Suppose a small island is home to two troops of monkeys. Every year, a certain fraction of each troop of monkeys are killed by predators. Every summer, each surviving pair of monkeys has one child. In this simplified model, the monkey population would look something like this:
Troop #1: Troop #2:
Year Season Number of
Monkeys
1 Spring 7
Summer 10
2 Spring 8
Summer 12
3 Spring 9
Summer 13
4 Spring 10
Summer 15
Year Season Number of
Monkeys
1 Spring 7
Summer 10
2 Spring 9
Summer 13
3 Spring 11
Summer 16
4 Spring 14
Summer 21
The first troop spends more time on the ground. The second troop spends more time in the trees.

Compare the sizes of the two monkey troops through time. Which of the following statements about the monkey troops is true?
A.
Because members of the first troop were better able to avoid predators, more of them were able to reproduce.
B.
Because members of the first troop were better able to reproduce, more of them were able to avoid predators.
C.
Because members of the second troop were better able to reproduce, more of them were able to avoid predators.
D.
Because members of the second troop were better able to avoid predators, more of them were able to reproduce.
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Answer:

9.72 g of O₂ are obtained in the decomposition

Explanation:

Reaction of decomposition is:

2KClO₃ → 2KCl + 3O₂

Ratio is 2:3. First, we determine the moles of chlorate

24.82 g. 1mol/ 122.55g = 0.202 moles

2 moles of chlorate can decompose into 3 moles of oxgen

Therefore, 0.202 moles of chlorate will decompose into (0.202 .3)/2 = 0.303 moles of O₂

We determine the mass of formed oxygen:

0.303 mol . 32g / 1mol = 9.72 g

Final answer:

The number of grams of O2 gas that can be obtained from 24.82 g of KClO3 is 9.725 g. This is calculated by converting the mass of KClO3 to moles, using the stoichiometric relationship from the balanced equation, and then converting moles of O2 to grams.

Explanation:

To calculate the number of grams of O2 gas that can be obtained from 24.82 g of KClO3, we need to follow a series of stoichiometric conversions. Initially, we must ensure that we have a balanced chemical equation, which for the decomposition of potassium chlorate to potassium chloride and oxygen gas is:

2 KClO3(s) → 2 KCl(s) + 3 O2(g)

This tells us that from every 2 moles of KClO3 we get 3 moles of O2. We can use the molar masses to convert between grams and moles:

Dividing the total mass of KClO3 by its molar mass gives us:

24.82 g KClO3 × (1 mol KClO3 / 122.55 g) = 0.2026 mol KClO3

Next, we use the stoichiometry of the balanced equation to determine the moles of O2:

0.2026 mol KClO3 × (3 mol O2 / 2 mol KClO3) = 0.3039 mol O2

Finally, we convert the moles of oxygen to grams:

0.3039 mol O2 × (32.00 g/mol O2) = 9.725 g O2

Therefore, from 24.82 g of KClO3, we can theoretically obtain 9.725 g of oxygen gas, assuming complete decomposition.

Answer:

Explanation:

Each orbital may contain a maximum of two electrons.

The energy level is the principal quantum number: 1, 2, 3, 4, 5, 6, 7.

The principal quantum number limits the kind of orbital (ℓ ) and the number of orbitals (mℓ ).

I. Principal quantum number, n = 1

  Angular or orbital quantum number : ℓ = 0 ⇒ ortibal s

  Magnetic quantum number:  mℓ = 0

                                 ⇒ number of orbitals 1 ⇒ number of electrons: 2

II. Principal quantun number, n = 2

  Angular or orbital quantum number : ℓ = 0 and 1 ⇒ ortibal s and p

  Magnetic quantum number:  

                                            for ℓ:  mℓ = 0: 1 s ortibal

                                            for ℓ = 1: mℓ = -1, 0, and +1:  3 p ortitals

                                 ⇒ number of orbitals 4 ⇒ number of electrons: 8

III. Principal quantun number, n = 3

    Angular or orbital quantum number : ℓ = 0, 1, and 2 ⇒ ortibal s, p and d

    Magnetic quantum number:  

