An adult eats food whose nutritional energy totals
approximately2.2*103 Cal per day. The adult
burns2.0*103 Cal per day. How much excess
nutritionalenergy, in kilojoules, does the adult consume per day?
If 1lb of fat is stored by the body for each
14.6*103kilojoules of excess nutritional energy
consumed, how long will ittake this person to gain 1 lb.

Answer:

K.E. = 5.4362 × 10⁻¹⁹ J

Explanation:

The expression for Bohr velocity is:

[tex]v=\frac{Ze^2}{2 \epsilon_0\times n\times h}[/tex]

Applying values for hydrogen atom,  

Z = 1

Mass of the electron ([tex]m_e[/tex]) is 9.1093×10⁻³¹ kg

Charge of electron (e) is 1.60217662 × 10⁻¹⁹ C

[tex]\epsilon_0[/tex] = 8.854×10⁻¹² C² N⁻¹ m⁻²

h is Plank's constant having value = 6.626×10⁻³⁴ m² kg / s

We get that:

[tex]v=\frac {2.185\times 10^6}{n}\ m/s[/tex]

Given, n = 2

So,

[tex]v=\frac {2.185\times 10^6}{2}\ m/s[/tex]

[tex]v=1.0925\times 10^6\ m/s[/tex]

Kinetic energy is:

[tex]K.E.=\frac {1}{2}\times mv^2[/tex]

So,

[tex]K.E.=\frac {1}{2}\times 9.1093\times 10^{-31}\times ({1.0925\times 10^6})^2[/tex]

K.E. = 5.4362 × 10⁻¹⁹ J

Answer: The density of the metal is 10.60 g/mL and the volume occupied by 86.0 grams is 8.11 mL

Explanation:

To calculate the density of unknown metal, we use the equation:

[tex]\text{Density of substance}=\frac{\text{Mass of substance}}{\text{Volume of substance}}[/tex]       ......(1)

Volume of unknown metal = 19.8 mL

Mass of unknown metal = 210.0 g

Putting values in equation 1, we get:

[tex]\text{Density of unknown metal}=\frac{210.0g}{19.8mL}\\\\\text{Density of unknown metal}=10.60g/mL[/tex]

The density of the metal remains the same.

Now, calculating the volume of unknown metal, using equation 1, we get:

Density of unknown metal = 11.45 /mL

Mass of unknown metal = 86.0 g

Putting values in above equation, we get:

[tex]10.60g/mL=\frac{86.0g}{\text{Volume of unknown metal}}\\\\\text{Volume of unknown metal}=8.11mL[/tex]

Hence, the density of the metal is 10.60 g/mL and the volume occupied by 86.0 grams is 8.11 mL

Answer:

b.0.34 M

Explanation:

Given that:

Mass of NaCl = 20 grams

Molar mass of NaCl = 58.44 g/mol

The formula for the calculation of moles is shown below:

[tex]moles = \frac{Mass\ taken}{Molar\ mass}[/tex]

Thus,

[tex]Moles= \frac{20\ g}{58.44\ g/mol}[/tex]

[tex]Moles= 0.3422\ mol[/tex]

Given that volume = 100 mL

Also,

[tex]1\ mL=10^{-3}\ L[/tex]

So, Volume = 100 / 1000 L = 0.1 L

Considering:

[tex]Molarity=\frac{Moles\ of\ solute}{Volume\ of\ the\ solution}[/tex]

[tex]Molarity=\frac{0.3422}{0.1}[/tex]

Molarity = 0.34 M

Answer:

v = 2.512 E-5 m³/mol

Explanation:

∴ P = 80 bar → V = 0.001384 m³/Kg......sat. liq water table

∴ P = 85 bar → V = 0.0014013 m³/Kg

⇒ P = 83 bar → V = ?

specific volume ( V ):

⇒ V = 0.001384 + (( 83 - 80 ) / ( 85 - 80 ))*( 0.0014013 - 0.001384 )

⇒ V = 0.00139438 m³/Kg

molar volume ( v ):

