A hot toluene stream, which has mass flow rate of 8.0 kg/min, is cooled by cooling water in a cocurrent heat exchanger; its temperature drops from 90o C to 60o C after passing through the heat exchanger. The cooling water stream has a mass flow rate of 10 kg/min and an inlet temperature of 20o C. Given that the specific heats of toluene and water are 0.41 and 1.00 kcal/(kg.o C), respectively, determine (a, 3%) the heat duty of the heat exchanger, (b,3%) the temperature of the cooling water leaving the heat exchanger, (c, 3%) the log mean temperature difference (or "driving force") for the heat exchange process, and (d, 3%) the UA value of the heat exchanger. Assume a negligible heat loss to the surroundings.

The concentration of the aluminum sulfate solution is calculated to be 25.8 g/dL by dividing the mass of the aluminum sulfate (116.0 g) by the volume of the solution (4.5 dL).

The concentration of a solution is given by the ratio of the mass of the solute to the volume of the solution. In this case, we have 116.0 g of aluminum sulfate dissolved in a solution whose total volume is 450.0 mL. To convert this volume to deciliters (dL), we remember that 1 L = 10 dL and 1 L = 1000 mL. Therefore, the volume of the solution is 450.0 mL * (1 L / 1000 mL) * (10 dL / 1 L) = 4.5 dL. The concentration of aluminum sulfate in the solution is thus 116.0 g / 4.5 dL = 25.8 g/dL.

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Answer:

89.52 gm

Explanation:

35.7 gm of NaCl , dissolves in 100ml of water.

Then amount of NaCl dissolved in 1 ml water = 35.7/100= 3.75 gm

therefore, sodium chloride dissolved in 250 ml of water

= 3.75×250= 89.25 gm

The maximum amount of sodium chloride that will dissolve in 250 ml of water is 89.25 g.

The solubility of sodium chloride in water is 35.7 g per 100 ml at 0°C. To find the maximum amount of sodium chloride that will dissolve in 250 ml of water, we can set up a proportion using the solubility values:

35.7 g / 100 ml = x g / 250 ml

Cross-multiplying and solving for x, we get:

x = (35.7 g * 250 ml) / 100 ml = 89.25 g

Therefore, the maximum amount of sodium chloride that will dissolve in 250 ml of water is 89.25 g.

Question: A optically active compound, C5H10O, exhibits IR absorption at 1730 cm-1.

Its carbon NMR shifts are given below. The number of hydrogen's at each carbon, determined by DEPT, is given in parentheses after the chemical shift.

13C NMR: δ 22.6 (3), 23.6 (1), 52.8 (2), 202.4 (1)

Draw the structure of this compound in the window below

Explanation:

3-methylbutanal is a butanal substituted by the methyl group at the 3rd position. It is a volatile constituent in the olive. Also, it is used as a flavoring agent and a plant metabolite, it is also a Saccharomyces cerevisiae metabolite. It is also called as the Isovaleraldehyde organic compound. The liquid is colorless at STP, and also found in very low concentrations. It is also seen to be produced commercially for different use. Mostly used compound reagent in the preparation of pharmaceuticals and pesticides.

Answer: The mass of cryolite produced is 65.06 kg

Explanation:

To calculate the number of moles, we use the equation:

[tex]\text{Number of moles}=\frac{\text{Given mass}}{\text{Molar mass}}[/tex]      .....(1)

Given mass of aluminium oxide = 15.8 kg = 15800 g     (Conversion factor:  1 kg = 1000 g)

Molar mass of aluminium oxide = 102 g/mol

Putting values in equation 1, we get:

[tex]\text{Moles of aluminium oxide}=\frac{15800g}{102g/mol}=154.9mol[/tex]

For the given chemical reaction:

[tex]Al_2O_3(s)+6NaOH(l)+12HF(g)\rightarrow 2Na_3AlF_6+9H_2O(g)[/tex]

As all the reactants are getting completely utilized. So, the amount of product can be determined by any 1 of the reactant.