                                            for ℓ:  mℓ = 0: 1 s ortibal

                                            for ℓ = 1: mℓ = -1, 0, and +1:  3 p ortitals

                                            for ℓ = 2: mℓ = -2, -1, 0, +1, and +2:  5 d ortitals

                                 ⇒ number of orbitals 9 ⇒ number of electrons: 18

IV. Principal quantun number, n = 4

    Angular or orbital quantum number : ℓ = 0, 1, 2, and 3 ⇒ ortibal s, p, d and f

    Magnetic quantum number:  

                                            for ℓ:  mℓ = 0: 1 s ortibal

                                            for ℓ = 1: mℓ = -1, 0, and +1:  3 p ortitals

                                            for ℓ = 2: mℓ = -2, -1, 0, +1, and +2:  5 d ortitals

                                            for ℓ = 3: mℓ = ±3, ±2, ±1, and 0: 7 f ortitals

                                 ⇒ number of orbitals 16 ⇒ number of electrons: 32.

Thus, you have:

energy level, n    maximum number of     maximum number of

                             orbitals                           electrons

      1                           1                                      2

      2                          4                                     8

      3                          9                                    18

      4                          16                                   32

Those numbers follow a rule: n² and 2n². You can verify that the previous numbers are in accordance with those formulas.

Answer:

The solution is shown in the attached image to this answer.

Explanation:

The first attached image is the complete question.

The second attached image is the solution to the question.

The major organic product formed when the compound undergoes a reaction with HNO3 and H2SO4 is the corresponding nitro compound, specifically 2-nitrobenzoic acid.

When the given compound reacts with a mixture of concentrated nitric acid (HNO3) and concentrated sulfuric acid (H2SO4), it undergoes a nitration reaction. This reaction results in the substitution of a nitro group (-NO2) at the meta position (position 2) of the benzene ring, yielding 2-nitrobenzoic acid as the major product.

The concentrated sulfuric acid serves as a catalyst and helps in the generation of the nitronium ion (NO2+), which is the electrophile responsible for attacking the benzene ring. The nitro group is introduced as a substituent on the aromatic ring, and the carboxylic acid group (-COOH) remains intact. Overall, this reaction is a common method for introducing nitro groups onto aromatic rings and is widely used in organic synthesis for the preparation of various nitroaromatic compounds.

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Answer:

0.1814 M

Explanation:

From the balanced equation of reaction:

[tex]2MnO_4^- + 16H^+ + 5C_2H_4^{2-} --> 2Mn^{2+} + 10CO_2 + 8H_2O[/tex]

2 mole of the permanganate requires 5 moles of oxalic acid.

Mole of 0.3577 g of oxalic acid = [tex]\frac{mass}{molar mass}[/tex]

                                    = 0.3577/90.03

                                       =0.00397 mole

Mole of permangante that will require 0.00397 mole of oxalic acid:

      = 5 x 0.00397/2

              = 0.00993 mole

Molarity of permanganate = mole/volume

Volume of permanganate = 54.77 mL = 0.05477 L

Molarity = 0.00993/0.05477

                   = 0.1814 M

The molarity of the permangante solution is 0.1814 M

Answer:

See explanation below

Explanation:

The reaction between permanganate and oxalic acid, is a redox reaction, and this can be balance in acid medium or basic medium.

The reaction (without being balanced) is the following:

MnO₄⁻ + H₂C₂O₄ -------> Mn²⁺ + CO₂ + H₂O

Now, to get the molarity, we need to use the following expression:

M₁V₁ = M₂V₂    (1)

Where:

1: permanganate

2: oxalic acid

And the moles:

n = M*V   (2)

However, expression (1) is only valid when the mole ratio between the two species, is the same (or 1:1). In this case, we do not know if the mole ratio is 1:1 because the reaction is unbalanced. Once the reaction is balanced we will see the mole ratio, and then, use the expression (1) to get the concentration.