∴ Mw water = 18.01528 g/mol

⇒ v = 0.00139438 m³/Kg * ( Kg/1000g ) * ( 18.01528 g/mol )

⇒ v = 2.512 E-5 m³/mol

Answer:

pH of buffer after addition of 1 mL of 0,1 M HCl = 7,0

Explanation:

It is possible to use Henderson–Hasselbalch equation to estimate pH in a buffer solution:

pH = pka + log₁₀

Where A⁻ is conjugate base and HA is conjugate acid

The equilibrium of phosphate buffer is:

H₂PO₄⁻ ⇄ HPO4²⁻ + H⁺    Kₐ₂ = 6,20x10⁻⁸; pka=7,2

Thus, Henderson–Hasselbalch equation for 7,00 phosphate buffer is:

7,0 = 7,2 + log₁₀ [tex]\frac{[HPO4^{2-}] }{[H2PO4^{-}]}[/tex]

Ratio obtained is:

0,63 = [tex]\frac{[HPO4^{2-}] }{[H2PO4^{-}]}[/tex]

As the problem said you can assume [H₂PO₄⁻] = 0,1 M and [HPO4²⁻] = 0,063M

As the amount added of HCl is 0,001 M the concentrations in equilibrium are:

H₂PO₄⁻   ⇄   HPO4²⁻ +        H⁺

0,1 M +x      0,063M -x  0,001M -x -because the addition of H⁺ displaces the equilibrium to the left-

Knowing the equation of equilibrium is:

[tex]K_{a} = \frac{[HPO_{4}^{2-}][H^{+}]}{[H_{2} PO_{4}^{-}]}[/tex]

Replacing:

6,20x10⁻⁸ = [tex]\frac{[0,063-x][0,001-x]}{[0,1+x]}[/tex]

You will obtain:

x² -0,064 x + 6,29938x10⁻⁵ = 0

Thus:

x = 0,063 → No physical sense

x = 0,00099990

Thus, [H⁺] in equilibrium is:

0,001 M - 0,00099990 = 1x10⁻⁷

Thus, pH of buffer after addition of 1 mL of 0,1 M HCl =

-log₁₀ [1x10⁻⁷] = 7,0

A buffer is a solution that can resist pH change upon the addition of an acidic or basic components. In this example you can see its effect!

I hope it helps!

Answer:

0.350 grams

Explanation:

The given mass of the pill that has to be taken as a dosage for the medication = 350 mg

The medication has to be determined in grams which means that milligram has to be converted to grams.

The conversion of mg to g is shown below:

[tex]1\ milligram=10^{-3}\ gram[/tex]

So,

[tex]350\ milligram=350\times 10^{-3}\ gram[/tex]

[tex]350\ milligram=0.350\ gram[/tex]

The medication required in grams = 0.350 grams

Final answer:

To convert 350 mg to grams, divide by 1000, resulting in 0.35 grams of medication.

Explanation:

To convert the dosage of medication from milligrams to grams, you need to know the conversion factor between these two units.

There are 1000 milligrams in one gram.

Therefore, you can find the amount in grams by dividing the milligram dosage by 1000.

For the pill with a dosage of 350 mg of medication, the conversion to grams would be:

Total given grams/1000

= 350 mg ÷ 1000

= 0.35 grams

Answer:

400 cans of soda would be lethal.

Explanation:

In a can of soda, there is (2.13 mg/oz * 12 oz) 25 mg caffeine.

25 mg * (1g / 1000 mg) = 0.025 g

If in a can of soda there is 0.025 g of caffeine, a lethal dose of caffeine will be ingested after drinking (10.0 g * (1 can / 0.025 g)) 400 cans of soda.

Answer:

Pr = 2273.58

Explanation:

∴ Cp = 0.5 J/g.°C

∴ κ = 0.2 W/m.°C * ( J/s / W ) = 0.2 J/s.m.°C

∴ μ = 2200 Lbm/ft.h * ( 453.592 g/Lbm ) * ( ft / 0.3048 m ) * ( h/3600 s )

⇒ μ = 909.433 g/m.s

⇒ Pr = ((0.5 J/g.°C )*( 909.433 g/m.s )) / 0.2 J/s.m.°C

⇒ Pr = 2273.58

Answer : The freezing point of solution is 273.467 K

Explanation : Given,

Mass of glucose (solute) = 0.3 g

Mass of water (solvent) = 1000 g = 1 kg

Moles of fructose (solute) = 0.5 mol

Mass of water (solvent) = 1000 g = 1 kg

Molar mass of glucose = 180 g/mole

First we have to calculate the moles of glucose.