By Stoichiometry of the reaction:

1 mole of aluminium oxide produces 2 moles of cryolite

So, 154.9 moles of aluminium oxide produces = [tex]\frac{2}{1}\times 154.9=309.8mol[/tex] of cryolite

Now, calculating the mass of cryolite by using equation 1, we get:

Moles of cryolite = 309.8 moles

Molar mass of cryolite = 210 g/mol

Putting values in equation 1, we get:

[tex]309.8mol=\frac{\text{Mass of cryolite}}{210g/mol}\\\\\text{Mass of cryolite}=(309.8mol\times 210g/mol)=65058g=65.06kg[/tex]

Hence, the mass of cryolite produced is 65.06 kg

0.87 grams of an 8% w/w progesterone gel must be mixed with 1.45 g of a 4% w/w progesterone gel to prepare a 2.32 g of 5.5% w/w gel

Let x represent the number of grams of an 8% w/w progesterone gel must be mixed with 1.45 g of a 4% w/w progesterone gel to prepare a (x + 1.45)g of 5.5% w/w gel

Hence:

(x * 8%) + (1.45 * 4%) = (x + 1.45) * 5.5%

0.08x + 0.058 = 0.055x + 0.07975

0.025x = 0.02175

x = 0.87 g

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To prepare a 5.5% w/w progesterone gel, you should mix 4.383 g of an 8% progesterone gel with 1.45 g of a 4% progesterone gel.

A weight/weight percent (w/w%) refers to the amount of a substance (in this case, progesterone) contained in a total solution. The equation we want to use here is 'mass of solute/mass of solution = concentration'. We know the concentrations of the individual gels and that of the final gel we want to achieve. We need to find out the amount of 8% gel to mix with 1.45 g of 4% gel to get a 5.5% gel.

This would be solved as follows:

Let's denote the weight of the 8% gel as x. The contribution of progesterone from the 8% gel is 0.08x, and from the 4% gel is 0.04*1.45 = 0.058 g. The total weight of the final gel solution is x+1.45 g. The total amount of progesterone is 0.08x + 0.058 g. To get a 5.5% solution, we set up the equation 0.08x + 0.058 / 1.45 + x = 0.055. Solving for x gives us 4.383 g.

Therefore, the answer is that 4.383 g of an 8% progesterone gel should be mixed with 1.45 g of the 4% gel to obtain a 5.5% gel.

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Answer:

A. False.

Every substance contains the same number of molecules i.e 6.02x10^23 molecules

B. False.

Mass conc. = number mole x molar Mass

Mass conc. of 1mole of N2 = 1 x 28 = 28g

Mass conc. of 1mol of Ar = 1 x 40 = 40g

The mass of 1mole of Ar is greater than the mass of 1mole of N2

C. False.

Molar Mass of N2 = 2x14 = 28g/mol

Molar Mass of Ar = 40g/mol

The molar mass of Ar is greater than that of N2.

Explanation:

Answer:

1-bromo-1-tert-butylcyclohexane

Explanation:

The parent compound comprises of a cyclohexane to with a tertiary butyl carbon attached. We have been told that the reaction occurs by radical mechanism hence we must recall the order of stability of radicals: tertiary>a secondary> a primary. This implies that the reaction will occur at carbon 1 of the cyclohexane which is a tertiary carbon atom. This leads to the formation of a radical at the 1-position and bromination at that position hence the answer chosen above.

The radical bromination of t-butylcyclohexane favors the formation of 1-bromo-1-tert-butylcyclohexane due to the stability of the tertiary radical intermediate formed during the reaction.

The major product obtained upon radical bromination of t-butylcyclohexane will most likely be 1-bromo-1-tert-butylcyclohexane. This is because radical bromination is highly selective for the most stable radical intermediate, which forms at the position with the greatest number of accessible hydrogens. In the case of t-butylcyclohexane, the tertiary carbon adjacent to the t-butyl group will form the most stable tertiary radical upon abstraction of a hydrogen, which leads to substitution by a bromine atom to form the final product.