Balancing the equation using the acid medium:

MnO₄⁻ + 8H⁺ + 5e⁻ -------> Mn²⁺ + 4H₂O     Reduction

H₂C₂O₄  ------------> 2CO₂ + 2e⁻ + 2H⁺         Oxidation

Equalling both equations:

(MnO₄⁻ + 8H⁺ + 5e⁻ -------> Mn²⁺ + 4H₂O) *2    

(H₂C₂O₄  ------------> 2CO₂ + 2e⁻ + 2H⁺) * 5  

___________________________________  

2MnO₄⁻ + 16H⁺ + 10e⁻ -------> 2Mn²⁺ + 8H₂O

5H₂C₂O₄  ------------> 10CO₂ + 10e⁻ + 10H⁺

____________________________________    

2MnO₄⁻ + 5H₂C₂O₄ + 6H⁺ -------> 2Mn²⁺ + 10CO₂ + 8H₂O

This is the balanced equation. According to this, we can say that the mole ratio is 2:5, therefore expression (1) becomes:

2M₁V₁ = 5M₂V₂   ---> solving for M₁:

M₁ = 5M₂V₂ / 2V₁   (3)  

Now that we know the expression, and the volume required, we need to get the concentration and volume of the acid. However, we do not know that, we only know the mass. So, we have to use the moles of oxalic acid to get the concentration. So replacing (2) in (3) we have:

M₁ = 5n₂ / 2V₁ (4)

Now, to get the moles, we need the molecular weight of the oxalic acid which is:

MM = (2*1) + (2*12) + (4*16) = 90 g/mol

The moles would be:

n = 0.3577 / 90 = 0.00397 moles

Finally, the concentration of the permanganate solution:

M₁ = 5*0.00397 / 2*0.05477

M₁ = 0.1812 M

Answer:

The answer to your question is below

Explanation:

This student is wrong.

Chemical bonds are forces that hold atoms together to form a molecule or compound. These interactions are inside the molecule. Example

Ionic bond: NaCl   (sodium and chlorine).

Intermolecular forces are weaker than chemical bonds and they are forces between atoms or molecules. These interactions are among different molecules.

Example

Two molecules of water interact forming hydrogen bridges.

Answer:

1. Nonmetals.  

2. Likely to form anions (except the noble gases).  

3. All of these  

4. Easily reduced (except the noble gases).

Explanation:

Elements with high electronegativities are found towards the upper right corner of the Periodic Table. Thus, they have all the above properties.

Nonmetals.  

 Likely to form anions (except the noble gases).  

 All of these  

Easily reduced (except the noble gases).

Therefore, Electronegative elements are known to be non-metals.

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Answer:

B. Relative Humidity

Answer : The balanced net ionic equation for the reactions are:

(A) [tex]2Ag^{+}(aq)+2Br^{-}(aq)\rightarrow AgBr(s)[/tex]

(B) [tex]H^{+}(aq)+OH^{-}(aq)\rightarrow H_2O(l)[/tex]

(C) [tex]Co^{2+}(aq)+S^{2-}(aq)\rightarrow CoS(s)[/tex]

Explanation :

Complete ionic equation : In complete ionic equation, all the substance that are strong electrolyte and present in an aqueous are represented in the form of ions.

Net ionic equation : In the net ionic equations, we are not include the spectator ions in the equations.

Spectator ions : The ions present on reactant and product side which do not participate in a reactions. The same ions present on both the sides.

Part A :

The balanced molecular equation will be,

[tex]2AgNO_3(aq)+MgBr_2(aq)\rightarrow Mg(NO_3)_2(aq)+2AgBr(s)[/tex]

The complete ionic equation in separated aqueous solution will be,

[tex]2Ag^+(aq)+2NO_3^{-}(aq)+Mg^{2+}(aq)+2Br^{-}(aq)\rightarrow Mg^{2+}(aq)+2NO_3^{-}(aq)+2AgBr(s)[/tex]

In this equation the species [tex]Mg^{2+}\text{ and }NO_3^-[/tex] are the spectator ions.

