation of matter states that the amount of substance before a reaction occurs should be the same as the amount of substance after the reaction.  

Which facts did you include in your response? Check all that apply.

There are three nitrogen atoms in the products.

The law of conservation of mass states that the amount of substance should be the same before and after a reaction.

Explanation:

The geometry around the left-most carbon in CH2CHCH3 is trigonal planar.

The geometry around the left-most carbon in the molecule CH2CHCH3 is trigonal planar.

When looking at the molecule, we can see that the left-most carbon is bonded to three other atoms: two hydrogen atoms and one carbon atom. Since the left-most carbon has three bonded atoms and no lone pairs, its geometry is trigonal planar.

This means that the three bonding pairs are arranged in a flat triangle around the carbon atom.

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The leftmost carbon in the molecule CH2CHCH3, also known as propene, has a tetrahedral conformation because of its sp³ hybridization. The atoms around the carbon are spaced so that the angles between them are approximately 109.5°, similar to methane (CH4).

The molecule CH2CHCH3 is also known as propene. It consists of a linear carbon chain, and the arrangement of atoms impacts its three-dimensional shape or conformation. Let's focus on the left-most carbon, which has two hydrogen atoms and two carbon atoms bonded to it.

Taking a look at this particular carbon, it shares three of its electrons with the hydrogen atoms as well as with the neighboring carbon atom in single, covalent bonds. The other electron forms a double bond with the middle carbon. This gives the left-most carbon a tetrahedral conformation. The sp³ hybridization of the carbon atom displays this tetrahedral geometry, with each atom around the carbon spaced in a way that angles between them are about 109.5°. This is similar to the molecule methane, CH4, which also has a tetrahedral geometry.

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10.535 ₓ 10²³ molecules

Given data:

Moles of dihydrogen monoxide = 1.75

No. of molecules of dihydrogen monoxide = ?

Solution:

1 mole of solution = 6.02 ₓ 10²³ molecules

1.75 mole of solution = (6.02 ₓ 10²³) ₓ 1.75

                                   = 10.535 ₓ 10²³ molecules

Final answer:

An azeotrope is a mixture that retains the same composition in both liquid and vapor states when boiled. This property limits the purity of ethanol to about 95.6% through fractional distillation because the ethanol-water mixture's vapor composition becomes identical to the liquid. To surpass this azeotropic point and obtain higher purity ethanol, specialized techniques must be used.

Explanation:

An azeotrope is a mixture of two or more liquids that retains the same composition in the liquid and vapor states because it boils at a constant temperature. This occurs because the vapor has the same composition as the liquid mixture due to the specific intermolecular interactions between the different components. A common example is the azeotropic mixture of approximately 95.6% ethanol and 4.4% water by mass, which has a boiling point of 78.1 °C.

When attempting to obtain pure ethanol by fractional distillation, the presence of an azeotrope poses a limitation. Since the vapor generated from the azeotropic mixture has the same percentage composition as the liquid, the usual effectiveness of fractional distillation in separating substances based on different boiling points is thwarted. Therefore, achieving ethanol purity higher than 95.6% through conventional distillation is not possible due to the formation of this azeotrope with water.

Some other methods, like the addition of a third component to break the azeotrope or the use of molecular sieves for dehydration, are necessary to produce ethanol with higher purity. In the context of ethanol production, the presence of azeotropes is why standard distillation techniques cannot yield 100% pure ethanol, and additional treatments are needed to reach such high purity levels.

Answer:

2SO2(g)+O2(g)→2SO3(g)

Explanation:

Two moles of sulfur dioxide needs to react with 1 mole of oxygen to form 2 moles of sulfur trioxide.

The chemical equation for the reaction between sulfur dioxide gas and oxygen gas to form sulfur trioxide gas is 2 SO₂(g) + O₂(g) → 2 SO₃(g), with all substances in the gaseous state.

The reaction between sulfur dioxide gas and oxygen gas to form sulfur trioxide gas can be expressed as the following balanced chemical equation:

2 SO₂(g) + O₂(g) → 2 SO₃(g)

In this equation, (g) indicates that sulfur dioxide (SO₂), oxygen (O₂), and sulfur trioxide (SO₃) are all in the gaseous phase. This reaction is a fundamental step in the industrial synthesis of sulfuric acid and is exothermic, releasing energy in the form of heat.

Explanation:

Potassium nitrate is a chemical compound with chemical formula [tex]{KNO}_3[/tex]. The shape of potassium nitrate is orthorhombic or regular prism.

Potassium nitrate has a large solubility difference in hot and cold water 2460 gram per litre at 100 degree celsius and 133 gram per litre at 0 degree celsius. Firstly we can dissolve potassium nitrate in hot water, and then let the water cool down.

