Which of the following statements about noncovalent interactions are true? Charge-charge interactions (salt bridge, ionic bond) are electrostatic interactions between a pair of ions. The energies of dipolar interactions depend on the relative orientation of the dipole. Van der Waals interactions have the shortest interaction range of noncovalent interactions. Hydrogen bonds are not directional.

Answer:

Carbon Cycle

Steps of the Carbon Cycle

Nitrogen Cycle

Steps of the Nitrogen Cycle

Oxygen Cycle

Oxygen is an element that is essential to biological organisms. The vast majority of atmospheric oxygen (O2) is derived from photosynthesis. Plants and other photosynthetic organisms use CO2, water, and light energy to produce glucose and O2. Glucose is used to synthesize organic molecules, while O2 is released into the atmosphere. Oxygen is removed from the atmosphere through decomposition processes and respiration in living organisms.

Explanation:

Answer:

K2X

Explanation:

Valency can be defined as the combining power of an element. It is the valency that dictates the value an element will have when writing a chemical formula for its compound.

MgX is a compound of magnesium and an element X. The valency of magnesium in most of its compound is +2. Now for the 2 to have been absent in the chemical formula, this shows that the element X itself have a valency if -2 for the valencies of both to have canceled out.

Now considering the element potassium, it is an alkaline metal belonging to group 1 of the periodic table. Hence, it is expected that it has a valency of +1

Forming a compound with element X means there would be an exchange of valencies between the two. We have established that x has a valency of -2. The formula of the compound thus formed by exchanging the valencies of both element would be K2X

The most likely formula for the compound formed between potassium and element X would be [tex]K_2X[/tex].

Magnesium reacts with X to form MgX.

Magnesium has 2 valence electrons ([tex]Mg^2^+[/tex]), in order to form MgX with the element X, it means X must have the capacity to accept the 2 valence electrons from Mg. Thus, X would carry a deficit of 2 electrons in its valence shell ([tex]X^2^-[/tex]).

Potassium has one valence electron ([tex]K^+[/tex]). In order for [tex]X^2^-[/tex] to react with potassium, 2 atoms of potassium would be needed to donate their electrons each to [tex]X^2^-[/tex] in order for X to become stable. Thus

2[tex]K^+[/tex] + [tex]X^2^-[/tex] ---> [tex]K_2X[/tex]

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Answer:

The nswer to the question is

The maximum fraction of the air in the room that could be displaced by the gaseous nitrogen is 0.548 or 54.8 %

Explanation:

To solve the question we note that

The density of the liquid nitrogen = 0.808g/mL and the volume is 195 L tank (vaporised)

Therefore since density = mass/volume we have

mass = Density × volume = 0.808 g/mL × 195 L × 1000 ml/L =157560 g

In gaseous form the liquid nitrogen density =1.15 g/L

That is density = mass/volume and volume = mass/density = 157560 g/(1.15g/L)  or

volume = 137008.69565 L

The dimension of the room = 10 m × 10 m × 2.5 m = 250 m³ and

1 m³ is equivalent to 1000 L, therefore 250 m³ = 250 m³  × 1000 L/m³ = 250000L

Therefore fraction of the volume occupied by the gaseous nitrogen =

137008.69565 L/250000 L = 0.548

Therefore the gaseous nitrogen occpies 54.8% of the room

To find the maximum fraction of air displaced by vaporized nitrogen in a room, calculate the mass of liquid nitrogen, convert it to gaseous volume, and compare it to the room's volume.

When considering the accidental vaporization of 195 liters of liquid nitrogen in a closed room, we need to calculate the volume of the room and determine what fraction of the room's air could potentially be displaced by the nitrogen gas. To do this, we will use the given room dimensions and the densities of liquid and gaseous nitrogen. The room's volume is 10.00 m x 10.00 m x 2.50 m, which equals 250 cubic meters or 250,000 liters. The density of liquid nitrogen is 0.808 g/mL, and it converts to 0.808 kg/L since there are 1000 milliliters in a liter. Multiplying the density by the total volume of liquid nitrogen gives us the mass in kilograms, which is then converted to the volume of gaseous nitrogen at standard temperature and pressure using the given density of 1.15 g/L.