Answer:

The precautionary principle would prevent the implementation of technologies that possess a risk to humans, animals, and the environment. The strengths are that it will definately save the population and planet from a new technology that could cause long-term harm.

The weakness is that this principle may inhibit new technologies that are needed to help under-developed countries from preventing diseases. The precautionary principle states that technologies should entirely risk-free.

Explanation:

Explanation:

According to the collision theory the rate of chemical reaction directly proportional to number of reaction between the reactant molecules. More the number of collision between the reactant molecules, more would  be the changes of reaction to occur that reactant converting into product.

Moreover, with an increase in concentration of reactant molecules, the chances of collision between the molecules increase and hence the rate of reaction also increase. Thus, we can say higher the concentration higher will be the rate of reaction.

Thus the above response about the theory is correct.

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Final answer:

To calculate the equilibrium constant, K, for the reaction A(aq) + 2B(aq) ⇒ 2C(aq), we can use the concentrations of A, B, and C at equilibrium. The equilibrium constant (K) for this reaction is approximately 5.07 x 10^-3.

Explanation:

To calculate the equilibrium constant, K, for the reaction A(aq) + 2B(aq) ⇒ 2C(aq), we need to use the concentrations of A, B, and C at equilibrium. Given that the equilibrium concentration of C is 0.0454 M, and the initial concentrations of A and B are 0.150 M and 0.200 M respectively, we can set up an expression for K.

The mathematical expression for the equilibrium constant, Kc, is given by:

Kc = [C]² / ([A] * [B]²)

Substituting the given equilibrium concentration and initial concentrations into the expression, we get:

Kc = (0.0454)² / (0.150 * (0.200)²) = 5.06666667 x 10^-3

Therefore, the equilibrium constant (K) for this reaction is approximately 5.07 x 10^-3.

Answer: 54.5%

Explanation:Please see attachment for explanation

Answer: the atomic Mass of Z is 46.26

Explanation:Please see attachment for explanation

Answer:

[NaOH] = 0.045 M

[red dye] = 0.031 M

Explanation:

The NaOH and the red dye will not react between them, so, the process that it's occurring is only a dilution. The final volume of the solution will be the volume of the flask, which is 100 mL.

The number of moles (n) of each substance will not vary, and it's calculated by the multiplication of the concentration (C) by the volume (V). If 1 is the initial solution, and 2 the diluted:

n1 = n2

C1*V1 = C2*V2

For NaOH:

C1 = 0.150 M

V1 = 30.0 mL

V2 = 100 mL

0.150*30 = C2*100

100C2 = 4.5

C2 = 0.045 M

For the red dye:

C1 = 0.125 M

V1 = 25.0 mL

V2 = 100 mL

0.125*25 = C2*100

100C2 = 3.125

C2 = 0.031 M

Final answer:

The final concentration of NaOH is 0.045 M and the final concentration of the red dye is 0.03125 M.

Explanation:

To calculate the final concentrations of NaOH and the red dye, we can use the formula:

11 = 22

Let's calculate the final concentration of NaOH first:

1 (concentration of NaOH) = 0.150 M

1 (volume of NaOH) = 30.0 mL = 0.030 L

2 (final concentration of NaOH) = ?

2 (final volume of solution) = 100 mL = 0.100 L

Plugging in the values into the formula gives us:

(0.150 M)(0.030 L) = 2 (0.100 L)

Solving for 2, we find that the final concentration of NaOH is 0.045 M.

Now, let's calculate the final concentration of the red dye:

1 (concentration of red dye) = 0.125 M

1 (volume of red dye) = 25.0 mL = 0.025 L

2 (final concentration of red dye) = ?