By removing the spectator ions from the balanced ionic equation, we get the net ionic equation.

The net ionic equation will be,

[tex]2Ag^{+}(aq)+2Br^{-}(aq)\rightarrow AgBr(s)[/tex]

Part B :

The balanced molecular equation will be,

[tex]HClO_4(aq)+KOH(aq)\rightarrow H_2O(l)+KClO_4(aq)[/tex]

The complete ionic equation in separated aqueous solution will be,

[tex]H^+(aq)+ClO_4^{-}(aq)+K^{+}(aq)+OH^{-}(aq)\rightarrow K^{+}(aq)+CLO_4^{-}(aq)+H_2O(l)[/tex]

In this equation the species [tex]K^{+}\text{ and }ClO_4^-[/tex] are the spectator ions.

By removing the spectator ions from the balanced ionic equation, we get the net ionic equation.

The net ionic equation will be,

[tex]H^{+}(aq)+OH^{-}(aq)\rightarrow H_2O(l)[/tex]

Part C :

The balanced molecular equation will be,

[tex](NH_4)_2S(aq)+CoCl_2(aq)\rightarrow 2NH_4Cl(aq)+CoS(s)[/tex]

The complete ionic equation in separated aqueous solution will be,

[tex]2NH_4^+(aq)+S^{2-}(aq)+Co^{2+}(aq)+2Cl^{-}(aq)\rightarrow 2NH_4^{+}(aq)+2Cl^{-}(aq)+CoS(s)[/tex]

In this equation the species [tex]NH_4^{+}\text{ and }Cl^-[/tex] are the spectator ions.

By removing the spectator ions from the balanced ionic equation, we get the net ionic equation.

The net ionic equation will be,

[tex]Co^{2+}(aq)+S^{2-}(aq)\rightarrow CoS(s)[/tex]

Final answer:

The net ionic equations are: 2Ag+ + 2Br- -> 2AgBr(s); H+ + OH- -> H2O(l); Co2+ + S2- -> CoS(s).

Explanation:

The net ionic equation for the reaction between silver nitrate (AgNO3) and magnesium bromide (MgBr2) is:

2Ag+ + 2Br- -> 2AgBr(s)

The net ionic equation for the reaction between perchloric acid (HClO4) and potassium hydroxide (KOH) is:

H+ + OH- -> H2O(l)

The net ionic equation for the reaction between ammonium sulfide ((NH4)2S) and cobalt(II) chloride (CoCl2) is:

Co2+ + S2- -> CoS(s)

Answer:

the awnser is 20dggrees

Explanation:

Answer:

3.7g

Explanation:

First we calculate the molar mass of the drug. Secondly, we now obtain the mass of the drug solution required at the given concentration to obtain a 1.5 milligram dose of the drug. The substitution is now properly done and the mass is obtained as 3.7g of the nalorphine drug which is a relative or morphine used to combat withdrawal symptoms in narcotic users.

Final answer:

Bread and whole grain foods contain large polysaccharide molecules which are composed of carbon, hydrogen, and oxygen. Carbon is the element present in carbohydrates and is essential in forming biomolecules found in foods like bread. Glycogen is an example of a complex polysaccharide composed of these elements.

Explanation:

Breads and other whole-grain foods are composed of large polysaccharide molecules which include hydrogen, oxygen, and the other element is carbon. Carbohydrates, which are found in these foods, are made up of carbon (C), hydrogen (H), and oxygen (O) atoms. Polysaccharides like starch and glycogen are complex carbohydrates, which are made up of many monosaccharide units.

The nutrient that is part of carbohydrates, like bread, also present in proteins and nucleic acids that forms biomolecules, is carbon. The complex carbohydrate glycogen, for example, has a chemical formula of C24H42021, indicating it is composed of carbon, hydrogen, and oxygen elements. Glycogen is a polysaccharide, as its name suggests (poly- meaning many and saccharide meaning sugar), and not a monosaccharide because it consists of multiple sugar units.