Now, converting the mass to volume for gaseous nitrogen, we can find out the fraction of room's air displaced by using the ratio of nitrogen gas volume over the room's total volume. This is an application of the ideal gas law where a given mass of gas occupies different volumes based on its phase (liquid or gas) and other conditions such as temperature and pressure.

Answer:

I > III > II

Explanation:

I) A disulfide bond between two cystines is created when a sulfur atom from one cystine forms a strong, single covalent bond with a sulfur atom from a second cystine. When a disulfide bond is created, each cystine loses one hydrogen atom. The atom count is 11 for a cystine in mid-chain, but changes to 10 if the cystine joins with another in a disulfide bond. This lead to a much more stable intermolecular interaction.

III) Hydrogen Bonding in water

These hydrogen bonds are at best an interaction, inducing slight positive and negative charges in the Hydrogen and Oxygen/Nitrogen atoms.

The Hydrophilic amino acids have O & N atoms, which form hydrogen bonds with water. These atoms have an uneven distribution of electrons, creating a polar molecule that can interact and form hydrogen bonds with water.

The hydrogen bonds aren't as strong as the covalent bonds in disulfides.

II) Hydrophobic interactions between two leucines

A hydrophobic interaction is formed between two nonpolar molecules.

It describes the preference of nonpolar molecular surfaces to interact with other nonpolar molecular surfaces, thereby displacing water molecules from the interacting surfaces.

Answer:

The answer is A.  a north, B south and C south

Explanation:

i just took the test

Answer:

A

Explanation:

USATestprep

Except for __________, the following statements about blood are true.

a.The viscosity is three to five times greater than water.

b The pH is slightly acidic.

c. It contains about 55% plasma.

D. It contains dissolved gases.

Except for the pH is slightly acidic, the following statements about blood are true.

Viscosity is an inherent feature of liquid compared to the inner resistance of nearby fluid films pushing through one another. All blood has a much greater viscosity than water.  Authorities regard these matters as “non-Newtonian fluids,” of which ketchup and blood are excellent illustrations.

Blood is usually slightly basic, with a typical pH scale of approximately 7.35 to 7.45. Plasma composes 55% of the whole blood volume. The albumin included in plasma restricts the blood from dropping too much water. The plasma of vertebrates also includes dissolved gases.

Blood is a fluid connective tissue that is 92 percent water. It is slightly more acidic, viscous, and salty than water.

Blood is a fluid connective tissue composed of plasma, dissolved substances, and blood cells. It is about 92 percent water, making the statement provided true. However, blood is slightly more acidic than water, slightly more viscous than water, and slightly more salty than seawater, making these statements false. Red blood cells carry oxygen, white blood cells defend the body, and platelets help blood clot.

Answer:

[tex]-3.896\times 10^{-12} N[/tex] is an electric force on the potassium ion due to the chloride ion.

Explanation:

Charge on potassium ion = [tex]q_1=1.602\times 10^{-19} C[/tex]

Charge on chlorine ion = [tex]=q_2=-1.602\times 10^{-19} C[/tex]

Separation between these two charges = r = [tex]7.700 nm=7.700\times 10^{-9} m[/tex]

[tex]1 nm=10^{-9} m[/tex]

Electric force on the potassium ion due to the chloride ion = F

Coulomb's law is given as ;

[tex]F=K\times \frac{q_1\times q_2}{r^2}[/tex]

[tex]q_1,q_2[/tex] = Charges on both charges

r = distance between the charges

K = Coulomb constant =[tex]9\times 10^{9} N m^2/C^2[/tex]

[tex]F=9\times 10^{9} N m^2/C^2\times \frac{1.602\times 10^{-19} C\times (-1.602\times 10^{-19} C)}{(7.700\times 10^{-9} m)^2}[/tex]

[tex]F=-3.896\times 10^{-12} N[/tex]

(negative sign indicates that attractive force is exerting between two ions)

[tex]-3.896\times 10^{-12} N[/tex] is an electric force on the potassium ion due to the chloride ion.