[tex]\text{Moles of glucose}=\frac{\text{Mass of glucose}}{\text{Molar mass of glucose}}=\frac{0.3g}{180g/mole}=0.00167mole[/tex]

Now we have to calculate the total moles after mixing.

[tex]\text{Total moles}=\text{Moles of glucose}+\text{Moles of fructose}[/tex]

[tex]\text{Total moles}=0.00167+0.5=0.502moles[/tex]

Now we have to calculate the molality.

[tex]\text{Molality}=\frac{\text{Total moles}}{\text{Mass of water(solvent in kg)}}[/tex]

[tex]\text{Molality}=\frac{0.502mole}{(1+1)kg}=0.251mole/kg[/tex]

Now we have to calculate the freezing point of solution.

As we know that the depression in freezing point is a colligative property that means it depends on the amount of solute.

Formula used :  

[tex]\Delta T_f=K_f\times m[/tex]

[tex]T^o_f-T_f=K_f\times m[/tex]

where,

[tex]\Delta T_f[/tex] = change in freezing point

[tex]T_f^o[/tex] = temperature of pure water = [tex]0^oC[/tex]

[tex]T_f[/tex] = temperature of solution = ?

[tex]K_f[/tex] = freezing point constant of water = [tex]1.86^oC/m[/tex]

m = molality = 0.251 mole/kg

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

[tex]0^oC-T_f=1.86^oC/m\times 0.251mole/kg[/tex]

[tex]T_f=-0.467^oC=273.467K[/tex]

conversion used : [tex]K=273+^oC[/tex]

Therefore, the freezing point of solution is 273.467 K

Answer:  0.14 kg

Explanation:

Gourmet chocolate candy contains 7.00 g of dietary fat in each 22.7-g piece

That is 1 piece of candy weighs 22.7 g and contains 7.00 g of dietary fat

Converting the mass in pounds to kg  

1 lb = 0.45 kg = 450 grams    (1kg=1000g)

Number of pieces = [tex]\frac{450}{22.7g}=20pieces[/tex]

1 piece contains = 7 g of dietary fat

Thus 30 pieces would contain =[tex]\frac{7}{1}\times 20=140g[/tex] of dietary fat

1 g = 0.001 kg

Thus 140 grams =[tex]\frac{0.001}{1}\times 140=0.14kg[/tex]

Thus 0.14 kg of dietary fat are in a box containing 1.00 lb of candy.

Answer:

The  pH of the resulting solution is 12.52.

Explanation:

[tex]Molarity=\frac{n}{V}[/tex]

n = number of moles

V = volume of the solution in Liters

1)1 mol of HCl gives 1 mol of hydrogen ion.

[tex][HCl]=[H^+]=0.1 m[/tex]

Concentration of the hydrogen ion = 0.1 M

Volume of the solution = 10 mL = 0.010 L

[tex]0.1 M=\frac{n}{0.010L}[/tex]

Moles of hydrogen ions =  = 0.001 mol

2) 1 mol of NaOH gives 1 mol of hydroxide ion.

[tex][NaOH]=[OH^-]=0.2 M m[/tex]

Concentration of the Hydroxide ions = 0.2 M

Volume of the solution ,V'= 8 mL = 0.008 L

[tex]0.2=\frac{n'}{V'}[/tex]

Moles of hydroxide ions ,n ' = 0.0016

1 mol of HCl neutralizes 1 mol of NaOH ,then 0.001 mol of HCl will neutralize 0.001 mol NaOH.

