For each pair below, select the sample that contains the largest number of moles .

Answers:  

1.02 g

Explanation:  

We know we will need a balanced equation with masses and molar masses, so let’s gather all the information in one place.  

M_r:       26.98              101.95  

               4Al + 3O₂ ⟶ 2Al₂O₃

Mass/g:   54  

1. Calculate the moles of Al  

Moles Al = 54 × 1/26.98  

Moles Al = 2.00 mol Al  

=====  

2. Calculate the moles of Al₂O₃  

The molar ratio is 2 mol Al₂O₃:4 mol Al  

Moles of Al₂O₃ = 2.00 × 2/4  

Moles of Al₂O₃ = 1.00 mol Al₂O₃

======  

3. Calculate the mass of Al₂O₃  

Mass of Al₂O₃  = 1.00 × 101.95

Mass of Al₂O₃  = 1.02 g

Answer : The mass of [tex]Al_2O_3[/tex] produced will be, 101.96 grams

Explanation : Given,

Mass of Al = 54 g

Molar mass of Al = 27 g/mole

Molar mass of [tex]Al_2O_3[/tex] = 101.96 g/mole

First we have to calculate the moles of Al.

[tex]\text{Moles of }Al=\frac{\text{Mass of }Al}{\text{Molar mass of }Al}=\frac{54g}{27g/mole}=2mole[/tex]

Now we have to calculate the moles of [tex]Al_2O_3[/tex]

The given balanced chemical reaction is,

[tex]4Al+3O_2\rightarrow 2Al_2O_3[/tex]

From the balanced reaction we conclude that,

As, 4 moles of Al react to give 2 moles of [tex]Al_2O_3[/tex]

So, 2 moles of Al react to give [tex]\frac{2}{4}\times 2=1mole[/tex] of [tex]Al_2O_3[/tex]

Now we have to calculate the mass of [tex]Al_2O_3[/tex]

[tex]\text{Mass of }Al_2O_3=\text{Moles of }Al_2O_3\times \text{Molar mass of }Al_2O_3=1mole\times 101.96g/mole=101.96g[/tex]

Therefore, the mass of [tex]Al_2O_3[/tex] produced will be, 101.96 grams

1) Answer is: D. Writing a hypothesis.

The scientific method is a process for experimentation that is used to explore observations.

Steps of the scientific method:

1) ask a question about something that is observed.

2) do background research.

3) construct a hypothesis, an attempt to answer questions with an explanation that can be tested.

4) test of hypothesis.

5) analyze collected data and draw a conclusion.

2) Answer is: A. Carbon and oxygen are chemically bonded in it.

A compound (in this example carbon dioxide CO₂) is a pure substance because its molecule cannot be broken down into simpler particles by physical means.

A chemical compound is a chemical substance composed of many identical molecules composed of atoms held together by chemical bonds.

Carbon dioxide (CO₂) are inorganic compounds with covalent bonds between carbon and oxygen.

3) Answer is: B. Components that are mixed can be in different states of matter.

A single substance can be used to make a mixture if the substance is composed of more than one element is not correct, because mixture is composed of at least two substances. For example mixture of water and alcohol ethanol.

There is a definite recipe to make each mixture, so the composition of a mixture is set is not correct, because composition of mixture can vary.

Components that are mixed can be in different states of matter is correct, for example mixture of salt (solid) and water (liquid).

the answer is Lithium.

The question is incomplete, here is the complete question.

Which metal will form a compound with the general formula [tex]M_2CO_3[/tex] when it combines with a carbonate ion

A. Beryllium  

B. Aluminum

C. Calcium

D. Lithium

Answer: The metal that will form the given compound is lithium.

Explanation:

We are given:

A general chemical formula of carbonate, which is [tex]M_2CO_3[/tex]

The given compound is an ionic compound.

Carbonate is a polyatomic ion having chemical formula [tex]CO_3^{2-}[/tex]

Metal ion has a charge of +1.

For the given options:

Option A: Beryllium is the 4th element of the periodic table having electronic configuration of [tex]1s^22s^2[/tex]

This element will loose 2 electrons to form [tex]Be^{2+}[/tex] ion.

Option B: Aluminium is the 13th element of the periodic table having electronic configuration of [tex]1s^22s^22p^63s^23p^1[/tex]

This element will loose 3 electrons to form [tex]Al^{3+}[/tex] ion.

Option C: Calcium is the 20th element of the periodic table having electronic configuration of [tex]1s^22s^22p^63s^23p^64s^2[/tex]

This element will loose 2 electrons to form [tex]Ca^{2+}[/tex] ion.

