The standard gibbs free energy of formation of ___ is zero: 1. h2o(l) 2. na(s) 3. h2 (g)

An ideal index fossil species should be easily recognizable, abundant, have a brief geologic lifespan, and a wide geographic distribution, assisting in the dating of rock layers.

The characteristics of an ideal index fossil species are that the organism should be easily recognizable, abundant, have existed for a relatively short period of time (geologically speaking), and possess a wide geographic distribution. These criteria make the fossil useful for dating and correlating the age of rock layers. For example, Belemnites, a type of extinct squid, are considered good index fossils of the Mesozoic era because they meet all of these criteria. When these fossils are found in a rock layer, they signal that the rock is from the Mesozoic period, specifically between 252 and 66 million years ago.

Answer: The number placed in front of a compound to balance a chemical reaction is called coefficient.

Explanation:

Assume this general form for a chemical equation:

The letters a, b, c, and d, in front of each compound A, B, C, and D, are called coefficients and indicate the number of formula units (molecules or ions) that take part in the equation.

Those coefficients are needed to balance the equation and ensure compliance with the law of mass conservation.

This example shows it:

        H₂ (g) + 2O₂(g) → 2H₂O(g)

In that equation:

You read it as: 1 mole of gaseous hydrogen and 2 moles of gaseous oxygen yield 2 moles of water vapor.

A o degrees Celsiusfycgvhbjhuygftxetrfyguhijuhygutfytftg

If i am correct the answer should be C because less than the amount would mean the ice has to melt from its ice form back to the original water liquid form.

Potassium permanganate will decompose into potassium manganate, manganese dioxide and oxygen gas: 2KMnO4 → K2MnO4 + MnO2 + O. When Potassium permanganate is heated it turns to Potassium manganate, manganese dioxide and oxygen gas

When potassium permanganate is decomposed, oxygen gas is released.

Potassium permanganate can be thermally decomposed according to the following equation:

[tex]2KMnO_4 --->K_2MnO_4+MnO_2+O_2[/tex]

The products formed are potassium manganate (K2MnO4), Manganese dioxide (MnO2), and oxygen (O2). Out of all the products, the only one that is gas is O2.

If the reaction is carried out in an open chamber, the oxygen gas would be released.

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Answer:

The number of large fish will increase.

Explanation:

If in a particular lake, thousands of small fishes are added, then the number of the larger fishes will increase. The reason for this is because in general the larger fishes are feeding on the smaller fishes, thus with the introduction of the thousands of small fishes there will be an increase in their food source. Also, the smaller fishes have much quicker reproduction, so the chances are that they will reproduce quickly enough so that they increase in numbers, thus providing constant food source that will enable the support of larger populations of the larger fishes.

Great change occur in big fish population with the introduction of thousands of small fish.

If someone adds thousands of small fish to a lake the number of big fish increases if their food is these small fishes because more food is available for it which results in the increase of population of big fish.

While on the other hand, if the small fishes feed on the same food on which the big fish feed than there is competition which negatively affected the big fish and decrease in population due to unavailability of food so we can conclude that big change occur in big fish population with the introduction of thousands of small fish.

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Well that big peak in the graph there is called the transition state. The reaction needs to get past this energy hurdle to continue. The difference between these two graphs is that II has a lower energy transition state. Catalysts are known to lower transition states so that's my vote, a catalyst was added.

Answer: A catalyst was added.

Explanation:

Activation energy is the extra energy that must be supplied to reactants in order to cross the energy barrier and thus convert to products.

When a catalyst is added top a reaction, it increases the rate of a reaction by taking the reaction through a different path which involves lower activation energy and thus more molecules can cross the energy barrier and convert to products.

The concentration of reactants and products remain same even after addition of catalyst.

B represents activation energy for uncatalyzed reaction and E represents activation energy for catalyzed reaction.

Answer:

e. 3.08 x 10⁻² mol of ions.

Explanation:

1.0 mol NiCl₂ contains → 6.022 x 10²³ molecules.