So left over moles of hydroxide ions in the solution will effect the pH of the solution:

Left over moles of hydroxide ions in the solution = 0.0016 mol - 0.0010 mol = 0.0006 mol

Left over concentration of hydroxide ions:

[tex][OH^-]'=\frac{0.0006 mol}{0.010 L+0.008 L}=0.0333 mol/L[/tex]

[tex]pOH=-\log[OH^-]=-\log[0.03333 M]=1.48[/tex]

pH +pOH = 14

pH = 14 - 1.48 = 12.52

The  pH of the resulting solution is 12.52.

Answer:

[tex]1s^22s^22p^63s^23p^64s^2[/tex]

Explanation:

Calcium is the chemical element with symbol Ca and the atomic number equal to 20. As alkaline earth metal, the element, calcium is reactive metal. IT lies in the second group and forth period of the periodic table.

The number of the valence electrons of the calcium element is 2 and thus primarily denotes these electrons and forms ionic bond.

The ground state- electron configuration for calcium is: [tex]1s^22s^22p^63s^23p^64s^2[/tex]

The kinetic energy of an electron can be calculated utilizing the equation KE = hf - BE, but this specific equation cannot be solved without additional information such as the binding energy, frequency of the light radiation, or Plank's constant. Energy can also be calculated using Planck's equation,E = hf, or for a specific orbital using 13.6 eV / n², where n refers to the level of the orbital.

The kinetic energy acquired by an electron in a hydrogen atom after absorbing light radiation can be found by utilizing the equation KE = hf - BE (kinetic energy equals energy of radiation minus binding energy). In this case, if the electron absorbs a light radiation of energy 1.08x101 J, it's crucial to determine the binding energy first.

However, given the information available, further clarification is needed since binding energy, frequency of the radiation, or Plank's constant (h) are not specified in the question.

Similar energy calculations involve using Planck's equation E = hf, where E is energy, h is Planck’s constant, and f is the frequency of radiation. Furthermore, energy can also be calculated for a specific orbital of a hydrogen atom using the equation 13.6 eV / n², where n refers to the level of the orbital.

Remember, when using these equations you may need to convert your units appropriately to reach the correct answer.

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Answer:

9.2584 mol/L is the solubility of helium in water at 25 °C.

Explanation:

Henry's law states that the amount of gas dissolved or molar solubility of gas is directly proportional to the partial pressure of the liquid.

To calculate the molar solubility, we use the equation given by Henry's law, which is:

[tex]C_{He}=K_H\times p_{H_2O}[/tex]

where,

[tex]K_H[/tex] = Henry's constant = [tex]3.26\times 10 mol/L atm[/tex]

[tex]p_{He}[/tex] = partial pressure of carbonated drink = 0.284 atm

Putting values in above equation, we get :

[tex]C_{He}=3.26\times 10 mol/L atm\times 0.284 atm=9.2584 mol/L[/tex]

9.2584 mol/L is the solubility of helium in water at 25 °C.

Answer:

B) Increase in boiling point and decrease in vapor pressure

Explanation:

Vapor pressure is inversely related  to the Boiling point , as

higher the boiling point, lower the vapor pressure. and

Lower the boiling point, higher the vapor pressure.

Hydrogen bonding.

The electrostatic attraction between Hydrogen , bonded to electronegative atom like F, O, N and the more electronegative atom is called as Hydrogen bonding.

For example -

In alcohols, - OH group has Hydrogen that is bonded to more electronegative atom O.

As ,  

Extra energy is required to break Hydrogen bonds.

because the substance which exhibits Hydrogen bonding have lower vapor pressure than that of the substance with out Hydrogen bonding.

Hence , the substance with Hydrogen bonding , has higher boiling point,.

Hence , the correct option is  Increase in boiling point and decrease in vapor pressure .

Answer: The change in volume is 2.05 L

Explanation:

To calculate the final temperature of the system, we use the equation given by Charles' Law. This law states that volume of the gas is directly proportional to the temperature of the gas at constant pressure.

Mathematically,

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

where,

[tex]V_1\text{ and }T_1[/tex] are the initial volume and temperature of the gas.

[tex]V_2\text{ and }T_2[/tex] are the final volume and temperature of the gas.