Answer:

The molarity of the solution is 1,48M

Explanation:

In chemistry, molarity, M, is an unit of concentration that represent the ratio between moles of solute and volume of solvent in liters.

In the problem, the solute is potassium carbonate, K₂CO₃, and the solvent is water.

There are 6.35moles of potassium carbonate and 4.30L of water. That means molarity is:

6,35mol / 4,30L = 1,48M

I hope it helps!

On a molecular level, the author means that no compound is grosser than any other, as all compounds are made up of the same fundamental building blocks: atoms and molecules.

The author means that, on a molecular level, no one compound is inherently more disgusting or repulsive than another. This statement suggests that all compounds, regardless of their odor, appearance, or taste, are made up of the same fundamental building blocks: atoms and molecules. For example, two compounds may have different smells, but they are both composed of the same elements and bond together in similar ways. So, while certain compounds may be perceived as gross or unpleasant to our senses, from a molecular standpoint, they are all equally fascinating and interconnected.

Answer:

Explanation:

The detailed steps and calculations is as shown in the attached file.

Answer:

 Number of molecules of H2=4.5454375x[tex]10^{21}[/tex]

Explanation

Given:

P1=P2=0.5 atmosphere=0.505x[tex]10^{5}[/tex]pa

T1=T2=300k

V1=10 liters of O2

N=5.0x[tex]10^{22}[/tex] molecules

10 liters of H2

V2=? liters of O2

H2=1/16 of O2

Procedure:

for every liter of H2, there are 16 liters of O2 since H2=1/16 of O2,

Therefore, 10 liters of H2= 160 liters of O2 i.e.

V2=160 liters of O2.

Applying ideal gas equation,

VP=NkT :where P is pressure, V is volume, N is number of molecules, T is temperature in kelvin and k is Boltzman constant=1.38X[tex]10^{-23}[/tex]J/K.

considering change in volume of O2, N can be calculated as follows:

V1P1=N1kT1..................................(1)

V2P2=N2kT2...............................(2)

dividing (2) by (1)

V2P2/V1P1=N2kT2/N1kT1

but P1=P2 and T1=T2 since they remain the same, they cancel out.

∵ V2/V1=N2/N1

substituting values, we have

160/110=N2/5.0x[tex]10^{22}[/tex]

N2=1.4545x5.0x[tex]10^{22}[/tex] =7.2727x[tex]10^{22}[/tex] molecules of O2

Recall that

N2 of H2=1/16 of N2 of O2

∵Number of molecules of H2=1/16 of 7.2727x[tex]10^{22}[/tex]

=4.5454x[tex]10^{21}[/tex]

Number of molecules of H2=4.5454375x[tex]10^{21}[/tex]

Answer:

Empirical formula (which matches the molecular formula) is = PbC₈H₂₀

Explanation:

Our sample: 60 g of tetraethyl lead

In order to determine the compound empirical formula we need the centesimal composition:

(Mass of element / Total mass) . 100 =

(38.43 g lead / 60g ) . 100 = 64.05%

(17.83 g C / 60g) . 100 = 29.72%

(3.74 g H / 60g) . 100 = 6.23 %

These % are the mass of the elements in 100 g of compound. Let's find out the moles of them:

64.05 g / 207.2 g/mol = 0.309 moles

29.72 g / 12 g/mol = 2.48 moles

6.23 g/ 1 g/mol = 6.23 moles

Next, we divide the moles, by the lowest value of them (0.309)

0.309 / 0.309 = 1 mol Pb

2.48 / 0.309 = 8 mol C

6.23 / 0.309 = 20 mol H

There, we have our formula PbC₈H₂₀

Answer:

Solar nebula

Explanation:

The theory of the origin of the solar system emanates from the believe that a dense giant spinning cloud of dust condensed to produce our solar system.

