why there is not reaction in nac2h3o2(aq)+pb(no3)2(aq)→?

   The volume  at standard  pressure  is 162.5 L

  calculation

The  volume  at Standard pressure (760  mm hg)  is calculated using the Boyle's  law formula

That is P₁V₁ =P₂V₂

where;

P₁=650 mmHg

V₁= 190 L

P₂ = 760 mm hg

V₂ =? L

make   V₂   the formula of the subject  by diving  both side of equation by P₂

V₂  is therefore = P₁V₁/P₂

= {(650 mmHg x 190 L) / 760 mmHg} =162.5 L

Answer : The volume of the gas at standard pressure (1 atm) is, 162.45 L

Solution : Given,

Initial pressure of gas = 650 mmHg = [tex]\frac{650}{760}=0.855atm[/tex]    [tex](1atm=760mmHg)[/tex]

Initial volume of gas = 190 L

Final pressure of gas = 1 atm     (standard pressure is 1 atm)

Formula used : [tex]\frac{P_1}{P_2}=\frac{V_2}{V_1}[/tex]

where,

[tex]P_1[/tex] = initial pressure of gas

[tex]P_2[/tex] = final pressure of gas

[tex]V_1[/tex] = initial volume of gas

[tex]V_2[/tex] = final volume of gas

Now put all the given values in the above formula, we get

[tex]\frac{0.855atm}{1atm}=\frac{V_2}{190L}[/tex]

By rearranging the terms, we get the final volume of the gas.

[tex]V_2=162.45L[/tex]

Therefore, the volume of the gas at standard pressure (1 atm) is, 162.45 L

Answer:  D) The lead (II) nitrate is the reaction's limiting reactant.

Explanation:

[tex]\text{no of moles of iron(III) chloride}={\text{Molarity}\times {\text{Volume in L}}[/tex]

[tex]\text{no of moles of iron(III) chloride}={0.100M}\times {0.05L}=5\times 10^{-3}[/tex]

[tex]\text{no of moles of lead nitrate}={\text{Molarity}\times {\text{Volume in L}}[/tex]

[tex]\text{no of moles of lead nitrate}={\text{0.100M}\times {0.05L}=5\times 10^{-3}[/tex]

[tex]2FeCl_3+3Pb(NO_3)_2\rightarrow 2Fe(NO_3)_3+3PbCl_2[/tex]

As can be seen from the balanced chemical equation,  3 moles of lead nitrate react with 2 moles of ferric chloride.

Thus [tex]5\times 10^{-3}[/tex] moles of lead nitrate react with [tex]=\frac{2}{3}\times {5\times 10^{-3}}={3.33\times 10^{-3}}[/tex] of ferric chloride.

[tex]5\times 10^{-3}-{3.33\times 10^{-3}}=1.67\times 10^{-3}[/tex]moles of ferric chloride will be left unreacted.

Limiting reagent is the reagent which limits the formation of product. Excess reagent is one which is in excess and thus remains unreacted.

Thus lead nitrate is the limiting reagent and ferric chloride is the excess reagent.

The correct answer is the bicarbonate buffer system.  

The bicarbonate buffer system refers to an acid-base homeostatic mechanism taking part in the balance of bicarbonate ion, carbonic acid, and carbon dioxide in order to sustain the pH in the duodenum and blood, among other tissues, to support the entire metabolic activities.  

The bicarbonate buffer system plays a vital role in the human body systems. In the duodenum and the stomach, the bicarbonate buffer system functions to both neutralize gastric acid and steady the intracellular pH of epithelial cells through the secretion of bicarbonate ion into the gastric mucosa.  

Answer:

Proteins

Explanation:

Building blocks of proteins are amino acids that are bonded by peptide bonds. The bonded amino acids form a long chain, which is essentially a protein.  Proteins are essential to the body as they control the structure, function, and regulation of the different cells, tissues and organs that make up different organisms. The arrangement of the amino acids are specific to a certain protein.

Answer:

The force will change as the net force applied will increase.

Explanation:

If you are pushing on a door really hard, trying to make it slide open and if your friend is also stand behind you and contributes to help you push towards the door, then the overall force will change as the net amount of force applied will increase.