2 (final volume of solution) = 100 mL = 0.100 L

Using the formula:

(0.125 M)(0.025 L) = 2 (0.100 L)

We find that the final concentration of the red dye is 0.03125 M.

Answer: v = 2π2 Kme2 Z / nh

Explanation:

The formula for velocity of an electron in the nth orbit is given as,

v = 2π2 Kme2 Z / nh

v = velocity

K = 1/(4πε0)

m= mass of an electron

e = Charge on an electron

Z= atomic number

h= Planck’s constant

n is a positive integer.

Answer:

cilia and flagella

Explanation:

In prokaryotic species , cilia are present , and in eukaryotic species , flagella is present .

Cilia and flagella both have same function , i.e. , to enable the movement of the cell , along with the movement of some substance and direct the flow of these substance along the tracts.

Cilia and flagella are composed of basal bodies.

Hence , from the given statement of the question,

The correct term is cilia and flagella .

Cilia are the structures that help move substances across the surface of a tract. They are primarily found in certain types of cells such as those in the respiratory tract and the oviducts.

The structures that assist in moving substances across a tract surface are primarily called cilia. In biology, cilia are tiny hair-like structures that line certain types of cells, especially those in the respiratory tract and the oviducts. They work much like oars on a boat, moving in coordinated waves to propel substances (like mucus or egg cells) along the surface of the tract they occupy. They are responsible in movement of substances across tract.

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Answer:

0.000273 M

Explanation:

Henry's states that at constant temperature the amount of a gas that dissolves in a liquid is directly proportional to the partial pressure in of that gas in equilibrium with that liquid.

Pressure of Oxygen = mole fraction of Oxygen × 1.00 atm

Mole fraction Oxygen = 21/100 × 1.00atm = 0.21 atm

Molar solubility of Oxygen = KH × PO2 = 0.0013 × 0.21 = 0.000273 M

The amount of a gas that dissolves in a liquid is proportional to the partial pressure of the gas above the liquid. Solubility of oxygen in water exposed to air at 1.00 atm is 0.000273 M.  

Henry's Law:

It states that at constant temperature the amount of a gas that dissolves in a liquid is proportional to the partial pressure of the gas above the liquid.

C = k P

Where,

C = concentration of a dissolved gas

k = Henry's Law constant = 0.0013 M/atm.

P = partial pressure of the gas = [tex]\bold {\dfrac {21}{100} \times 1.00\ atm = 0.21\ atm}[/tex]

Put the values in the formula,

[tex]\bold {C = 0.0013 \times 0.21 = 0.000273\ M }[/tex]

Therefore, solubility of oxygen in water exposed to air at 1.00 atm is 0.000273 M.

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Answer:

a) compressed adiabatically:

T2 = 576.8 K

ΔU = 3422 J/mol

b) cooled at P contant to 30°C:

Q = - 5965.04 J/mol

c) expanded isotermally to P=100 KPa:

W = - 4054.403 J

Explanation:

ideal gas in a mechanically reversible process:

∴ T1 = 30°C = 303 K

∴ P1 = 100 KPa

a) compressed adiabatically to 500 KPa:

⇒ ΔU = W = CvΔT.....(1)

∴ Cv = (3/2)R = 12.5 J/K.mol

∴ W = - PδV........(2)

(1) = (2):

⇒ [(R+Cv)/R] Ln (T2/T1) = Ln (P2/P1)

∴ R+Cv/R = 5/2

⇒ (5/2) Ln(T2/T1) = 1.6094

⇒ LnT2 - LnT1 = 0.64376

⇒ LnT2 = 0.64376 + 5.7137 = 6.3575

⇒ T2 = 576.8 K

⇒ ΔU = W = (12.5 J/K.mol)(576.8 - 303 ) = 3422 J/mol

b)n cooled at constant P = 500KPa to 30°C:

∴ T2 = 303 K

∴ T1 = 576.8 K

∴ ΔU = Q + W

⇒ Q = CpΔT

∴ Cp = (5/2)R = 20.8 J/K.mol

⇒ Q = (20.8 J/K.mol)(303 - 576.8)