We are given:

[tex]V_1=3.25L\\T_1=250.0K\\V_2=?\\T_2=406.8K[/tex]

Putting values in above equation, we get:

[tex]\frac{3.25L}{250.0K}=\frac{V_2}{406.8K}\\\\V_2=5.30L[/tex]

Change in volume = [tex]V_2-V_1=(5.30-3.25)L=2.05L[/tex]

Hence, the change in volume is 2.05 L

Answer:

[tex]A(t)=1.8+34.2*e^{-t}[/tex]

Explanation:

The concentration of CO2 in the room will be the amount of CO2 in the room at time t, divided by the volume of the room.

Let A(t) be the amount of CO2 in the room, in ft3 CO2.

The air entering the room is 3000 ft3/min with 0.06% concentrarion of CO2. That can be expressed as (3000*0.06/100)=1.8 ft3 CO2/min.

The mixture leaves at 3000 ft3/min but with concentration A(t)/V. We can express the amount of CO2 leaving the room at any time is A(t).

We can write this as a differential equation

[tex]dA/dt=v_i-v_o=1.8-A[/tex]

We can rearrange and integrate

[tex]dA/dt=v_i-v_o=1.8-A\\\\dA/(A-1.8)=-dt\\\\\int(dA/(A-1.8) = -\int dt\\\\ln(A-1.8)=-t+C\\\\A-1.8=e^{-t}* e^{C}=C*e^{-t}\\\\A=1.8+C*e^{-t}[/tex]

We also know that A(0) = 12000*(0.3/100)=36 ft3 CO2.

[tex]A(0)=1.8+C*e^{-0}\\36=1.8+C*1\\C=34.2[/tex]

Then we have the amount A(t) as

[tex]A(t)=1.8+34.2*e^{-t}[/tex]

The subsequent amount A(t) of carbon dioxide in the room at time t is determined by solving the differential equation that models the problem as a tank mixing problem, accounting for the rate of air being pumped in and out of the room.

To determine the subsequent amount A(t), in ft³, of carbon dioxide in the room at any given time t, we need to set up a differential equation that accounts for the rate of air being pumped in and out of the room. This situation is analogous to a classic problem in differential equations and mathematical modeling called the tank mixing problem.

The rate at which carbon dioxide enters the room is constant at 0.06% of the 3,000 ft³/min being pumped in, which equals 1.8 ft³/min of CO₂. The rate at which it leaves the room is proportional to the concentration of carbon dioxide in the room at time t. The change in the amount of carbon dioxide at any moment is then given by the rate in minus the rate out.

Let C0 be the initial concentration of CO₂ (0.3%), CV be the volume of the room (12,000 ft³), and r be the rate of air exchange (3,000 ft³/min). The differential equation modeling this situation is:

with initial condition A(0) = C0 * V. This equation can be solved using separation of variables and integrating both sides,

Upon inserting the values for V, C0, and r, we can find the expression for A(t).

Answer: Drugs.com is the site which have all we need regarding medicines and uses of medicines. It give the facility to search A-Z drugs, once you have searched the desired medicine by this feature of site, it further gives information about identification of pills, approval date, and interaction between drug-drug and drug- the food you eating, the manufacturing date of medicines. It doesn't give information about the calculators.

Therefore, (e) is the correct option here.

Drugs.com is a resourceful website for information about various drugs. It provides details like Pill Identification, Drugs A-Z, Interaction Checker, and more. However, it does not provide any calculator-type feature.

Drugs.com provides comprehensive information related to different types of medications. It covers areas such as Pill Identification, Product, Manufacturers, Drug Approval Date, Drugs A-Z, and Interaction Checker. However, Drugs.com does not offer any feature or functionality related to 'Calculators' pertaining to drug calculations or dosage calculations. Use of the site could enable someone to determine whether they have a substance use disorder, but it does not replace professional medical advice.

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Answer:

q = Positive

w = Negative

Explanation:

As per first law of thermodymanics,

ΔE = q + w

Where,

ΔE = Change in internal energy

q = Heat absorbed or heat released by the system

w = Work done

Sign conventions are used for heat transfer and work done during a thermodynamics process.