This is an example of Newton's second law according to which you need more force to move an object with heavier mass.

F = ma

Therefore, the force applied by you and your friend will add and the net force applied will be increased.

Answer:

2.42 L  

Step-by-step explanation:

Since all other properties constant, we can use Boyle’s Law.

p₁V₁ = p₂V₂    Divide each side by p₁

  V₁ = V₂ × p₂/p₁

Data:

p₁ = 101.01 kPa; V₁ = ?

p₂ = 101.7   kPa; V₂ = 2.40 L

Calculations:

V₁ = 2.40 × 101.7/101.01

V₁ = 2.42 L

Answer: The correct answer is option B.

Explanation: Reactivity of elements is defined as the tendency to loose or gain electrons.

These reactions are a type of single displacement reactions. A single displacement reaction is a type of reaction in which an element displaces another element in a chemical reaction. These are studied with the help of reactivity series.

The element which lies above in the reactivity series can easily displace the element which lies below in the reactivity series.

Option A: This reaction will not yield a stable product because Zinc lies below Aluminium in the reactivity series.

[tex]AlBr_3+Zn\rightarrow \text{No reaction}[/tex]

Option B: This reaction will yield a stable product because Sodium lies above Calcium in the reactivity series.

[tex]CaBr_2+2Na\rightarrow 2NaBr+Ca[/tex]

Option C: This reaction will not yield a stable product because Hydrogen lies below Magnesium in the reactivity series.

[tex]MgBr_2+H_2\rightarrow \text{No reaction}[/tex]

Option D: This reaction will not yield a stable product because Calcium lies below Barium in the reactivity series.

[tex]BaBr_2+Ca\rightarrow \text{No reaction}[/tex]

Option E: This reaction will not yield a stable product because barium lies below Lithium in the reactivity series.

[tex]2LiBr+Ba\rightarrow \text{No reaction}[/tex]

a catalyst speed up the chemical reaction and will not appear as a part of product . plus it will decrease the amount of heat needed to do the reaction

Answer:

It speeds up the rate of a reaction.

Explanation:

A.P.E.X.

Answer: The number is 2.

Explanation: The molecular formula of water is [tex]H_2O[/tex]. It contains two atoms of hydrogen and one atom of oxygen.

Thus there is an odd number of oxygen atom. To make the atoms even , with the smallest number, we multiply the formula by 2. The number of oxygen atoms in 2[tex]H_2O[/tex] will be 2 , which is an even number.

The answer is C, because wind turbines are used to produce electricity, and it's also the most safest way--but they are  expensive.

Answer is:  Fluorine and chlorine, because they are both halogens.

Halogen elements are in group 17: fluorine (F), chlorine (Cl), bromine (Br) and iodine (I). They are very reactive and easily form many compounds.

In the gaseous state halogens form diatomic covalent molecules.

Halogen diatomic molecules (halogen means "salt producing") in the gaseous state in room temperature are fluorine (F₂) and chlorine (Cl₂).

Both molecules have single covalent bond and they are very reactive.

Halogens need to gain one electron to have electron cofiguration like next to it noble gas. For example, fluorine has 9 electrons and it gain easily one electron in chemical reaction to have electron configuration like noble gas neon (Ne) with 10 electrons.

Answer:

Fluorine and chlorine, because they are both halogens

Explanation:

Answer:

It will not dissolve. More crystals will separate from the solution.  

Step-by-step explanation:

If you add a crystal of ammonium nitrate to a supersaturated solution of the solute, it will not dissolve.  

Instead, it will act as a "seed" on which more ammonium nitrate crystals will form.

They will separate from the solution as long, colourless, needle-like crystals until the solution is no longer supersaturated.

Adding a crystal of ammonium nitrate to a supersaturated solution likely causes crystallization instead of further dissolving, as the solution already has more solute than equilibrium allows.