??? mol NiCl₂ contains → 6.188 x 10²¹ molecules.

∴ The no. of moles of NiCl₂ = (1.0 mol)(6.188 x 10²¹ molecules)/(6.022 x 10²³ molecules) = 1.028 x 10⁻² mol.

NiCl₂ → Ni²⁺ + 2Cl⁻.

Which means that every 1.0 mol of NiCl₂ is ionized to produce 3.0 moles (1.0 mol of Ni²⁺ and 2 moles of Cl⁻).

∴ The total moles of ions are released = 3 x 1.028 x 10⁻² mol = 3.083 x 10⁻² mol of ions.

Approximately 0.0309 moles of ions are released when 6.188 x 10^21 formula units of NiCl2 dissolve in water. Hence, the answer would be (e) 3.08 x 10^-2 mol of ions.

To calculate the total moles of ions released when 6.188 x 1021 formula units of NiCl2 dissolves in water, we first need to convert the formula units to moles using Avogadro's number (6.022 x 1023 formula units/mole). The number of moles of NiCl2 is therefore around 0.0103 moles.

However, each unit of NiCl2 releases 3 ions (1 Ni2+ and 2 Cl-) when it dissolves. Consequently, the total moles of ions released into the water is approximately 0.0309 moles (0.0103 moles*3 ions/mole). So, the closest answer would be (e) 3.08 x 10-2 mol of ions.

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Answer:

Explanation:

5.11= 9.3001x

x=0.5494

2 mol HI produced. Thus,

(2)(0.5494)=1.0989 = 1.09 = [HI] present at equilibrium.

Answer: eight (8), for most atoms.

Explanation:

Atoms gain chemical stability by completing the highest energy level with all the electrons it can have, which is 8 for most atoms.

The elements of the first period (row 1), hydrogen and helium, have outer energy level, n, equal to 1.

So, since n = 1, the atoms of hydrogen and helium (in the ground state) fill the 1s orbital, so they need just two electrons to be chemically stable. That is why helium, having 2 electrons, is a noble gas, and hydrogen, having 1 electron, just needs to add 1 more electron to be chemically stable like helium.

For period 2 through 7 of the periodic table (n = 2, n=3, n =4, n =5, n = 6, and n = 7), the outer energy levels can hold 8 electrons. That is why the noble gases Ne, Ar, Kr, Xe, Rn, and Og, each with 8 electrons in the outer energy level are chemically stable.

Here you have two examples to see how this works:

I think it’s D. I’m not really shore....

the answer is A 0=0

Answer:

C) CsF, HF

Explanation:

A solution containing CsF and HF pairs of substances will be a buffer solution.

Buffer solutions are formed by the mixture of weak acid and its conjugate base or by weak base and its conjugate acid, and helps to retain the pH of the solution if any strong acid or base is added in small quantity.

Among the given pairs all pairs will form buffer solution except CsF and HF, because HF is a weak base and F⁻ is conjugate base of HF acid.

Hence, option (c) is correct i.e. CsF and HF.

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Answer: A.) always near the same molecules

Explanation:

The capillary action of water is the movement of water from roots to the leaves and other plant parts against the gravitational force of earth. This conduction of water is facilitated by the two properties of water that are cohesion and adhesion.

Cohesion can be define as the attraction of the molecule of water towards another water molecule. Adhesion can be define as the attraction of the molecules of water towards the different type of molecule.  

Among the given options A is the correct option because of the fact that the attraction of water molecules among themselves gives water a definite volume in the glass. Cohesive forces keeps the water molecules close together.      

As a water molecule in a glass of water, you are constantly running into different molecules due to the higher kinetic energy in the liquid state which allows free movement, with transient hydrogen bonding creating temporary clusters.

In a liquid state, such as being a water molecule in a glass of water, you would experience a dynamic and ever-changing environment. If we imagine ourselves as a water molecule, we would be in constant motion, with hydrogen bonds forming and breaking as we interact with our neighboring molecules. Unlike in a solid where molecules are in a fixed position and only vibrate, in a liquid state, the molecules have more energy allowing them to move around freely, although they are still close to each other. This movement leads to different clusters or ''clumps'' of molecules circulating within the confines of the container.