This cloud of dust is called the solar nebula.

Answer:

The answer to your question is letter A

Explanation:

Data

Empirical formula CH₂

Molecular weight = 70 u

Process

1.- Calculate the molecular weight of the empirical formula (CH₂)

CH₂ = (12 x 1) + (1 x 2) = 12 + 2 = 14 g

2.- Divide the molecular weight by the molecular weight of the empirical formula

                      70/14 = 5

3.- Write the empirical formula

                       5(C₁H₂) = C₅H₁₀

1. C₅H₁₀

Given:

Empirical formula = CH₂

Molecular weight = 70 u

To find Molecular formula of the compound:

1.- Calculate the molecular weight of the empirical formula (CH₂)

CH₂ = [tex](12 * 1)+(1*2)=12+2=14 u[/tex]

(As molecular weight of C=12u and H= 1u)

2.- Divide the molecular weight by the molecular weight of the empirical formula

[tex]\frac{\text{Molecular weight}}{\text{ Molecular weight of Empirical formula}} = \frac{70}{14} =5[/tex]

3.- Write the empirical formula

5(C₁H₂) = C₅H₁₀

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Answer:

C

Explanation:

The question asks to know what happens when an electron moves from a higher energy level to a lower energy level.

Firstly, it is important to note that when an electron moves from a lower energy level to a higher energy level, energy is absorbed by the atom. Conversely, when an electron moves from a region of higher energy to a region of lower energy, energy is released by the atom.

Thus we can say that the movement of an electron from a region of higher energy to a region of lower energy can result in the emission of a photon of light as energy is released by the atom

In electron energy transition when an electron moves from a higher energy level to a lower one in an atom, it emits a photon. This is because the electron discards the excess energy it no longer needs when it shifts to a less energetic state. These energy releases as photons create atomic spectral lines that help astronomers identify certain elements in the universe.

This physics-related query pertains to the behavior of electrons in electromagnetic radiation, which can be best understood through photons -- particles of light. When an electron goes from a higher energy level to a lower one within an atom, option (c) - a photon is emitted is accurate. This movement signifies that an electron is transmitting energy, which happens in the form of a photon.

In a higher energy state, the electron has more energy than it requires to maintain its 'orbit' around the nucleus of the atom. Consequently, when it descends to a lower energy level, the reduction in energy gets emitted as a photon. The different energy levels in an atom correspond to certain fixed amounts of energy; as such, the energy difference between the higher and lower levels translates into a photon of a specific frequency. This entire process forms the basis of atomic spectral lines, that aid astronomers in determining the elements present in a celestial body.

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Answer:

FALSE

Explanation:

The density of seawater depends on certain factors such as-

Thus, the above-given statement is False.

Answer:

1. Hydrogen

Explanation:

The interior of these planets contains liquid hydrogen (the Earth has liquid iron in it).

When this element is subjected to tremendous pressures (as in Jupiter and Saturn), the electrons of each hydrogen atom can "jump" to other atoms. This property allows liquid hydrogen to behave with a metal.

With the rotation of the planets and the large amount of constant energy emitted by the nucleus, currents are induced in liquid hydrogen, giving rise to magnetic fields that propagate for millions of kilometers in space (Jupiter's magnetic field is fourteen times stronger than Earth's, for example).

Answer:

In an exothermic reaction, q is negative while w is positive.

In an endothermic reaction, q is positive while w is negative

Explanation:

An Exothermic reaction is one in which the heat content of the system is greater than the heat content of the surroundings. As a result of this, heat (measured by Q) is given off into the surroundings and the surroundings is hotter than than the system. The heat emitted does work against the surroundings, hence the value of work done W is positive.

An endothermic reaction is the opposite of an exothermic reaction.

During an endothermic reaction, the heat content of the reactants is lesser than the heat content of the products. The surroundings then does work on the system , resulting in heat (measured by Q) being absorbed from the surroundings into the system, making the system hotter than than the surroundings. The value of work done W in an endothermic reaction is negative because the system does work against the surroundings.