If a crystal of ammonium nitrate is added to a supersaturated ammonium nitrate solution, it is likely to initiate crystallization rather than dissolve because the solution already contains more dissolved solute than can be maintained at equilibrium. Supersaturated solutions are unstable, and the introduction of a seed crystal often precipitates rapid crystallization. Ammonium nitrate is known to dissolve in water endothermically, and while it will dissolve to reach a saturation point, once a solution is supersaturated, additional solid will not dissolve and will instead cause the excess solute to crystallize out of the solution.

Answer:

the only element above is potassium

the first question is block A

because there isn't a lot of room for the particles to move around

Rain.

I finished the Future Diary im so sad seeing Yuki and Yuno for the last time. Im listening to the saddest song in the OST called "Here with you" im literally crying D:

i think that the answer is d. millions of small rocky objects

Millions of small rocky objects called asteroids orbit the Sun in a belt between Mars and Jupiter.

D. millions of small rocky objects

Answer is:  the number of bromine molecules is 1.35·10²⁴.

n(Br₂) = 2.25 mol; amount of bromine molecules.

Na = 6.022·10²³ mol⁻¹; Avogadro constant.

N(Br₂) = n(Br₂) · Na.

N(Br₂) = 2.25 mol · 6.022·10²³ mol⁻¹.

N(Br₂) = 13.54 ·10²³.

N(Br₂) = 1.35·10²⁴; number of bromine molecules.

Final answer:

The number of bromine (Br2) molecules present in 2.25 mol is calculated by multiplying the moles of substance by Avogadro's number, yielding 1.355 × 10^24 molecules of Br2.

Explanation:

To calculate the number of bromine (Br2) molecules present in 2.25 mol, we need to utilize Avogadro's number, which is approximately 6.022 × 1023 molecules/mol. The number of molecules can be found by multiplying the moles of substance by Avogadro's number.

Here’s the calculation:

Multiply the number of moles of bromine by Avogadro’s number: 2.25 mol × 6.022 × 1023 molecules/mol = 1.355 × 1024 molecules of Br2.

Answers:  

p(NO) = 0; p(O₂) = 0.300 atm; p(NO₂) = 0.400 atm  

Step-by-step explanation:  

Step 1. Moles of NO  

pV = nRT  

n = (pV)/(RT)  

p = 0.500 atm  

R = 0.082 06 L·atm·K⁻¹mol⁻¹  

T = (22 + 273.15)  

T = 295.15 K  

n = (0.500 × 6.00)/(0.082 06 × 295.15)  

n = 3.00/24.22  

n = 0.1239 mol  

===============  

Step 2. Moles of O₂  

p = 2.50 atm  

V = 1.50 L  

n = (2.50 × 1.50)/24.22  

n = 3.75/24.22  

n = 0.1548 mol  

===============  

Step 3. Identify the limiting reactant  

             2NO  +   O₂  ⟶  2NO₂  

n/mol: 0.1239  0.1548  

Calculate the moles of NO₂ we can obtain from each reactant.    

From NO:  

The molar ratio of NO₂: NO is 2:2

Moles of NO₂ = 0.1239 × 2/2  

Moles of NO₂ = 0.1239 mol NO₂  

From O₂:  

The molar ratio of NO₂: O₂ is 2:1.  

Moles of NO₂ = 0.1548 × 2/1  

Moles of NO₂ = 0.3097 mol NO₂  

NO is the limiting reactant because it gives the smaller amount of NO₂.  

===============  

Step 4. Moles of each species after reaction  

               2NO  +       O₂  ⟶  2NO₂  

I/mol:     0.1239      0.1548         0  

C:/mol: -0.1239     -0.06193  +0.1239  

F/mol:        0          0.0929      0.1239  

===============  

Step 5. Partial pressure of NO  

p(NO) = 0  

===============  

Step 6. Partial pressure of O₂  

pV = nRT  

p = (nRT)/V  

V= 6.00 + 1.50  

V = 7.50 L  

p = (0.0929 × 24.22)/7.50  

p = 2.25/7.50  

p = 0.300 atm

===============  

Step 7. Partial pressure of O₂  

p = (0.1239 × 24.22)/7.50  

p = 3.00/7.50  

p = 0.400 atm  

p(NO) = 0; p(O₂) = 0.300 atm; p(NO₂) = 0.400 atm  

The partial pressure of NO is 0 atm, and [tex]\rm NO_2[/tex] is 0.400 atm at the end of the reaction.