On the either side, the quantity of nitrate will be greater than water is able to dissolve. So, the excess will come out from the solution as in the form of crystals. Crystals are usually formed by the microscopic particles and growing by regular layers of atoms are bond to one another.

Answer:

the anser is b

Explanation:

The type of bond that a Phosphorous pentachloride have is an Ionic Bonding. It is a form of chemical bond that encompasses the electrostatic attraction between oppositely charged ions which serves as the primary interaction happening in ionic compound. Phosphorus has 5 valence electrons and Chlorine has 7 valence electrons. Phosphorus contributes 1 electron to each chlorine and all the 6 achieve 8 electrons in the outer shell thus creating an ionic bond.

Answer:

PCl5 is a covalent bond

Explanation:

Ionic bonds are bonds between a metal and a non-metal.

Covalent bonds are bonds between 2 or more non-metals.

Neither P or Cl are metals, therefore PCl5 has a covalent bond.

Answer:

Concentration: 0,52

Explanation:

Remember that the concentration of a solution, is the calculus of dividing the amount of solute, could be in grams, mililiters, moles, by the amount of solvent in which the solute is going to be dissolved, in this case we will use the data provided to solve with the next formula:

[tex]C1V1=C2V2\\C2=\frac{C1*V1}{V2}\\ C2=\frac{65*6}{750}\\ C2=0,52[/tex]

So the concetration will be 0,52 m

The concentration of the diluted solution is 0.52 M

Dilution is simply reducing the concentration of a solution by the application of water.

The concentration of a diluted solution can be obtained by using the following formula:

Where:

C₁ => is the concentration of the stock solution

V₁ => is the volume of the stock solution

C₂ => is the concentration of the diluted solution

V₂ => is the volume of the diluted solution.

With the above formula, we can obtain the concentration of the diluted solution as follow:

Volume of stock solution (V₁) = 65 mL

Concentration of stock (C₁ ) = 6 M

Volume of diluted solution (V₂) = 750 mL

C₁V₁ = C₂V₂

6 × 65 = C₂ × 750

390 =  C₂ × 750

Divide both side by 750

C₂ = 390 / 750

Therefore, the concentration of the diluted solution is 0.52 M

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The Lewis structure for HNC (hydrogen isocyanide) consists of a hydrogen atom bonded to a nitrogen atom, which is then bonded to a carbon atom. The formal charges assigned to each atom are H: 0, N: 0, and C: -1.

The Lewis structure for HNC (hydrogen isocyanide): Determine the total number of valence electrons,

1. Determine the total number of valence electrons:

  Hydrogen (H) has 1 valence electron.

  Nitrogen (N) has 5 valence electrons.

  Carbon (C) has 4 valence electrons.

Total valence electrons = 1 (H) + 5 (N) + 4 (C) = 10 valence electrons

2. Place the least electronegative atom (hydrogen) in the center and connect it to the more electronegative atoms (nitrogen and carbon) using single bonds.

                H

                 |

            N - C

3. Fill the remaining valence electrons around each atom to complete their octets (except hydrogen, which only needs 2 electrons).

  H: 2 electrons (1 bond)

  N: 4 electrons (1 bond) + 4 electrons (lone pairs) = 8 electrons (full octet)

  C: 4 electrons (1 bond) + 4 electrons (lone pairs) = 8 electrons (full octet)

                H

                 |

            N - C

            :   :

4. Check if all atoms have achieved their octets. In this case, they have.

The Lewis structure for HNC is:

                H

                 |

            N - C

            :   :

Let's assign formal charges to each atom. The formal charge of an atom is calculated by comparing the number of valence electrons an atom has in a Lewis structure with the number of electrons it "owns" in a molecule.

To calculate the formal charge, we use the formula:

Formal charge = Valence electrons - (Non-bonded electrons + 1/2 * Bonded electrons)

For each atom in HNC:

H: Formal charge = 1 - (0 + 1/2 * 2) = 0

N: Formal charge = 5 - (4 + 1/2 * 2) = 0

C: Formal charge = 4 - (4 + 1/2 * 2) = -1

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Answer: -

Rutherford and Soddy's research involved:

3)The theory that uranium successively disintegrated to lead

Radioactivity involves conversion of one atom of an element into another by particle decay or radiation. They stated the disintegration theory of radioactivity, also discovering a large number of radioactive elements.

They both got Nobel prizes as well.

By using proportional rule, the simplest formula can be calculated as [tex]\rm \bold { Cu_2O}[/tex]

Molar mass of Copper is 63.54 g

Molar mass of Oxygen is 16

Here,

The mole of copper is 0.0393

The moles of oxygen is  0.0194

Hence, by using proportional rule, the simplest formula can be calculated as [tex]\rm \bold { Cu_2O}[/tex].

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a compound is a elements that are bonded together chemically