Sign convention for Heat transfer

Sign convention for Work done

In the given question, work is done on the surroundings so, w is negative.

Heat flows into a system or in other word heat is added to the system,

So q is positive.

Answer:

When experiments are carried out or research is done in a certain field of knowledge the scientist at first hypothesise certain knowledge or make theoretical hypotheses about that field of knowledge.

And then conduct the experiment or research to derive certain conclusions and get answers which they can apply on the hypothesis made or on the previous knowledge they have and thereby confirm or negate the hypothesis.

When two scientists are working on similar experiment and they tend to differ in the conclusions drawn by the result, as they get from experiment then it is called as confirmation bias among the scientists.

Answer:

The correct option is: b. pH 6.4-8.0

Explanation:

Phenol red is a weak acid that is used as a pH indicator and exists in the form of stable red crystals.

The color of the phenol red solution changes from yellow to red when the change in pH is observed. The color of phenol red transitions from yellow to red when the pH is 6.8 - 8.2 or 6.4 - 8.0

Above the pH of 8.2, the phenol red solution turns a bright pink in color.

Explanation:

Except for the use in the chemistry laboratory , were it is used to synthesize many useful products, silver nitrate is also has biolofical and medical relevance.

Silver nitrate is commonly used for silver staining, for demonstrating the reticular fibers, the proteins and the nucleic acids. It is also used as stain in the scanning electron microscopy.

Silver Nitrate is also used for the bone ulcers as well as the burns and the acute wounds.

Answer:

A loud ordinary conversation following the supplied information in the question is about 4500 dB. But, in the official decibel system measure a loud conversation does not overcome 100 dB.

Explanation:

Using the supplied data of the exercise, we say that in a restaurant conversation the value is 45 dB. If we multiply this by 100 we will have a value for a laud ordinary conversation.

45×100 = 4500 dB.

but as I mentioned in the answer, in the official decibel system measure a loud conversation between 2 man reaches a maximal of 100 dB.

The mole fraction of NaCl in the solution is 3.15 × 10-2.

The mole fraction of NaCl in a solution prepared by dissolving 117 g NaCl in 1.11 kg H2O can be calculated by dividing the moles of NaCl by the total moles of solute and solvent. First, we convert the mass of NaCl to moles using its molar mass. Then, we calculate the moles of water by dividing its mass by its molar mass. Finally, we divide the moles of NaCl by the sum of moles of NaCl and moles of water to get the mole fraction of NaCl in the solution.

Given:

Step 1: Convert mass of NaCl to moles:

Moles of NaCl = (mass of NaCl / molar mass of NaCl) = (117 g / 58.44 g/mol) = 2 moles

Step 2: Convert mass of H2O to moles:

Moles of H2O = (mass of H2O / molar mass of H2O) = (1110 g / 18.02 g/mol) = 61.55 moles

Step 3: Calculate mole fraction of NaCl:

Mole fraction of NaCl = (moles of NaCl / (moles of NaCl + moles of H2O)) = (2 moles / (2 moles + 61.55 moles)) = 3.15 × 10-2

Answer:

The final temperature of the entire water sample after all the ice is melted, is 12,9°C. We should realize that if there is no loss of heat in our system, the sum of lost or gained heat is 0.  It is logical to say that the temperature has decreased because the ice gave the water "heat" and cooled it

Explanation:

This is the begin:

Q1 = Q which is gained from the ice to be melted

Q2 = Q which is lost from the water to melt the ice

Q1 + Q2 = 0

We are informed that the ice is at 0 ° so we have to start calculating how many J, do we need to melt it completely. If the ice had been at a lower temperature, it should be brought to 0 ° with the formula

Q = mass. specific heat. (ΔT)

and then make the change of state by the latent heat of fusion.

The heat of fusion for water at 0 °C is approximately 334 joules per gram.