The correct answer to the given question is C.) constantly running into different molecules. Water molecules in a liquid phase such as in a glass of water are not held in a rigid pattern, nor are they always near the same molecules because their increased kinetic energy allows them to move and trade places with one another. This movement is random yet constrained by the surface of the liquid. The hydrogen bonding that occurs is transient - while it does create some structure, it is not rigid or permanent.

Answer:

11. 227 kJ·mol⁻¹; 12. 587 kJ

Step-by-step explanation:

11. Calculate ΔH°f

The formula for calculating the enthalpy change of a reaction by using the enthalpies of formation of reactants and products is

ΔH°r = ΣmΔH°f(products) - ΣnΔH°f(reactants)

                        2C₂H₂ + 5O₂ ⟶ 4CO₂ + 2H₂O; ΔH°c = -1299 kJ·mol⁻¹

ΔH°f/kJ·mol⁻¹:      2x         0          -393     -286

2(-1299) = 4(-393) + 2(-286) - 2x

  -2598 = -1572 - 572 - 2x

  -2598 = -2144 -2x

    -454 = -2x

         x = 227 kJ·mol⁻¹

ΔH°f for acetylene is 227 kJ·mol⁻¹

12. Hess's Law

Warning: It is almost impossible to solve a problem like this by trial and error. You must have a strategy beforehand.

We have five equations:

(I)     Ca + 2C ⟶ CaC₂;                    ΔH =    -62.8   kJ

(II)   Ca + ½O₂ ⟶ CaO;                   ΔH =   -635.5  kJ

(III) CaO + H₂O ⟶ Ca(OH)₂;           ΔH =   -653.1   kJ

(IV) C₂H₂ + ⁵/₂O₂ ⟶ 2CO₂ + H₂O;  ΔH = -1300     kJ

(V)  C + O₂ ⟶ CO₂;                         ΔH =   -393.51 kJ

From these, we must devise the target equation:  

(VI) CaC₂ + 2H₂O → Ca(OH)₂ + C₂H₂;  ΔH = ?  

Here comes the strategy. Remember, you can use each of the given equations only once.  

Start with the target equation. It has CaC₂ on the left, so you need an equation containing CaC₂ on the left.  

Reverse Equation (I). When you reverse an equation, you change the sign of its ΔH.

(VII) CaC₂ ⟶ Ca + 2C; ΔH = 62.8   kJ

Equation (VII) has Ca on the right, and that is not in the target. You need an equation with Ca on the left to cancel it. Add Equation (II)

(VIII) Ca + O₂ ⟶ CaO; ΔH = -1271.0 kJ

Equation (VII) also has 2C on the right, and there is no C in the target. We need an equation with 2C on the left to cancel it.

Double Equation (V). When you double an equation, you double its ΔH.

(IX) 2C + 2O₂ ⟶ 2CO₂; ΔH = -587.02 kJ

Now, we must eliminate the CaO from Equation (VII). Add Equation (III).

(X) CaO + H₂O ⟶ Ca(OH)₂; ΔH = -653.1 kJ

Equation (VIII) has 2CO₂ on the right. You need an equation with 2CO₂ on the left.

Reverse Equation (IV).

(XI) 2CO₂ +H₂O ⟶ C₂H₂ + ⁵/₂O₂ ; ΔH = 2600  kJ

Now, we add all five equations,  cancelling substances that appear on both sides of the reaction arrow. All the formulas in italics have been cancelled

(VII)  CaC₂ ⟶ Ca + 2C;                           ΔH =   62.8   kJ

(VIII) Ca + ½O₂ ⟶ CaO;                         ΔH = -635.5   kJ

(IX)   2C + 2O₂ ⟶ 2CO₂;                        ΔH = -787.02 kJ

(X)    CaO + H₂O ⟶ Ca(OH)₂;                ΔH = -653.1    kJ

(XI)   2CO₂ + H₂O ⟶ C₂H₂ + ⁵/₂O₂     ; ΔH = 2600     kJ

(VI)   CaC₂ + 2H₂O → Ca(OH)₂ + C₂H₂;  ΔH =    587     kJ

ΔH = 587 kJ

The answer would actually be, because Earth is formed from cold gases collapsing due to gravity. The Solar System was formed when a huge amount of dust and gas began to collapse under its own gravity, and as the cloud collapse it started to spin causing the material within the cloud to gather into a swirl and then formed into planets and as the planets are formed they kept this spinning motion.