Answer:17.955atm

Explanation:Pv=nrt

P= nrt/v

P= 7.25*0.08205*360/11.90

P= 214.1505/11.90

P=17.995atm

Answer:

Cellular respiration is the process by which the molecules of food are broken down into simple components due to the oxidation process resulting in the release of cellular energy in the form of ATP. Cellular respiration involves the oxidation of fats, carbohydrates (sugars), and proteins which are fuels for the cellular respiration process.

The combustion is also an exothermic reaction just like cellular respiration. Combustion is a process of burning, in this, the reactants are reacted with oxygen gas to produce carbon dioxide and water. For example, gasoline is octane and it burns to produce water and carbon dioxide as products.

Combustion and cellular respiration are energy-releasing processes with differences in mechanisms and outcomes. Cellular respiration generates ATP and happens in cells, while combustion releases energy as heat and light.

Combustion and cellular respiration are two processes that release energy through the breakdown of substances, but they differ significantly in their mechanisms and outcomes.

Key Differences

In summary, cellular respiration occurs in the mitochondria of cells and converts glucose into ATP using oxygen, whereas combustion breaks down various fuels with oxygen to release energy as heat and light.

Answer:True

Explanation:

Answer: The kilogram is the SI unit of mass and it is the almost universally used standard mass unit.

Explanation: When we use kilograms to measure weight, we are actually referring to kgf or kilogram-force.

Answer: covalent bond

Explanation:

An ionic bond is formed when an element completely transfers its valence electron to another element. The element which donates the electron is known as electropositive element or the metal and the element which accepts the electrons is known as electronegative element or non metal. Example: [tex]NaCl[/tex]

A covalent bond is formed when an element shares its valence electron with another element. This bond is formed between two non metals. Example: [tex]F_2[/tex] which is formed by sharing of one electron each from flourine atom.

A covalent bond is formed when one pair of electrons is shared between two atoms. This bond helps the atoms to complete their valence shell. Multiple pairs of electrons can also be shared, resulting in double and triple bonds.

When one pair of electrons is shared between two atoms, a covalent bond is formed. This type of bond is a strong one that can be formed between two atoms of the same or different elements. The sharing of electrons fulfills each atom's need to complete its valence shell, or outer ring of electrons.

For example, hydrogen gas (H-H) is an instance of a single covalent bond where two atoms of hydrogen each share their solitary electron.

Further, it is important to note that more than one pair of electrons can be shared between a pair of atoms, leading to what we call double and triple bonds. For instance, in formaldehyde (CH₂O), a double bond forms as two pairs of electrons are shared between the carbon and oxygen atoms.

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Answer:

The new volume of the balloon when the pressure equalised with the pressure of the atmosphere = 494 L.

The balloon expands by am additional 475 L.

Explanation:

Assuming Helium behaves like an ideal gas and temperature is constant.

According to Boyle's law for ideal gases, at constant temperature,

P₁V₁ = P₂V₂

P₁ = 26 atm

V₁ = 19.0 L

P₂ = 1 atm (the balloon is said to expand till the pressure matches the pressure of the atmpsphere; and the pressure of the atmosphere is 1 atm)

V₂ = ?

P₁V₁ = P₂V₂

(26 × 19) = 1 × V₂

V₂ = 494 L (it is assumed the balloon never bursts)

The new volume of the balloon when the pressure equalised with the pressure of the atmosphere = 494 L.

The balloon expands by am additional 475 L.

Hope this Helps!!!

Using the ideal gas law, the volume of the balloon when it stops inflating and the pressures equalize would be 494.0 L, as calculated from the initial pressure and volume of the tank and the atmospheric pressure.