⇒ Q = - 5695.04 J/mol

c) expanded isothermally a P=100 KPa

∴ ΔU = 0

∴ T = 303 K

∴ P1 = 500 KPa

∴ P2 = 100 KPa

∴ W = nRT Ln(P2/P1)......assuming n = 1 mol

⇒ W = (1 mol)(8.314 J/K,mol)(303 K) Ln(100/500)

⇒ W = - 4054.403 J

This student's question concerns physics and thermodynamic cycles. It describes an ideal gas's behavior when it undergoes adiabatic compression, isobaric cooling, and isothermal expansion in a closed system.

Let's break these down:

In the entire cycle, the work done by the gas or on the gas depends on the path the gas follows during each process.

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Answer:

The concentration is 4.16 grams per liter, we call the solution saturated.

Explanation:

Step 1: Data given

The solubility of calcium chromate in water is 4.16 grams per liter.

Saturated Solution : A solution with solute that dissolves until it is unable to dissolve anymore, leaving the undissolved substances at the bottom.

Unsaturated Solution: A solution (with less solute than the saturated solution) that completely dissolves, leaving no remaining substances.

Supersaturated Solution: A solution (with more solute than the saturated solution) that contains more undissolved solute than the saturated solution because of its tendency to crystallize and precipitate.

Step 2:

If the calcium chromate solution has a concentration of 4.16 grams per liter.

If the concentration is less than 4.16 grams per liter, we call it unsaturated.

If the concentration is more than 4.16 grams per liter, we call it supersaturated.

The concentration is 4.16 grams per liter, we call the solution saturated.

Final answer:

A saturated solution contains the maximum amount of solute that can dissolve in a solvent at a specific temperature.

Explanation:

The solution is saturated because the concentration of calcium chromate in the solution is equal to its solubility in water, which is 4.16 grams per liter.

A saturated solution contains the maximum amount of solute that can dissolve in a given solvent at a specific temperature.

Saturated solutions are in a dynamic equilibrium where the rate of dissolution is equal to the rate of precipitation.

Answer: 0.83mol/m3

Explanation:

Number of mole = 2.5 mmol = 0.0025mol

Recall

1L = 0.001m3

Therefore 3L = 3x0.001 = 0.003m3

0.003m3 contains 0.0025mol

Therefore, 1m3 will contain = 0.0025/0.003 = 0.83mol

The concentration in mol/m3 is 0.83mol/m3

The concentration of this solution in number of molecules per cubic meter is equal to 5 x 10^23 molecules.

To calculate the amount of molecules present in a given substance, one must use Avogadro's constant, which corresponds to:

                                     [tex]6 \times 10 ^{23}molecules =1mol[/tex]

For this question, we must first calculate the molarity, so that:

                                               [tex]\frac{2.5 \times 10^{-3}mol}{xmol} =\frac{3L}{1L}[/tex]

                                            [tex]x = 0.83 \times 10^{-3} mol/L[/tex]

After that, you must convert the unit of volume to cubic centimeters, that is, milliliters, so that:

                                   [tex]0.83 \times 10^{-3} mol/L = 0.83 mol/ml[/tex]

Finally, just multiply the value obtained by the avogadro constant:

                                [tex]0.83 \times 6\times 10^{23}= 5 \times 10^{23} molecules[/tex]

So, the concentration of this solution in number of molecules per cubic meter is equal to 5 x 10^23 molecules.

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Answer:

              Ethanol is completely miscible due to presence of Hydrogen bonding.

              Ethanethiol is partially miscible due to absence of Hydrogen Bonding.

Explanation:

                     The miscibility of liquids depend upon the intermolecular interactions between the two liquids. The stronger the intermolecular interactions the more miscible will be the liquids.