The concentration of NO and [tex]\rm O_2[/tex] initially are;

By ideal gas equation:

PV =nRT

P = pressure

V = volume

n = moles

R = constant = 0.0816 L.atm/mol.K

T = temperature = 22 [tex]\rm ^\circ C[/tex] = 273 + 22 K = 295 K

Moles of NO = [tex]\rm \frac{PV}{RT}[/tex]

Moles of  NO = [tex]\rm \frac{0.5\;\times\;6}{0.0816\;\times\;295}[/tex]

Moles of NO = 0.1239 moles

Moles of [tex]\rm O_2[/tex] = [tex]\rm \frac{2.50\;\times\;1.50}{0.0816\;\times\;295}[/tex]

Moles of [tex]\rm O_2[/tex] = 0.1548 moles

The reaction will be:

[tex]\rm 2\;NO\;+\;O_2\;\rightarrow\;2\;NO_2[/tex]

2 moles of NO gives 2 moles of [tex]\rm NO_2[/tex]

So, 0.1239 moles of NO gives 0.1239 moles of [tex]\rm NO_2[/tex]

1 mole of [tex]\rm O_2[/tex] gives 2 moles of [tex]\rm NO_2[/tex]

0.1548 moles of [tex]\rm O_2[/tex] gives 0.3097 moles of [tex]\rm NO_2[/tex]

Since No produces smaller amount of [tex]\rm NO_2[/tex], it is the limiting factor.

Partial pressure of NO = 0 since it is completely used.

Partial pressure of [tex]\rm NO_2[/tex] = [tex]\rm \frac{nRT}{V}[/tex]

n = 0.1239 moles

Total volume = 6 + 1.50

V = 7.5 L

Partial pressure of [tex]\rm NO_2[/tex] = [tex]\rm \frac{0.0929\;\times\;0.0816\;295}{7.5}[/tex]

Partial pressure of [tex]\rm NO_2[/tex] = 0.400 atm

For more information, refer the link:

https://brainly.com/question/8408970?referrer=searchResults

According to the electronic configuration, there are seven valence electrons present in the given atom.

Electronic configuration is defined as the distribution of electrons which are present in an atom or molecule in atomic or molecular orbitals.It describes how each electron moves independently in an orbital.

Knowledge of electronic configuration is necessary for understanding the structure of periodic table.It helps in understanding the chemical properties of elements.

Elements undergo chemical reactions in order to achieve stability. Main group elements obey the octet rule in their electronic configuration while the transition elements follow the 18 electron rule. Noble elements have valence shell complete in ground state and hence are said to be stable.

Learn more about electronic configuration,here:

https://brainly.com/question/29757010

#SPJ6

One of the following that is NOT considered to be a pyroclastic material is;

D. Pahoehoe

Pyroclast material range in size from very small pieces of dust to ash to lapilli to bombs and block to cinders. A pahoehoe is just basaltic lava forming smooth undulating masses. Thus, it is not considered of pyroclastic material.

Pahoehoe lava flows are described by smooth, lightly undulating, or broadly hummocky surfaces. The liquid lava running beneath a thin, still-plastic crust drags and twists it into tapestry-like folds and rolls relating twisted rope. Pahoehoe lava flows are maintained substantially wholly internally by rivers of liquid lava flowing beneath a fixed or partly solidified surface.

Not necessarily.

Isomers might differ in polarities. They will end up with different physical properties such as melting points.

Example:

Both 1,4- and 1,2-dichlorobenzene contains two chlorine atoms connected to a benzene ring. The two molecules are structural isomers.

The two chlorine atoms are adjacent to each other in the 1,2 isomer. The molecule is asymmetric and polar.

The two chlorine align with an axis of symmetry in the 1,4 isomer. The molecule is symmetric. The dipoles would cancel out to produce a nonpolar molecule.

Dipole-dipole interactions are typically stronger than induced dipole in isomers. As a result, the 1,2 isomer has a higher melting point.