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Answer:

The reactions that have a positive ΔSrxn are the second and the fourth:

Explanation:

ΔSrxn stands for the change in entropy of a reaction.

Since ΔSrxn equals Final entropy - Initial entropy, a positive ΔSrxn (ΔSrxn > 0) means that the entropy increases.

Given the chemical equations for some reactions, you can identify the direction of the change of entropy (increase or decrease) by inspection, using basic definitions and principles.

These are:

With those principles, you get the following results for each of the given systems.

1) 2A(g) + B(g) → C(g)

  Since in the product (right) side there are fewer molecules than in the reactant (left) side, you predict that the entropy decreases, and so the ΔSrxn is negative.

2) A(g) + B(g) → 3C(g)

    Since in the product (right) side there are more molecules than in the reactant (left) side, you predict that the entropy increases, and so the ΔSrxn is positive.

3) 2A(g) + 3B(g) → 4C(g)

    Since in the product (right) side there are fewer molecules than in the reactant (left) side, you predict that the entropy decreases, and so the ΔSrxn is negative.

4) 2A(g) + B(s) → 3C(g)

    Since there are the same number of molecules in both sides, the determining factor of the change of entropy is the physical state of the components.

Since the reactant B (s) is in solid state and the only product is C(g), and it is in gas state, you predict that the entropy increases, and ΔSrxn is positive.

Conclusion: the reactions that have a positive ΔSrxn are the second and the fourth:

Answer: C.   Forming the activated complex requires energy.

Explanation:

Activation energy is the extra energy that must be supplied to reactants in order to cross the energy barrier and thus convert to products.

In order that reactants change into products, they have to cross an energy barrier. When reactant molecules absorb energy, their bonds are loosened and new loose bonds are formed between them.

The intermediate thus formed is called as activation complex. It is unstable and immediately dissociates to form stable products by release of energy.

The moles of acid (HCOOH) and base (NaOH) were calculated based on their respective volumes and concentrations. The moles of excess acid, along with the total volume, were used to determine the concentration of excess acid. Using this concentration, the pH during the titration was found to be 3.336.

Calculate the moles of acid and base:

Moles of HCOOH = (Volume) * (Concentration) = (30.0 mL) * (0.1000 M)

Moles of NaOH = (29.3 mL) * (0.1000 M)

Calculate the moles of excess acid:

Moles of excess HCOOH = (Moles of HCOOH) - (Moles of NaOH)

Calculate the concentration of excess acid:

Concentration of excess HCOOH = (Moles of excess HCOOH) / (Total volume)

Total volume = 30.0 mL + 29.3 mL

Use the concentration of excess acid to find [H+]:

[H+] = sqrt(Ka * Concentration of excess HCOOH)

The formula [H+] = sqrt(Ka * C) comes from the equilibrium expression for a weak acid, where C is the concentration of the acid.

Calculate pH:

pH = -log[H+]

Now, let's substitute the values:

Moles of HCOOH = (30.0 mL) * (0.1000 M) = 0.003 moles

Moles of NaOH = (29.3 mL) * (0.1000 M) = 0.00293 moles

Moles of excess HCOOH = 0.003 moles - 0.00293 moles = 6.72 x 10^-5 moles

Total volume = 30.0 mL + 29.3 mL = 59.3 mL = 0.0593 L

Concentration of excess HCOOH = (6.72 x 10^-5 moles) / (0.0593 L) = 1.13 x 10^-3 M

[H+] = sqrt((1.8 x 10^-4) * (1.13 x 10^-3 M)) = 4.61 x 10^-4 M

pH = -log(4.61 x 10^-4) = 3.336

Therefore, the pH during the titration is 3.336.