Among the two given examples, Ethanol is more miscible in water because it exhibits hydrogen bonding which is considered the strongest intermolecular interaction. Hydrogen bonding occurs when the hydrogen atom is bonded to more electronegative atoms like Fluorine, Oxygen and Nitrogen. In this way the hydrogen atom gets partial positive charge and the electronegative atom gets partial negative charge. Hence, these partial charges results in attracting the opposite charges on other surrounding atoms.

While, in case of Ethanethiol the hydrogen atom is not bonded to any high electronegative atom hence, there will be no hydrogen bonding and therefore, there will be less interactions between the neighbour atoms.

The difference in solubility between ethanol and ethanethiol in water can be explained by the difference in polarity and the ability to form hydrogen bonds with water molecules.

Ethanol (C2H5OH) has a hydroxyl (-OH) group, which is polar and can form hydrogen bonds with water molecules. The oxygen atom in the hydroxyl group has a partial negative charge due to its higher electronegativity, and the hydrogen atoms in water have a partial positive charge. This allows for the formation of hydrogen bonds between the ethanol molecules and water molecules, which overcomes the energy required to break the hydrogen bonding network in water. As a result, ethanol can mix with water in any proportion, making it completely miscible.

On the other hand, ethanethiol (C2H5SH) contains a thiol (-SH) group instead of a hydroxyl group. Although the thiol group can still form hydrogen bonds, the sulfur atom is less electronegative than the oxygen atom in ethanol. This results in a weaker hydrogen bond with water molecules. Additionally, the larger size of the sulfur atom compared to the oxygen atom leads to a greater Van der Waals radius, which can disrupt the hydrogen bonding network in water more than the smaller oxygen atom. As a result, ethanethiol is not as soluble in water as ethanol, and its solubility is limited to 1.5 grams per 100 milliliters of water.

In summary, the greater polarity and hydrogen bonding capability of ethanol with water molecules make it completely miscible, while the weaker hydrogen bonding and disruption of water's hydrogen bonding network by ethanethiol limit its solubility in water.

The gas is accurately described by the ideal gas equation. Calculations reveal that the given conditions match Argon (Ar) most closely. Thus, the correct option is B) Ar.

To identify the gas accurately, we can use the ideal gas equation: PV = nRT, where P is pressure, V is volume, n is the number of moles, R is the ideal gas constant, and T is the temperature in Kelvin.

First, let's calculate the number of moles (n) using the given mass (m) of the gas and its molar mass (M). The molar mass of the gas is necessary for this step.

[tex]\[ n = \frac{m}{M} \][/tex]

For this calculation, we need to know the molar mass of each gas option. The molar masses are approximately:

- CO2: 44.01 g/mol

- Ar: 39.95 g/mol

- Ne: 20.18 g/mol

- N2: 28.02 g/mol

Let's go through the calculations step by step.

Given values:

- Mass (m) = 27.1 g

- Volume (V) = 50.0 L

- Pressure (P) = 0.500 atm

- Temperature (T) = 449 K

1. Calculate moles (n) using the given mass:

[tex]\[ n = \frac{m}{M} \][/tex]

For CO2: [tex]\( n_{\text{CO2}} = \frac{27.1 \, \text{g}}{44.01 \, \text{g/mol}} \approx 0.616 \, \text{mol} \)[/tex]

For Ar: [tex]\( n_{\text{Ar}} = \frac{27.1 \, \text{g}}{39.95 \, \text{g/mol}} \approx 0.679 \, \text{mol} \)[/tex]

For Ne: [tex]\( n_{\text{Ne}} = \frac{27.1 \, \text{g}}{20.18 \, \text{g/mol}} \approx 1.342 \, \text{mol} \)[/tex]

For N2: [tex]\( n_{\text{N2}} = \frac{27.1 \, \text{g}}{28.02 \, \text{g/mol}} \approx 0.968 \, \text{mol} \)[/tex]

2. Use the ideal gas equation to calculate moles (n):

[tex]\[ n = \frac{PV}{RT} \][/tex]