Answer:

B. A harmful compound can become harmful when its elements are seperated.

Explanation:

In the question, common table salt, NaCl was the illustration.

NaCl is a crystalline solid whjch has different benefits like for preservation, add taste to foods etc. NaCl is generally consumed by humans daily and is found readily. This goes to show that NaCl is a harmless compound but the individual elements that is, Soduim and Chlorine gas,

2Na + Cl2 --> NaCl

Soduim metal is a reactive and unstable element with 1 (valence) electron in its outer shell. Hence why the reaction of sodium strips with water is explosive.

Chlorine gas is very poisonous, unstable as well as reactive because of the 7 (valence) electrons in its outermost shell.

Picture A and B are examples of pure substances.

Classifying substances based on composition, without seeing the pictures but assuming the guideline of uniform composition defining pure substances, the culmination is that if both Pictures B and D exhibit uniform compositions, they should be categorized as pure.

This discussion refers to the subject of Chemistry which involves classifying substances based on their composition. Without access to actual images, supposing we have a comprehension of the classification criteria: pure substances consist of a single type of particles whereas mixtures are composed of, more so, diverse particle types. If we take pure substance as uniform in composition, and Picture B and Picture D exhibit that characteristic, then the answer should be 'Pictures B and D are examples of pure substances'.

https://brainly.com/question/34608873

#SPJ6

Answer: Octet rule

Explanation: The elements which have filled s and p orbitals or noble gases are most stable and thus every element tends to get stable by completing their octet.

For example:  Sodium [Na] has atomic no of 11 and thus the electronic configuration is : [tex]Na:1s^22s^22p^63s^1[/tex] tends to get stable by losing one electron and gets converted to [tex]Na^+[/tex]

Electronic configuration for  [tex]Na^+:1s^22s^22p^6[/tex]

Thus acquiring stable configuration with filled s and p orbitals.

For example:  Fluorine [F] has atomic no of 9 and thus the electronic configuration is : [tex]NF:1s^22s^22p^5[/tex] tends to get stable by gaining one electron and gets converted to [tex]F^-[/tex]

Electronic configuration for [tex]F^-:1s^22s^22p^6[/tex]

Thus acquiring stable configuration with filled s and p orbitals.

Answer:

A dipole-dipole refers to an intermolecular force, which takes place in between the two molecules that are polar. They take place when the slight negative terminal of one polar molecule gets fascinated towards the slight positive terminal of another polar molecule. These are weaker bonds in comparison to hydrogen bonds, however, they are stronger in comparison to London dispersion forces.

Dipole interactions are caused by the electrostatic attraction of the partial negative end of a molecule to the partial positive end of another. These interactions include dipole-dipole attractions, and van der Waals forces, such as electric dipoles, induced dipoles, and hydrogen bonding.

Dipole interactions, also referred to as dipole-dipole attractions, are caused by the electrostatic attraction of the partial negative end of one polar molecule for the partial positive end of another. These interactions are part of the larger group of intermolecular attractive forces, or van der Waals forces, which are fundamental to the behavior of liquids and solids.

Electric dipoles form in a system of two equal but opposite charges at a fixed distance apart, such as in an atom or a molecule where the positive and negative charges are displaced by opposing forces. An example of this is a water molecule inside a microwave oven. Induced dipoles also occur, which are temporary dipoles formed when the electrons of an atom or molecule are distorted by the instantaneous dipole of a neighboring atom or molecule.

Dipole interactions also include hydrogen bonding, which occur when hydrogen is bonded to one of the three most electronegative elements: F, O, or N, resulting in exceptionally strong dipoles. These concepts and interactions between particles are fundamental to understanding behavior at a molecular and atomic level in chemistry.

https://brainly.com/question/4160423

#SPJ6

 The atomic number increases moving left to right across a period and subsequently so does the effective nuclear charge. Therefore, moving left to right across a period the nucleus has a greater pull on the outer electrons and the atomic radii decreases.

Valence is the same in every family... except for transition metals, it goes from 1-8

dk if that helped

the correct answer is "all members within any period"