Option D: Lithium is the 3rd element of the periodic table having electronic configuration of [tex]1s^22s^1[/tex]

This element will loose 1 electron to form [tex]Li^{+}[/tex] ion.

Hence, the metal that will form the given compound is lithium.

Answer is: from strongest to weakest attractions: ionic forces, covalent forces, hydrogen forces, Van der Waals forces.

Ionic bond is the electrostatic attraction between oppositely charged ions; ionic bond is very strong.

For example, sodium chloride (NaCl) has ionic bond between sodim cation and chlorine anion.

Covalent bond is bond between nonmetals. Hydrogen and oxygen are nonmetals.

For example, in water, atoms of hydrogen (H) and oxygen (O) are connected by polar covalent bonds.

Hydrogen bond is an electrostatic attraction between two polar groups that occurs when a hydrogen atom (H), covalently bound to a highly electronegative atom such as flourine (F), oxygen (O) and nitrogen (N) atoms.

For example, because of hydrogen bonds, water has higher melting and boiling temperatures than H₂S.

There are two kinds of Van der Waals forces: weak London dispersion forces and stronger dipole-dipole forces.

The process of formation of sugar or carbohydrate by plants is known as photosynthesis.

It occurs in presence of light so the term "photo"

Here the plant uses carbon dioxide and it reacts with water to given glucose

The general reaction will be

6CO2(g)  + 6H2O(g)  + sunlight ---> C6H12O6  + 6O2

Thus the carbon dioxide is being converted to glucose

Higher the rate of absorption of carbon dioxide by plant more the rate of formation of glucose or more the rate of photosynthesis by the plant

The formation of glucose from carbon dioxide is a metabolic pathway which is a cycle known as Calvin cycle. Here actually the carbon is fixed into useful carbohydrates and this pathway is light independent.

Hence

Carbon dioxide absorption is an appropriate indicator of photosynthesis because  the main part of photosynthesis if fixation of carbon dioxide into useful carbohydrates by Calvin cycle (occurs in chloroplast of plant cells)

Given:

K = 0.71 = Kp

The reaction of sulphur with oxygen is

                            S(s)   + O2(g)  ---> SO2(g)

initial Pressure                   6.90         0

Change                                -x            +x

Equilibrium                     6.90-x          x

Kp = pSO2 / pO2 = 0.71 = x / (6.90-x)

4.899 - 0.71x  = x

4.899 = 1.71x

x = 2.86 atm = pressure of SO2 formed

temperature = 950 C = 950 + 273.15 K = 1223.15 K

Volume = 50 L

Let us calculate moles of SO2 formed using ideal gas equation as

PV = nRT

R = gas constant = 0.0821 L atm / mol K

putting other values

n = PV / RT = 2.86 X 50 / 1223.15 X 0.0821 = 1.42 moles

Moles of Sulphur required = 1.42 moles

Mass of sulphur required or consumed = moles X atomic mass of sulphur

mass of S = 1.42 X 32 = 45.57 grams or 0.04557 Kg  of sulphur

D.!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!

Answer:

Explanation:

A galaxy cluster is a structure consisting in many galaxies bounded by gravitational forces maintaining their form, many clusters form superclusters galaxies. One of the notable clusters is Virgo cluster on the constellation of Virgo.

Energy Change= Mass X Specific Heat X Temperature Change

126 times .5 = 63.

63 times 10= 630

630 joules

Answer:

630 J

Explanation :

The formula for the heat required is

q = mCΔT

q = 0.5 × 126 × 10

q = 630 J

Answer:

See below.  

Step-by-step explanation:

Hydrogenation of an alkyne in the presence of a Lindlar catalyst produces a cis-alkene.

Thus,treatment of the acetylenic cyclopentenone with hydrogen and Lindlar catalyst gives 3-methyl-2-[(Z)-pent-2-enyl]cyclopent-2-en-1-one

(cis-jasmone).

Cis-jasmone's formation from an alkyne using H2 and the Lindlar catalyst results in a molecule with a double bond due to the catalyst's selective reduction, and the cis configuration indicating the two added hydrogen atoms are on the same side of the molecule. This structure can be drawn using a molecular drawing utility.

The structure of cis−jasmone can be determined based on its formation from an alkyne using H2 and the Lindlar catalyst. The Lindlar catalyst is a hydrogenation catalyst used to selectively hydrogenate alkynes to alkenes without further reduction to alkanes. Therefore, the operation converts a triple bond into a double bond.

Along with the cis-configuration specification, the product has the double bond on the same side.

However, you can easily draw it out using a molecular drawing utility. Start with the carbon backbone of the alkyne, and replace one of the triple bonds with a double bond. Make sure the cis configuration is represented, meaning the additional hydrogen atoms added to the carbon atoms are on the same side.

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Answer : The formula unit of Sr & Cl is [tex]SrCl_2[/tex] and the formula unit of Al & S is [tex]Al_2S_3[/tex]

Explanation :

Formula unit : it is defined as the lowest number ratio of ions of an elements in an ionic compound or covalent compound.

For the formula unit of Sr & Cl, two chloride ions[tex](Cl^-)[/tex] are needed to neutralize the one strontium ion[tex](Sr^{2+})[/tex].

For the formula unit of Al & S, three sulfide ions[tex](S^{2-})[/tex] are needed to neutralize the two aluminium ion[tex](Al^{3+})[/tex].

The formula unit of [tex]SrCl_2[/tex] and [tex]Al_2S_3[/tex] are shown below.

Answer:

The reaction force accelerates the bat in a direction opposite that of the ball.

Explanation:

your welcome! (; (:

Answer:

2 mol Fe₂O₃/ 4 mol Fe  

Step-by-step explanation:

The balanced equation is

2Fe₂O₃ + 3C → 4Fe + 3CO₂

The molar ratio uses the coefficients of the formulas in the balanced equation.

Those in front of Fe₂O₃  and Fe are 2 and 4, respectively.

B is wrong. the correct ratio is 3 mol C/4 mol Fe.

C is wrong. The correct ratio is 2 mol Fe₂O₃/3 mol C.

D is wrong. The correct ratio is 3 mol C/3 mol CO₂.

The answer is A. The melting and freezing points of a substance are the same. The only difference between melting and freezing is the order in which they occur. Melting starts with a solid and changes into a liquid. Freezing starts with a liquid and changes into a solid. Think of water. At 0 degrees celsius and if the temperature was decreasing before, it would freeze. At 0 degrees celsius and the temperature was increasing before, it would melt. Look at a heating/cooling curve, the straight lines are the transition points. On a heating curve, the first straight line is for melting. On a cooling curve, the last straight line is for freezing. They both occur at the same temperature.

Hope this helped!

The melting and freezing points of a substance are the same (A), which is shown by water's equilibrium at 0°C, where ice melts and liquid water freezes at the same temperature. The heat of fusion and heat of vaporization are unique and differ for each substance. Option A is correct .

The correct statement regarding the phase transitions of a substance is option  A. The melting and freezing points of a substance are the same. This fact can be exemplified with water (H₂O), which has the same melting point and freezing point at 0°C. This temperature represents the equilibrium in which solid water is in equilibrium with its liquid state, as represented by the following equilibrium equation:

H₂O (s) ⇔ H₂O (l)

At this temperature, adding heat will cause the solid to melt and become liquid, while removing heat will result in the liquid freezing and becoming solid. In contrast, the boiling point of water is 100°C, which is where liquid water comes into equilibrium with water vapor, its gaseous state.

Moreover, the heat of fusion and heat of vaporization are unique to each substance and refer to the amount of energy needed to change a substance from solid to liquid and liquid to gas, respectively. These values are not typically the same for a given substance.

We have to know which two substances are related correctly.

The correct answer is: (C) H₃O⁺ is the conjugate acid of H₂O.

In an acid-base reaction, an acid reacts with a base and gives a conjugate base and conjugate acid. The reaction is shown below:

Acid₁ + Base₂ ⇄ Conjugate Base₁ + Conjugate Acid₂

In the reaction H₂CO₃ + H₂O ⇌ H₃O⁺ + HCO₃⁻, H₂CO₃  is an acid because it releases H⁺ ion and converts to HCO₃⁻. Here HCO₃⁻ is the conjugate base of H₂CO₃ ( according Arrhenius theory).

H₂O accepts H⁺ ion and is converted to H₃O⁺ , thus H₂O behaves as Bronsted base. So, H₃O⁺ is the conjugate acid of Bronsted base H₂O.

Hence, the correct answer is: (C) H₃O⁺ is the conjugate acid of H₂O.

Answer:

The correct answer is C.) H30+ is the conjugate acid of H20

Explanation:

The statements of Dalton atomic theory are

All elements are composed of tiny indivisible particles called atoms.

Atoms of the same element are identical. The atoms of any one element are different from those of any other element

Atoms of different elements can physically mix together or can chemically combine to form compounds

Chemical reactions occur when atoms are separated from each other, joined, or rearranged in a different combination.

where P is the pressure (atm),

V is the volume (L),

n is the number of moles,

R is the general gas constant (8.314 L.atm/mol.K),

T is the temperature in Kelvin

P1 = 3.20 atm, T1 = 300 K, T2 = 290 K, P2 = ??

(3.20 atm)(290 K) = P2(300 K)

P2 = (3.20 atm)(290 K)/ (300 K) = 3.093 atm

Answer: 3.093 atm

I got it right on my quiz

Explanation:

V is the volume (L),

n is the number of moles,

R is the general gas constant (8.314 L.atm/mol.K),

T is the temperature in Kelvin

at constant volume of the gas: P1T2 = P2T1

P1 = 3.20 atm, T1 = 300 K, T2 = 290 K, P2 = ??

(3.20 atm)(290 K) = P2(300 K)

P2 = (3.20 atm)(290 K)/ (300 K) = 3.093 atm

Answer: A) Nonmetal carbon shares valence electrons with each nonmetal chlorine forming four covalent bonds.

Explanation: Covalent bond is formed by sharing of electrons between atoms.

Ionic bond is formed by transfer of electrons between atoms.

Carbon with atomic no 6 and has configuration of [tex]1s^22s^22p^2[/tex]. Carbon has 4 valence electrons. It can only share electrons as it is difficult to gain or lose 4 electrons to complete it's octet.

Chlorine with atomic no 17 has configuration of [tex]1s^22s^22p^3s^23p^5[/tex]. It has 7 valence electrons and need one electron to complete its octet.

Thus carbon will share 4 electrons, one each with four chlorine atoms to form carbon tetra chloride.

Answer:

A

Explanation:

Answer: C) Both are made up of monomers that are linked by covalent bonds

Explanation: Polymers are large molecules which are formed by combination of small repeating units called as monomers.

Natural polymers are found in nature such as cellulose whereas synthetic polymers are synthesized in laboratories such as Nylon 6,6.

All the polymers, whether natural or synthetic are made up of monomers and are joined by covalent bonds.

Both natural and synthetic polymers consist of monomers that are linked together by covalent bonds, with natural polymers having a wider variety of monomers like amino acids, and synthetic polymers often containing fewer types of monomers. Option C is correct .

Natural polymers and synthetic polymers are similar in that they are both made up of monomers linked together by covalent bonds. Examples of natural polymers include proteins and DNA, which are fundamental to biological structure and function. Synthetic polymers, on the other hand, include plastics like polystyrene. Option C is correct .

The monomers in natural polymers can vary greatly; there are 20 different amino acids that can combine in a multitude of sequences to form different proteins. Synthetic polymers typically feature fewer types of monomers, but the process of polymerization, which results in the formation of large molecules through the joining of these monomers, is a common characteristic shared by both natural and synthetic polymers.

Proteins are significant examples of natural polymers, functioning as enzymes that catalyze biological reactions. While synthetic polymers do not serve in biological catalysis, their repeating monomer units confer them with unique physical properties making them valuable in a variety of applications.

 The volume in liters  occupied  by 22.6 g  of I₂  gas  at STP  is  1.99 L (answer A)

 calculation

Step: find the  moles of I₂

moles= mass÷  molar mass

from  periodic table the  molar mass  of I₂  is  253.8 g/mol

moles = 22.6 g÷253.8 g/mol =0.089 moles

Step 2:find the volume  of I₂  at STP

At STP  1  moles =22.4 L

         0.089 moles= ? L

by cross  multiplication

={ (0.089 moles x 22.4 L) /1 mole} = 1.99 L

Answer: gas and then solid.

Explanation: Just trust me ok.

I would say C. Since the material is getting warmer, the atoms and molecules will start to move fasten and then also create more "messiness" (which is entropy with a less-nice word)

Answer:

C. Thawing - APEX

Explanation:

Answer : The incorrect option is, (d) The reactant that was the smallest given mass is the limiting reagent.

Explanation :

Limiting reagent : It is the reagent that is completely consumed in the chemical reaction when the chemical reaction is complete. No amount is left after the reaction is complete. The amount of product obtained is determined by the limiting reagent. A balanced equation is necessary to determine which reactant is limiting reagent.

Excess reagent : It is the reagent that are not completely consumed in the chemical reaction. That means the reagent is in excess amount. Some amount of the excess reagent is left over after the reaction is complete.

From this we conclude that the options, A, B and C are correct. While the option D is incorrect.

Option D is incorrect because it is not necessary the reactant that was the smallest given mass is the limiting reagent but it is judge by the number of moles present in the reaction.

Hence, the incorrect option is, (d)

Answer: d. the reactant that was the smallest given mass is the limiting reagent.