So Q = Hf . mass

Q1 = 334 J/g . 8.32 g = 2778,88 J

For water we should use this:

Q = mass. specific heat. (ΔT)

Q2 = 55g . 4180 J/kg. K (Tfinal -T initial)

Q2 = 55g . 4180 J/kg. K (Tfinal -T initial)

(notice we have kg, so we have to convert 55 g, to kg, 0,055kg so units can be cancelled)

Q2 = 0,055kg . 4180 J/kg. K (Tfinal (The unknown) -25°)

T° should be in K for the units of Specific heat but it is the same. The difference is the same, in K either in °C

25°C = 298K

Q2 = 0,055kg . 4180 J/kg. K (Tfinal -298K)

Now the end

Q1 + Q2 = 0

334 J/g . 8.32 g + 0,055kg . 4180 J/kg. K (Tfinal -298K)

2778,88 J + 229,9 J/K (Tfinal - 298 K) = 0

2778,88 J + 229,9 J/K x Tfinal - 68510,2 J = 0

229,9 J/K x Tfinal = 68510,2 J - 2778,88 J

229,9 J/K x Tfinal = 65731,4 J

Tfinal = 65731,4 J / 229,9 K/J

Tfinal = 285,9 K

Tfinal = 285,9 K - 273K = 12,9 °C

The final temperature of the water after an 8.32 g ice cube at 0.00 °C is placed into 55 g of water at 25 °C and all the ice melts is 12.959 °C, using the conservation of energy and assuming no heat loss to the surroundings.

When an 8.32 g ice cube at 0.00 °C is placed into 55 g of water at 25 °C, we can find the final temperature after all the ice is melted by applying the principle of conservation of energy. The heat gained by the ice melting must be equal to the heat lost by the water cooling down. We will assume that no heat is lost to the surroundings in this perfectly insulated system.

We need to calculate the heat required to melt the ice cube (Qmelt) using the heat of fusion of water (which is 79.9 cal/g or 334 J/g), and the heat lost by the water as it cools down (Qwater) using the specific heat of water (which is 4.184 J/g°C).

First, calculate the heat necessary to melt the ice:

Qmelt = mass of ice * heat of fusion

Qmelt = 8.32 g * 334 J/g

Qmelt = 2778.08 J

Next, set up the equation based on the conservation of energy, where the heat lost by the water (Qwater) equals the heat gained by the ice (Qmelt):

Qwater = mass of water * specific heat of water * temperature change

Qwater = Qmelt

55 g * 4.184 J/g°C * (25 °C - final temperature) = 2778.08 J

Solving for the final temperature:

230.62 J/°C * (25 °C - final temperature) = 2778.08 J

25 °C - final temperature = 2778.08 J / 230.62 J/°C

25 °C - final temperature = 12.041 °C

Final temperature = 25 °C - 12.041 °C

Final temperature = 12.959 °C

Therefore, the final temperature of the water after all the ice has melted is 12.959 °C (rounded to three significant figures).

Answer:

The correct answer is: 1.316 . 10⁻³ m³/kg.

Explanation:

The density (ρ) of a substance is the ratio of its mass (m) to its volume (V). At constant temperature and pressure, its value is constant and it is an intrinsic property of materials. The units of density are kg/m³.

[tex]\rho = \frac{m}{V}[/tex]

The specific volume (ν) of a substance is the ratio of its mass to its volume. We can see that it is the reciprocal of density and an intrinsic property of matter as well. Therefore, the units of specific volume are m³/kg.

[tex]\nu = \frac{V}{m}=\frac{1}{\rho }[/tex]

Given we know the density of the liquid, we can use this relationship to find out its specific volume:

[tex]\nu =\frac{1}{\rho }=\frac{1}{760.0kg/m^{3} } =1.316 .10^{-3} m^{3} /kg[/tex]

Answer: The concentration of [tex]Ba(OH)_2[/tex] comes out to be 0.129 M.

Explanation:

To calculate the concentration of base, we use the equation given by neutralization reaction:

[tex]n_1M_1V_1=n_2M_2V_2[/tex]

where,

[tex]n_1,M_1\text{ and }V_1[/tex] are the n-factor, molarity and volume of acid which is [tex]H_2SO_4[/tex]

[tex]n_2,M_2\text{ and }V_2[/tex] are the n-factor, molarity and volume of base which is [tex]Ba(OH)_2[/tex]

We are given:

[tex]n_1=2\\M_1=0.1023M\\V_1=12.58mL\\n_2=2\\M_2=?M\\V_2=10.00mL[/tex]

Putting values in above equation, we get:

[tex]2\times 0.1023\times 12.58=2\times M_2\times 10.00\\\\M_2=0.129M[/tex]

Hence, the concentration of [tex]Ba(OH)_2[/tex] comes out to be 0.129 M.

Answer: The time required will be 19.18 years

Explanation:

All the radioactive reactions follows first order kinetics.

The equation used to calculate half life for first order kinetics:

[tex]k=\frac{0.693}{t_{1/2}}[/tex]

We are given:

[tex]t_{1/2}=4.7\times 10^1yrs[/tex]

Putting values in above equation, we get:

[tex]k=\frac{0.693}{4.7\times 10^1yr}=0.015yr^{-1}[/tex]

Rate law expression for first order kinetics is given by the equation:

[tex]k=\frac{2.303}{t}\log\frac{[A_o]}{[A]}[/tex]

where,  

k = rate constant  = [tex]0.015yr^{-1}[/tex]

t = time taken for decay process = ?

[tex][A_o][/tex] = initial amount of the reactant = 2 g

[A] = amount left after decay process =  (2 - 0.5) = 1.5 g

Putting values in above equation, we get:

[tex]0.015yr^{-1}=\frac{2.303}{t}\log\frac{2}{1.5}\\\\t=19.18yrs[/tex]

Hence, the time required will be 19.18 years

Answer:

The answer to your question is:

mass = 3.74 g

Explanation:

Data

V = (4/3) πr³

density = 1.74 g/cm³

radius = r = 0.80 cm

Process

V = (4/3) π(0.8)³             Substitution

V = 2.1446 cm³

mass = density x volume

mass = 1.74 x 2.1446      Substitution

mass = 3.74 g

I don't understand if the second section is also a question.

Answer:

The reaction rate k is 0.0012563 (1/hour).

Explanation:

We considered the reactions occurring in the plant as first order, and represented by this equation:

[tex]y = L (1- e^{-kt})[/tex]

where y is the BOD at time t, L is the initial value of BOD and k is the reaction rate.

If we replaced with the values

y = 2 mg O2/l (1% of the initial value)

L = 200 mg 02/l

t = 8 hr

We can calculate k

[tex]y=L(1-e^{-kt})\\\\k=-(1/t)*ln(1-y/L) = -(1/8)*ln(1-2/200)=-(1/8)*(-0.01)=0.0012563 \, hour^{-1}[/tex]

The reaction rate k is 0.0012563 1/hour.

Final answer:

The rate of reaction for a municipal wastewater treatment plant can be found by calculating the total oxygen consumed to lower the BOD, using the volume of wastewater and the residence time. The initial BOD is 200 mg O2/liter and is reduced to a negligible level, indicating a complete reaction over the course of the 8-hour residence time.

Explanation:

Finding the Rate of Reaction in Wastewater Treatment Tanks

The student is tasked with finding the rate of reaction for a municipal wastewater treatment plant where wastewater is treated with aerobic bacteria that decompose organic material. The process significantly lowers the biochemical oxygen demand (BOD) from an entering feed of 200 mg O2/liter to a negligible level in the effluent. The key to solving for the rate of reaction is utilizing the given information: the wastewater volume (32,000 m3/day) and the mean residence time (8 hours)

To find the rate of reaction, we need to calculate the amount of oxygen consumed by the microorganisms to reduce the BOD to negligible levels. The initial BOD is given as 200 mg O2/liter, and since it's reduced to a negligible level, we can assume that virtually all the initial oxygen demand is consumed by the reaction. The volume converted to liters (since BOD is in mg/liter) and residence time in days must be considered to calculate the daily rate of reaction:

Once the daily rate is found, the rate of reaction will be the amount of oxygen consumed per day divided by the volume of wastewater treated in one day (in liters), providing the rate in mg O2/liter/day.