The answer is D. forty calories

Answer:

it depends on how high up u dropped the ball if the ball was only taking 15 seconds to hit the ground then the ball couldn't go any faster cause its done landed but if the ball was falling 20 mph then there is a chance that it would go 25mph landing compared to when it first fell

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a) IF = polar

b) CS2 = non-polar

c) SO3 = non-polar

d) PCl3 = polar

e) SF6 = non-polar (bonds are polar, but the molecule is non-polar, since the                                                                                                                                    net dipole moment is zero)

f) IF5 = polar

The classification of the given molecules as polar or non-polar are;

a) IF; Polar

a) IF; Polarb) CS2; Non - polar

a) IF; Polarb) CS2; Non - polar c) SO3; Non - polar

a) IF; Polarb) CS2; Non - polar c) SO3; Non - polar d) PCl3; Polar

a) IF; Polarb) CS2; Non - polar c) SO3; Non - polar d) PCl3; Polare) SF6; Non - polar

a) IF; Polarb) CS2; Non - polar c) SO3; Non - polar d) PCl3; Polare) SF6; Non - polar f) IF5; Polar

To answer this question, we need to first understand polar and non - polar molecules.

When we say that a molecule is polar, it means that the arrangement of the atoms is in such a manner that makes one end of the molecule to have a positive electrical charge with the other end having a negative charge. This means that polar molecules are formed from polar covalent bonding when two atoms do not share electrons equally .

When we sat that a molecule is non-polar, what it means is that it does not have electrical poles. This means that it's electrons are shared equally unlike that of polar molecules.

In contrast to polar molecules, non-polar molecules do not have an abundance of charges at the opposite ends. Examples are found in hydrocarbon liquids.

From the Explanations above, we can categorize the given molecules into polar or non polar as;

a) IF; Polar

b) CS2; Non - polar

c) SO3; Non - polar

d) PCl3; Polar

e) SF6; Non - polar

f) IF5; Polar

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Answer: The contour interval is inconsistent.

Explanation: I just too the test and this is the correct answer.

Answer:

c

Explanation:

It'll take one year for the Earth to complete one revolution around the Sun.

How long does it take for the Earth to revolve around the Sun?

Your answer is (A. One Year) or 365.25 days.

Hope this helps! :D

Answer:

P₁V₁ = P₂V₂.

Explanation:

So, for two different values of both P and V:

∴ P₁V₁ = P₂V₂.

by photosynthesis make it enzymes

Answer:

Transition state, decreases, substrates & gets decreased.

Explanation:

Most of the chemical reactions are slow because of the transition state barriers. It requires a lot of energy to cross the transition state barriers. So enzymes provide an alternate pathway for carrying out the reaction by stabilizing the transition state. When enzymes interact with the substrates with the help of functional groups present in their active sites it results in the lowering of activation energy because the transition state gets stabilized with the help of enzyme.

Answer:

d) Metallic character decreases as you go to the right across a row in the periodic table and increases as you go down a column.

Explanation:

The formula unit for the compound formed when each pairs of ions interact are as mentioned below-

Li⁺ and 0²⁻ forms Li2O

Mg²⁺ and S²⁻ forms Mg S

A1³⁺ and CI⁻ forms AlCl3Na⁺ and

N³⁻ forms Na3N

The formula unit is the smallest unit of an ionic substance that tells us  of the ratio in which ions are combined in the ionic compound.

The formula unit for the compounds formed depends on the valency of the combining ions.

Usually, the formula unit is written on the valency of the ions.

The formula unit for the compound formed when each pairs of ions interact are therefore as written-

Li⁺ 0²⁻ forms Li2O

Mg²⁺S²⁻ forms Mg S

A1⁺³  CI⁻ forms AlCl3 and

Na+ N³⁻ forms Na3N.

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The answer would be C, because it is the follower up of oxygen.