You may not be able to see the sugar you've stirred into your tea, coffee or hot chocolate, but it's still there. Rather than disappearing completely, it dissolves. When a solute is dissolved in another substance, a solution is created. So when you prepare your hot beverage, the sugar is the solute, the water is the substance and the finished product is the solution. Working out how to dissolve sugar faster involves some interesting experiments that you can easily carry out at home with sugar cubes and cups of water.

Agitation, temperature, and surface area of the dissolving particles determine how fast the substance will dissolve.

to increase the rate of sugar dissolving in a cup of tea:

Agitation - by stirring w a spoon, the sugar solid will be agitated n dissolve faster in tea.

temperature - by heating the tea, the sugar will dissolve faster in tea.

surface area of dissolving particles - by using granular sugar instead of sugar cube, the contact surface area w tea is increased. granular sugar will dissolve faster in tea.

Answer is: C alkane.

Name of this molecule is n-hexane.

Hexane is alkane (acyclic saturated hydrocarbon, carbon-carbon bonds are single) of six carbon atoms.

Carbon atoms in hexane have sp3 hybridization.

In sp3 hybridization hybridize one s-orbital and three p-orbitals of carbon atom.

Alkene has one double bond and alkyne has one triple bond.

Answer:

cthx guy from 2 yrs ago

Explanation:

The answer is: (D) 2-Propanol experiences stronger hydrogen bonding than acetone.

2- propanol has greater boiling point, because hydrogen bonds between 2-propanol molecules, more energy is required to breake those bonds.

Hydrogen bond is an electrostatic attraction between two polar groups that occurs when a hydrogen atom (H), covalently bound to a highly electronegative atom such as flourine (F), oxygen (O) and nitrogen (N) atoms.

In molecule of 2-propanol there are hydrogen forces between negatively charged oxygen from one molecule of 2-propanol and positively charger hydrogen of another molecule of 2-propanol.

2-propanol is alcohol and acetone is ketone, both are organic compounds.

For neutral atoms, the number of valence electrons is equal to the atom's main group number. The main group number for an element can be found from its column on the periodic table. For example, carbon is in group 4 and has 4 valence electrons. Oxygen is in group 6 and has 6 valence electrons.

The number of valence electrons an atom has can usually be determined by its group number in the periodic table. However, for ions, adjustments have to be made for the lost or gained electrons. Exceptions exist such as transition metals and hydrogen.

You can determine the number of valence electrons an atom has by considering its position in the periodic table. For main group elements, the group number (excluding any Roman numerals or A/B designations in some versions of the table) often indicates the number of valence electrons. For example, Sodium (Na), located in Group 1, has 1 valence electron, and Oxygen (O), located in Group 6, has 6 valence electrons.

However, for ions, you need to consider if an atom has lost or gained electrons. For a positive ion (cation), such as NO*, subtract the number of positive charges (equal to the number of lost electrons) from the number of valence electrons. For a negative ion (anion), such as CHO₂, add the number of negative charges (equal to the number of gained electrons) to the initial number of valence electrons.

Further, do note that there are exceptions. For instance, transition metals do not strictly follow these general rules due to their unique electron configurations. Additionally, hydrogen, though located in Group 1, is not a metal and only needs 2 electrons to fill its shell, again an exception to the octet rule.

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Answer:

2.0 mol of oxygen are consumed.

Step-by-step explanation:

You know that you will need a balanced equation with masses, moles, and molar masses, so gather all the information in one place.

M_r:   28.0                 44.0

          CO  + ½O₂ ⟶ CO₂ + 67.6 kcal

m/g:   112

Step 1. Convert grams of CO to moles of CO

1 mol CO = 28.0 g CO

Moles of CO = 112 × 1/28.0

Step 2. Convert moles of CO to moles of CO₂.

The molar ratio is 1 mol CO₂ to 1 mol CO

Moles of CO₂ = 4.000 × 1/1

Moles of CO₂ = 4.00 mol CO₂

Option A is wrong.

Step 3. Calculate the amount of heat generated.

q = ΔH

The conversion factor is 67.6 kcal/1 mol CO₂

q = 4.00 × 67.6

q = 270 kJ

Option B is wrong, because it gives the heat generated by 1 mol of CO.

Step 4. Calculate the moles of O₂ consumed

Moles of O₂ = 2.00 mol O₂

Option C is correct.

Step 5. Calculate the moles of CO₂ formed

Already done in Step 2.

Moles of CO₂ = 4.00 mol CO₂

Option D is wrong.

Step 6. Calculate the moles of O₂ produced

Already done in Step 4.

Moles of O₂ = 2.00 mol O₂

Option E is wrong.

The modern atomic model is sometimes called the electron cloud , or quantum mechanics model.

So the answer is electron cloud

The answer to this question should be electron cloud.