Final answer:

To find the electric force on a K+ ion due to a Cl- ion, Coulomb's law is used, employing the values for Coulomb's constant, the charge of each ion, and the distance between the ions.

Explanation:

The question refers to calculating the electric force on a K+ ion due to a Cl- ion across a membrane using Coulomb's law. Coulomb's law is defined as F = k * |q1*q2| / r^2, where F is the force between the charges, k is the Coulomb's constant (8.987 x 10^9 N m^2/C^2), q1 and q2 are the magnitudes of the charges (for K+ and Cl-, it's 1.602 x 10^-19 C), and r is the distance between the charges (7.700 nm or 7.700 x 10^-9 m). Plugging these values into Coulomb's law:

F = (8.987 x 10^9) * (1.602 x 10^-19)^2 / (7.700 x 10^-9)^2

After calculating, you will find the electric force exerted on the K+ ion due to the Cl- ion. This principle is crucial in understanding the movement of ions across cell membranes, influencing cell behavior and function.

Answer: d) 67.7KJ

Explanation:

Number of moles of Benzene= 125/78.11=1.60 moles

Q = mc◇T = 125× 1.60×(425-353)= 9540J

Q= ◇Hvap× 1.60=

33.9 × 1.60 = 54.24KJ

Q = mc◇T= 125 × 1.73× (353-335)=3803KJ

Total energy required to remove Carbon= (9540 + 54240+ 3893) J =67,673J =67

7KJ

Answer:

Although the question is not clear enough, I'll explain in the most helpful way that I can.

Explanation:  The Quantum Mechanical Model of the atom is one of two models that explains the structure of an atom. In this model, it is imposssible to know the exact position and momentum of an electron at the same time and thus its position is uncertain. However, electrons are said to occupy three dimensional regions of probability referred to as 'ORBITALS'. You can simply refer to the orbitals as where there is very high likelihood for one or two electrons to be found. Each of these orbials are depicted with a number, n and a letter(s,p,d,f or g) eg 1s, 2p, etc. The 'number' signifies the  distance of the orbital from the nucleus and the energy level of the electron in an atom while the 'letter' indicates the shape of the orbital, for example, the s-orbital is spherical in shape.

I hope this helps!

Answer:

8.75 mL

Explanation:

First, we calculate the molar mass of NaCl = molar mass of Na + molar mass of Cl. Molar mass of Na = 23 g/mol, molar mass of Cl = 35.5 g/mol.

So molar mass NaCl = (23 + 35.5) g/mol = 58.5 g/mol. The number of moles ,n of NaCl in 12.5g is n = mass of NaCl/ molar mass NaCl = 12.5 g / 58.5 g/mol =  0.214 mol.

The molarity, M of 150 mL M = number of moles/ volume = 0.214 mol / 150 mL = 1.427 M.

We now calculate the number of moles of NaCl in 250 mL of 0.500 M.

Number of moles, n = molarity × volume. molarity = 0.500 M, volume = 250 mL. So n = 0.500 × 250 = 0.125 moles. Since we have 0.125 moles in the dilute 250 mL solution, the volume of the 150 mL 1.43 M solution required is number of moles in 250 mL solution/molarity of 150 mL solution = 0.125 mol / 1.427 M = 0.0875 L = 8.75 mL

The molarity of the given ethanol solution can be computed using its given molality and the density of the solution. The molality tells us the moles of ethanol per kilogram of water, and the density allows us to convert this to moles per liter, generally yielding a larger molarity for the same solution. Thus, the molarity of ethanol in this solution would be 914 M.

To calculate the molarity of the ethanol solution, we first need to know that the definition of molality (m) is the moles of solute (in this case, ethanol) per kilogram of solvent (here, water). Given that the density of the solution, is 0.914 g/mL, we can convert this to kg/L for ease of calculation. So, 0.914 g/mL is equivalent to 914 kg/m^3.

Next, let's take 21.71 molal solution, implying there are 21.71 moles ethanol in 1 kilogram of water. Since the density of the solution is 0.914 g/mL (or 914 kg/m^3), there would be 914 moles of ethanol in 1 m^3 of solution (since 1 L = 1 m^3).

Thus, the molarity (M), which is defined as the moles of solute per liter of solution, of the ethanol in the solution would be 914 M.

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Answer:

The answer to your question is letter B. 2.5 atm

Explanation:

Data

P1 = ?                  P2 = 2 atm

T1 = 45°C = 318°K           T2 = 35°C = 308°K

V1 = 28 L             V2 = 34 L

Formula

Combined gas law

   P1V1/T1 = P2V2/T2

solve for P1

   [tex]P1 = \frac{T1P2V2}{V1T2}[/tex]

Substitution

  P1 = (318 x 2 x 34) / (28 x 308)

Simplification

  P1 = 21624 / 8624

Result

  P1 = 2.5 atm

Answer:

The answer to your question is   2NaCl  + 2H₂O    ⇒   2NaOH  +  Cl₂  +  H₂

Explanation:

Original chemical equation

                   NaCl  +  H₂O    ⇒   NaOH  +  Cl₂  +  H₂

                   Reactant      Element        Products

                       1                    Na                    1

                       1                    Cl                      2

                       2                    H                      3

                       1                     O                      1

This reactions is unbalanced

                2NaCl  + 2H₂O    ⇒   2NaOH  +  Cl₂  +  H₂

                   Reactant      Element        Products

                      2                    Na                    1

                      2                    Cl                     2

                      4                    H                      4

                      2                     O                     2

Now, the reaction is balanced

Answer:

NaCl +     2         H2 O →     2      NaOH +      Blank    Cl 2 + Blank                H 2

Answer:

The work done on the system is 17.75_KJ

Explanation:

To solve this question we need to know the required equations from the given variables, thus

Initial volume = 85L

Final volume = 12L

External pressure = 2.4 atm.

work done = - PΔV

2.4×(85-12) = 175.2L×atm

Converting from L•atm to KJ is given by

1 L•atm = 0.1013 kJ

(175.2 L•atm) * (0.1013 kJ / 1 L•atm)

= 17.75 kJ

The work done on the system is 17.75_KJ

The work done on the system is -17.75 kJ.

Work done is obtained using the relation;

w = PΔV

where;

w = work done

V = change in volume

V1 =  85 L

V2 =  12 L

P =  2.4 atm

Hence;

w =  2.4 atm(12 - 85) L = -175.2 atm L

Now;

1 L atm = 101.325 J

-175.2 atm L = -175.2 atm L ×  101.325 J/1 L atm  = -17.75 kJ

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Answer:

The correct option is  2.No, because only electrons are involved in bonding.

Explanation:

The type of bond formed by carbon and nitrogen (carbon-nitrogen bond) is covalent bond

Also known as molecular bond, a covalent bond involves the sharing of pairs of electrons (known as bonding pairs or shared pairs) between the carbon and nitrogen atoms forming stable, balanced forces in attraction and repulsion as they share common electrons in their compounds.

This electron sharing covalent bond is what enables the formation of the several compounds between carbon and nitrogen for example, in an amine, nitrogen which has five electrons, has two remaining electrons that forms a lone pair whereby it can combine further with other elements.

Hence the factor that influences the bonds to make the numerous organic molecules is the available electrons which constitutes the shared electron pairs in covalent bonds while the neutrons which function is to keep the repulsive forces of positively charged protons from ripping the nucleus apart.

Explanation:

The given reaction equation is as follows.

         [tex]BaSO_{4}(s) \rightleftharpoons Ba^{2+}(aq) + SO_{4}^{2-}(aq)[/tex]

The value of [tex]\Delta G^{o}[/tex] = 59.1 kJ/mol

We know that ,

            [tex]\Delta G^{o} = -RT ln K_{sp}[/tex]

 or,       [tex]ln K_{sp} = -(\frac{\Delta G^{o}}{RT}) [/tex]

                       = -(\frac{59.1 kJ/mol}{(8.314 \times 10^{-3} kJ/mol.K \times 310 K))}[/tex]  

            = -22.93

or,      [tex]K_{sp} = e^{-22.93}[/tex]

                      = [tex]1.1 \times 10^{-10}[/tex]

      [tex]K_{sp} = [Ba^{2+}][ SO_{4}^{2-}][/tex]

Therefore,      [tex][Ba^{2+}] =\sqrt{K_{sp}}[/tex]

                                        = [tex]\sqrt{ 1.1 \times 10^{-10}}[/tex]

                                         = [tex]1.05 \times 10^{-5} M[/tex]

Therefore, we can conclude that the value of [tex][Ba^{2+}][/tex] in the intestinal tract is [tex]1.05 \times 10^{-5} M[/tex].

The concentration of Ba2+ (barium ions) in the intestinal tract following the ingestion of BaSO4 slurry can be calculated using the equilibrium constant (K) derived from the Gibbs free energy equation. After performing the calculations, [Ba2+] is found to be 3.45 x 10⁻⁶ M.

The question is essentially asking for the concentration of Ba2+ ions in the intestinal tract following the ingestion of BaSO4 slurry, given a ΔG° value of 59.1 kJ/mol at 37°C. In order to solve this, we need to consider the process of the reaction: BaSO4(s) ⇌ Ba2+(aq) + SO42−(aq). From the Gibbs free energy equation, we can calculate the equilibrium constant (K) as: K = e^(-ΔG°/RT), where R is the gas constant (R = 8.314 J/molK) and T is the temperature in Kelvin (37°C = 310K).

Therefore, ΔG° = -RTlnK -> K=e^(-ΔG°/RT). We find K = e^(-(−59.1×10³J mol⁻¹)/((8.314 J K⁻¹ mol⁻¹)(310 K))), which gives K = 1.19 x 10⁻¹⁰. Since the equilibrium involves the dissolution of one BaSO4 molecule to give one Ba2+ ion and one SO42- ion, the equilibrium concentrations of Ba2+ and SO42- are equal. Hence, [Ba2+] = sqrt(K) = sqrt(1.19 x 10⁻¹⁰) = 3.45 x  10⁻⁶ M.

In conclusion, the concentration of Barium ions, Ba2+, in the intestinal tract following ingestion of BaSO4 slurry would be around 3.45 x  10⁻⁶M.

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The number of moles in each compound is:

What is Avogadro's number?

It is the number of atoms or molecules in one mole of a substance, equal to 6.023 × 10²³.

We want to convert molecules to moles, so Avogadro's number will be the conversion factor.

The number of moles in each compound is:

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Final answer:

To find the moles for CO2, H2O, and C6H12O6, we divide the number of molecules by Avogadro's number, yielding 4.09 × 10^-3 mol for CO2, 1.66 × 10^-20 mol for H2O, and 1.45 × 10^9 mol for C6H12O6.

Explanation:

To calculate the number of moles of each compound given the number of molecules, we will use Avogadro's number (6.022 × 10^23), which represents the number of particles in one mole of a substance. The formula to convert molecules to moles is:

Number of moles = (Number of molecules) / (Avogadro's number)

For CO2 (carbon dioxide):

Number of moles = (2.46 × 10^21 molecules) / (6.022 × 10^23 molecules/mol) ≈ 4.09 × 10^-3 mol

For H2O (water):

Number of moles = (10,000 molecules) / (6.022 × 10^23 molecules/mol) ≈ 1.66 × 10^-20 mol

For C6H12O6 (glucose):

Number of moles = (8.75 × 10^32 molecules) / (6.022 × 10^23 molecules/mol) ≈ 1.45 × 10^9 mol

Answer:0.119g

Explanation:equation of rxn is

2Al+6HCl=2AlCl3+3H2

From ideal gas eqn

PV=nRT

n=PV/RT

P here is the partial pressure of H2 from the qtn.According to Dalton law of partial pressure, PT=PH2+PH20

PT=0.89atm given

PH20=25.2mmhg given=25.2/760atm,=0.033atm

PH2=PT-PH20

PH2=0.89-0.033=0.857atm

T=26+273=299K

R=0.082atmdm^-3mol^-1K^-1

V=190.6ml=190.6cm3=190.6/1000=0.1906dm3

n=PV/RT

n=0.857*0.1906/0.082*299

=0.00667moles of H2.

From the eqn of reaction,

2moles of Al reacts to gv 3moles of H2

xmoles of Al will give 0.00667moles of H2

xmoles=0.00667*2/3 (cross multiplying)=0.00444moles of Al

From the relationship, n=mass/MW

mass=MW*n

MW of Al=27g/mol

mass=0.0044moles*27g/moles

mass=0.119grams of Al.

The mass of aluminum that has reacted is 0.119 g.  The mass of the reactant can be calculated by finding its moles.

the mass of the reactant can be calculated by finding its moles in the reaction and putting the value in the mole formula.

The given reaction is:

[tex]\bold {2Al+6HCl\rightarrow 2AlCl_3+3H_2}[/tex]

First, calculate the moles of the Hydrogen from the ideal gas equation,

[tex]n=\dfrac {0.857\times 0.1906}{0.082\times 299}\\\\ n = \rm 0.00667 \ moles \ of \ H2.[/tex]

The molar ratio between Al and [tex]\bold {H_2 }[/tex] is 3:2.

Thus, moles of Aluminium is:

[tex]\text{Moles of Al} = 0.00667\times \dfrac 23 \\\\\text{Moles of Al} = 0.00444 \rm \ moles[/tex]

Thus the mass of Aluminium,

[tex]m ={\rm 0.0044 \ moles\times 27 \ g/moles}\\\\m = 0.119\rm \ g[/tex]

Therefore, the mass of aluminum that has reacted is 0.119 g.

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Answer:

The correct answer to a) is sulfuric acid

b) 1/6 moles of aluminum sulfate is produced

Explanation:

To solve this we need to write out the balaned chemical equation as follows

Al(OH)3(s) + 3 H2SO4(aq) -----> Al2 (SO4)3(aq) + 6 H2O(l)

Here we see that one mole of aluminium hydroxide reacts with three moles of sulphuric acid to form one mole of aluminium sulphate and six ,oles of water

Hence the limiting reactant in this question is the sulphuric acid as 0.5 moles of alumininium hydroxide requires 1.5 moles of sulphuric acid to completely use up the aluminium hydroxide present

Dividing the number of moles of the reactants present by the amount of moles of sulphuric acid required we have

Hence 3 mole of sulphric acid combines with  1 mole of Aluminium hydroxide

0.5 mole of sulfuric acid combines with  0.5÷3 or 1/6 mole of Aluminium hydroxide

Hence the correct answer is sulfuric acid

b) to solve this, since three moles of sulfuric acid produces one mole of aluminium sulfate then 0.5 moles of sulfuric acid produces 0.5/3 or 0.166 mole of aluminum sulfate

hence 1/6 moles of aluminum sulfate is produced

Final answer:

After calculating the heat released by the condensation of water and equating it to the heat absorbed by the aluminum block, the final temperature of the aluminum block is found to be approximately 25.2°C.

Explanation:

The question asks us to determine the final temperature of an aluminum block after heat transfer occurs due to condensation of water on its surface. Both the water and the aluminum block initially have the same temperature of 25°C. We can use the concept of thermal equilibrium and specific heat capacity to solve this problem.

The heat released during the condensation of water (Qwater) is used to increase the temperature of the aluminum block (Qaluminum). According to the principle of conservation of energy, Qwater = Qaluminum.

We can calculate Qwater using the latent heat of condensation for water, which is 2260 J/g. Since 0.48 g of water condenses:
Qwater = mass × latent heat = 0.48 g  2260 J/g = 1084.8 J

Next, we calculate the change in temperature of the aluminum block using its specific heat capacity (900 J/kg•K), which allows us to find the final temperature:
Qaluminum = mass × specific heat capacity × change in temperature
1084.8 J = 0.055 kg × 900 J/kg•K × (final temperature - initial temperature)

Now, isolating the final temperature, we can solve for it:

final temperature = (1084.8 J / (0.055 kg × 900 J/kg•K)) + 25°C
final temperature = 25.2°C

Thus, the final temperature of the aluminum block, after absorbing the heat from the condensation of water, is approximately 25.2°C.

Answer:

[tex]V_f=V_2=1.22\times 10^{-3} L=1.22mL[/tex]

Explanation:

Use Charles's law which states: "At constant pressure, the volume occupied by a gas sample is directly proportional to the absolute temperatures they support."

This law can be expressed mathematically as follows:

[tex]\frac{V_1}{T_1}=\frac{V_2}{T_2}[/tex]

Where:

[tex]V_1=Initial\hspace{3}volume=1.64mL=1.64\times 10^{-3} L\\V_2=Final\hspace{3}volume\\T_1=Initial\hspace{3}temperature=94.6$^{\circ}$C=367.75K\\T_2=Final\hspace{3}temperature=0.3$^{\circ}$C=273.45K[/tex]

Solving for [tex]V_2[/tex]

[tex]V_2=\frac{V_1*T_2}{T_1} =\frac{(1.64\times 10^{-3} )*273.45}{367.75} =1.21946431\times 10^{-3} \approx1.22\times 10^{-3} L =1.22mL[/tex]

Answer:

[CaCl₂] = 1.32 M

Explanation:

We know the volume of solution → 0.30 L

We know the mass of solute → 44 g of CaCl₂

Let's convert the mass of solute to moles.

44 g . 1 mol / 110.98 g = 0.396 moles

Molarity (mol/L) → 0.396 mol / 0.3 L  = 1.32 M

Answer:

A  fan is a common house appliance which is attached to the ceiling and uses an electric motor to rotate blades or paddles in a circular motion. Ceiling fans help cool a room by moving air which causes evaporative cooling. Fans range in size from 36 inches to 56 inches using 55 to 100 watts, a typical 48 inch ceiling fan will use 75 watts.

where you have

Hours Used Per Day:5

Power Use (Watts): 75

Price (kWh): 0.01

then you have

Cost Per Hour=0.0075

Cost Per Day= 0.0375

Cost Per Month=1.14

Cost Per Year=13.69

kWh Per Day: 0.38

Answer:

5W

Explanation:

Answer: b. there is no net change in the amount of substrates or products.

Explanation:

The reactions which do not go on completion and in which the reactant forms product and the products goes back to the reactants simultaneously are known as equilibrium reactions.

Equilibrium state is the state when reactants and products are present but the concentrations does not change with time.

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For a chemical equilibrium reaction, equilibrium state is achieved when the rate of forward reaction becomes equals to rate of the backward reaction.

Explanation:

Evaporation

It is the process of converting liquid into vapors .

Condensation

It is the process of converting  vapors back into liquid state .

It is seen that  a equilibrium is reached when "rate of evaporation becomes equal to rate of condensation ".

Answer:

e. Na, Fe, K

Explanation:

The group of elements that will be positive charge ions is metal. You can find metal in the first 2 columns of the periodic table and in the transition area. Natrium/sodium (Na), iron (Fe), and kalium/potassium(K) categorized as metal and they will form positive charge ions.  

On the other hand carbon(C),  oxygen (O), arsenic(As) and bromine(Br) is gas and will form negative charge ions. Gas located on the right side of the periodic table.

The elements that readily form positively charged ions, or cations, are more often metals like Sodium (Na), Iron (Fe), and Potassium (K). Therefore, the correct answer from the options given is 'Na, Fe, K'. option e.

The elements that form cations, or positively charged ions, readily are elements that tend to lose electrons. This characteristic is typically associated with metals. In the options given, Na (Sodium), Fe (Iron), and K (Potassium) are the ones which are more likely to form cations. So, the correct answer to your question: 'Which of the following elements form cations (positively charged ions) readily: C, O, Na, Fe, As, Br, K?' would be option e. Na, Fe, K.

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Answer:

18.00 mL is the volume in mL of 1 mol of water

Explanation:

Water density = water mass / water volume

1 g/mL = water mass / water volume

1 mol of water weighs 18 g. Therefore, 1 g/mL = 18 g / water volume

water volume = 18 mL

Answer:

18.0

Explanation:

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Answer:

The answer to your question is Pd₂H₄

Explanation:

Data

mass of palladium = 42.56 g

mass of hydrogen = 0.8 g

Process

1.- Convert the grams of each substance to moles

                   106 g of Pd ----------------- 1 mol

                    42.56 g of Pd -------------  x

                      x = (42.56 x 1)/106

                      x = 0.402 moles

                      1 g of H --------------------- 1 mol

                     0.8 g of H ------------------ x

                     x = (0.8 x 1)/1

                     x = 0.8 moles

2.- Divide by the lowest number of moles

Palladium = 0.402/0.402 = 1

Hydrogen = 0.8/0.402 = 1.99 ≈ 2              

3.- Write the empirical formula

                                 PdH₂

4.- Calculate the mass of the empirical formula

PdH₂ = 106 + 2 = 108

5.- Divide the molar mass by the molar mass of the empirical formula

                     216.8/108 = 2

6.- Get the molecular formula

                 2(PdH₂) = Pd₂H₄

The molecular formula of the compound is determined to be Pd2H4, based on the calculated mole ratio of palladium to hydrogen and considering the given molar mass of the compound.

To find the molecular formula of a compound, we first determine the mole ratio between palladium and hydrogen. The molar mass of palladium (Pd) is 106.42 g/mol and the molar mass of hydrogen (H) is 1.008 g/mol. Therefore, 42.56 g of Pd is equivalent to 42.56/106.42 = 0.4 mol, and 0.80 g of H is equivalent to 0.80/1.008 = 0.793 mol. This simplifies to a ratio of 1:2, indicating the empirical formula of the compound is PdH2.

Next, we compare the molar mass of the empirical formula with the molar mass given for the compound. The molar mass of PdH2 is 1.008*2 + 106.42 = 108.436 g/mol. The molar mass given for the compound is 216.8 g/mol. Therefore, the molecular formula is twice the empirical formula, result to be Pd2H4.

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Answer:

1. A substance that is soluble in two liquids and makes an emulsion last longer is called "Emulsifier".

2. The process that reduces the size of particles so emulsions will last longer is called "Homogenization".

Explanation:

Emulsifiers are additives which enable two liquids to mix around each other. Water and oil separate in a container, for an instance, but using an emulsifier can make the liquids blend along. It is widely used on various foods and beverages. Egg yolks and mustard are a few examples of emulsifiers.

Homogenization is the physical mechanism by which the fat molecules in milk are broken down because then they stay incorporated instead of segregated as cream. Majority of the milk sold in the United States is homogenized.

Answer : A hypotonic solution has a higher concentration of water and lower concentration of solute than the cell placed in the solution.

Explanation :

Solution : It is made up of the combination of amount solute and solvent.

Isotonic solutions : It is defined as the solutions in which the concentration of solute inside the cell and outside the cell is same.

Hypotonic solutions : It is defined as the solutions in which the concentration of solute inside the cell is lower than outside the cell.

For example : Diluted sugar syrup

Hypertonic solutions : It is defined as the solutions in which the concentration of solute inside the cell is higher than outside the cell.

For example : Concentrated sugar syrup

Hence, a hypotonic solution has a higher concentration of water and lower concentration of solute than the cell placed in the solution.

The term for a solution that has a higher concentration of water and a lower concentration of solute than a cell is 'hypotonic'. In this scenario, water moves into the cell via osmosis.

A(n) hypotonic solution has a higher concentration of water and lower concentration of solute than the cell placed in the solution. In biology, we often talk about the relationship between cells and their surrounding environment in terms of tonicity. In a hypotonic environment, there is less solute (like salt or sugar) outside the cell compared to inside the cell. This causes water to move into the cell by osmosis, because water moves from areas of high concentration to areas of low concentration until equilibrium is reached.

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