The question concerns the behavior of gases under different conditions and relates to the ideal gas law, which is a fundamental concept in chemistry. When a balloon is filled with helium from a tank with a pressure of 26.0 atm and a volume of 19.0 L, the balloon will inflate until the pressure inside the balloon equals the outside atmospheric pressure. At this point, the volume of the balloon could be derived using the ideal gas law, which states that for a fixed amount of gas at constant temperature, the product of the pressure and volume (P1V1) will be equal to the product of the final pressure and volume (P2V2). In this scenario, assuming the temperature remains constant and the atmospheric pressure is 1 atm, we apply the equation P1V1 = P2V2.

Given that P1 is 26.0 atm and V1 is 19.0 L, and P2 is 1.0 atm (atmospheric pressure), we can solve for V2 as follows: V2 = (P1V1/P2) = (26.0 atm * 19.0 L) / 1.0 atm = 494.0 L. The volume of the balloon when it stops inflating and the pressures equalize would be 494.0 L.

Answer:

N2= 193.25mmHg

Cl2= 579.75mmHg

Explanation:

Total number of moles=4

For N2 mole fraction=1/4

Partial pressure of N2= 1/4× 773= 193.25mmHg

For Cl2, mole fraction= 3/4

Partial pressure of Cl2= 3/4 × 773 = 579.75 mmHg

The correct partial pressures of each gas in the container are:

[tex]\[ P_{\text{N}_2} = \frac{2}{3} \times 773 \text{ mmHg} \] \[ P_{\text{Cl}_2} = \frac{1}{3} \times 773 \text{ mmHg} \][/tex]

To find the partial pressures of each gas, we use Dalton's Law of Partial Pressures, which states that the total pressure exerted by a mixture of gases is equal to the sum of the partial pressures of each individual gas. The chemical equation for the decomposition of nitrogen trichloride (NCl3) is:

[tex]\[ 2\text{NCl}_3(l) \rightarrow 2\text{N}_2(g) + 3\text{Cl}_2(g) \][/tex]

From the stoichiometry of the balanced equation, we see that 2 moles of NCl3 decompose to form 2 moles of N2 and 3 moles of Cl2. Therefore, for every mole of NCl3 that decomposes, 1 mole of N2 and 1.5 moles of Cl2 are produced. This gives us a molar ratio of N2 to Cl2 of 2:3 or, simplified, 2 parts N2 for every 3 parts Cl2, which corresponds to a ratio of 2/5 for N2 and 3/5 for Cl2 in the mixture.

Since the total pressure of the mixture is 773 mmHg, we can calculate the partial pressure of each gas by multiplying the total pressure by the respective molar ratios:

For nitrogen (N2):

[tex]\[ P_{\text{N}_2} = \frac{2}{5} \times 773 \text{ mmHg} \] \[ P_{\text{N}_2} = \frac{2}{3} \times 773 \text{ mmHg} \][/tex]

For chlorine (Cl2):

[tex]\[ P_{\text{Cl}_2} = \frac{3}{5} \times 773 \text{ mmHg} \] \[ P_{\text{Cl}_2} = \frac{1}{3} \times 773 \text{ mmHg} \][/tex]

Thus, the partial pressure of nitrogen gas (N2) is[tex]\( \frac{2}{3} \times 773 \text{ mmHg} \)[/tex] , and the partial pressure of chlorine gas (Cl2) is [tex]\( \frac{1}{3} \times 773 \text{ mmHg} \)[/tex]. These are the partial pressures of each gas in the container after the decomposition of liquid nitrogen trichloride.

Explanation:

Answer:

This tells us the radial velocity of the object and that the object is approaching or coming towards us.

Explanation:

Certain chemicals radiate with particular wavelengths or colors  when their temperature is raised or when they are charged electrically. Also observable are dark strokes separating the spectrum known as absorption lines

These spectral lines of chemicals are well known as stated above and from the phenomenon of Doppler effect, spectroscopy can be used to detect the movement of a distant object by the change of the emitted frequency of the wavelength

The Doppler effect is used in calculating the radial velocity of a distant object due to the fact that an approaching object compresses its emitted signal wavelength while a receding object has a longer wavelength than normal