Substitute values:

[tex]\[ n = \frac{(0.500 \, \text{atm} \times 50.0 \, \text{L})}{(0.0821 \, \text{L}\cdot\text{atm/mol}\cdot\text{K} \times 449 \, \text{K})} \][/tex]

[tex]\[ n \approx \frac{25}{36.8029} \approx 0.681 \, \text{mol} \][/tex]

3. Compare the calculated moles:

- [tex]\( n_{\text{CO2}} \approx 0.616 \, \text{mol} \)[/tex]

- [tex]\( n_{\text{Ar}} \approx 0.679 \, \text{mol} \)[/tex]

- [tex]\( n_{\text{Ne}} \approx 1.342 \, \text{mol} \)[/tex]

- [tex]\( n_{\text{N2}} \approx 0.968 \, \text{mol} \)[/tex]

The closest match is [tex]\( n_{\text{Ar}} \approx 0.679 \, \text{mol} \)[/tex], so the gas is likely Argon (Ar). Therefore, option B) Ar is the correct answer.

Complete question :- A real gas is in a regime in which it is accurately described by the ideal gas equation of state. 27.1 g of the gas occupies 50.0 L at a pressure of 0.500 atm and a temperature of 449 K. Identify the gas.

A) CO2

B) Ar

C) Ne

D) N2

Answer: the empirical formula is CH3O and the subscripts are 1, 3, 1

Explanation:Please see attachment for explanation

Answer: C

Explanation:

N-methylpropanamide and methylamine are the compounds that posses hydrogen bonds.

Hydrogen bonds are formed when hydrogen is covalently bonded to a highly electronegative atom. Hydrogen bonds are weaker than covalent bonds but they significantly impact on the chemistry of the molecules in which they occur.

Primary, secondary and tertiary amines all form hydrogen bonds. The compounds that has hydrogen bonds are;

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Final answer:

The problem cannot be solved as presented because the initial energy flux of the black body at 255 K is not given. Without it, we cannot apply the Stefan-Boltzmann law to find the new temperature after adding 150 W/m^2.

Explanation:

The student is asking how to find the new temperature of a black body that was initially at 255 K after adding an energy flux of 150 W/m2. To solve this, we can apply the Stefan-Boltzmann law, which states that the energy radiated by a black body per unit area is directly proportional to the fourth power of the black body's temperature (E = σT4). The constant of proportionality, σ, is known as the Stefan-Boltzmann constant (σ = 5.67 x 10-8 W/m2K4).

where

q= heat flux = 155 W/m²+150 W/m² = 255 W/m²

σ= Stephan-Boltzmann constant = 5.67*10⁻⁸ W/m²K⁴

T= absolute temperature

T₀= absolute initial temperature = 255 K

solving for T

q = σ*(T⁴-T₀⁴)

T = (q/σ + T₀⁴)^(1/4)

replacing values

T = (q/σ + T₀⁴)^(1/4) = (255 W/m²/(5.67*10⁻⁸ W/m²K⁴) + (255 K)⁴)^(1/4) = 305.63 K

T=305.63 K

thus the final temperature is T=305.63 K

Answer:

We need 4.06 J to heat of 406.0 mg of cyclohexane

Explanation:

Step 1: Data given

Mass of cyclohexane = 406.0 mg = 0.406 grams

The initial temperature = 33.5 °C

The final temperature = 38.9 °C

The specific heat of cyclohexane = 1.85 J/g*K

Step 2: Calculate the energy required to heat

Q = m*c*ΔT

⇒ with m = the mass of cyclohexane = 0.406 grams

⇒ with c = the specific heat of cyclohexane = 1.85J/g*K

⇒ with ΔT = The change of temperature = T2 - T1 = 38.9 - 33.5 = 5.4

Q = 0.406 g * 1.85J/g*K * 5.40

Q = 4.06 J

We need 4.06 J to heat of 406.0 mg of cyclohexane

Answer:

Nitrogen fixation is the  conversion of gaseous nitrogen into an organism friendly form (ammonia) .

Explanation:

Nitrogen fixation -

It is very important and necessary process by which the nitrogen gas present in the atmosphere gets converted to nitrogen derivatives like ammonia  in the soil , is referred to as the process of nitrogen fixation.  

This occurs due to the reason , that the derivatives of nitrogen are of much more importance than the molecular nitrogen.  

Biologically the process is done by the rhizobium bacteria .

Hence ,

From the question,

The correct option is a.

Answer:

The state of the element or compound decided by two forces mainly:

The force of the attraction

The Kinetic(thermal) energy between the molecules of the element.

Explanation:

Kinetic Energy depends upon the temperature , and on increasing the temperature the kinetic energy also increases.

Force of attraction between the particles is increased by applying pressure to the substance.

When the substance is in solid state then , the force of attraction between the particles is much more then the thermal energy of the particles.

The thermal energy or kinetic energy reduces the force of attraction between the particles.Hence if the kinetic energy is increased then the substances goes from solid to liquid state.

Thus on, increasing the temperature the substance changes the state from solid to liquid

[tex]Solid\rightleftharpoons Liquid[/tex]

If you increase further , the kinetic energy then the substance goes from liquid to gaseous state again.

[tex]liquid\rightleftharpoons Gases[/tex]

Role of Kinetic energy : The kinetic energy separate the particles further to large distance.Hence they become far apart result in change in state.

Affect of increasing pressure produce the reverse products.

[tex]Gas\rightleftharpoons liquid\rightleftharpoons Solid[/tex]

Answer: one simple distillation column is required to separate the stream into five pure products. With four different flat bottom flask, for collection of the distilled products

Explanation: simple distillation works with the difference in boiling points of the liquid to be separated. For the separation of five different constituent to be possible, we have to know the boiling points of the constituents.

For your understanding, let's define constituents in the liquid to be A, B, C, D, E. And the boiling points increases respectively. Start by heating the liquid to the boiling point of A to extract A. After a while check if the constituents A is still dropping in the flat bottom flask, if it has stopped dropping, it simply means that we have extracted all A constituents in the liquid, label the Flask A. Get another flask to extract constituent B.

Heat the mixture to the boiling point of B, after a while check if constituent B is still dropping in the flat bottom flask, if it has stopped dropping,it means that we have extracted all B constituent in the liquid, label the Flask B. Get another flask for C.

Repeat the same process for C and D.

After Extracting D we don't need to distillate E because we already have a pure form of E inside to the conical flask.

SEE PICTURE TO UNDERSTAND WHAT A SIMPLE DISTILLATION LOOKS LIKE

Final answer:

To calculate the moles of ammonium perchlorate needed to produce a certain amount of water, use the balanced chemical equation and the mole ratio between ammonium perchlorate and water.

Explanation:

To calculate the moles of ammonium perchlorate needed to produce a certain amount of water, we need to use the balanced chemical equation. From the equation 10Al(s) + 6NH4C1O4(s) → 4Al2O3 (s) + 2AlCl3 (s) + 12H₂O(g) + 3N2 (8), we can see that for every mole of NH4C1O4, 12 moles of H₂O are produced. Therefore, the moles of ammonium perchlorate needed can be calculated by multiplying the given moles of water by the ratio of moles of NH4C1O4 to moles of water, which in this case is 6.

Answer:

Hi

Acebutolol hydrochloride is the form of the hydrochloride salt of acebutolol, a synthetic derivative of butyranide with a hypotensive and antiarrhythmic activity. Acebutolol acts as a cardioselective beta-adrenergic antagonist with very little effect on bronchial receptors, having intrinsic sympathomimetic properties. Acebutolol is used in ventricular arrhythmias. Other indications may include hypertension, alone or in combination with other drugs. The salt scheme is found in the attached file.

Explanation: