if the isentropic efficiency of the turbine is 80%, calculate the actual work output of the turbine, in kj/kg.

Answer:

we have four moles in 56L of co2

Answer:

ionic --complete transferring

covalent--- sharing of electron

metallic bonding--- occurs between free electrons and metal ions.

Explanation:

In ionic bond, the electrons transfer from one atom to another atom. The atom which loses electrons is known as donor whereas the atom which accept electrons is known as acceptor. In covalent bond, atoms share electrons mutually means both atoms donate their electrons and no one loses their electrons, it can only be shared. Metallic bonding refers to the type of bonding in which electrostatic attractive force present between free electrons  and positively charged metal ions.

The correct net ionic equation for the given precipitation reaction is;  Pb²⁺ (aq) + 2I⁻ (aq) → PbI₂(s). Option D is correct.

In the reaction, Pb²⁺ cations from lead nitrate (Pb(NO₃)₂) react with I- anions from potassium iodide (KI) to form solid PbI₂ (lead iodide). This is a precipitation reaction where the insoluble salt PbI₂ is formed.

Option A (2(NO₃)⁻ (aq) + 2K⁺(aq) → 2KNO₃) is not the correct net ionic equation because it represents the dissociation and reformation of the soluble salts potassium nitrate (KNO₃) and lead nitrate (Pb(NO₃)₂), but it does not include the formation of the insoluble PbI₂ precipitate.

Option B (Pb²⁺(aq) + 2(NO₃)⁻ (aq) + 2K⁺ (aq) + 2I⁻ (aq) → PbI₂(s) + 2K⁺ (aq) + 2(NO₃)⁻ (aq)) is not the correct net ionic equation because it includes the spectator ions (K⁺ and NO₃⁻) that do not participate in the actual formation of the precipitate.

Option C (Pb²⁺ (aq) + I₂⁻(aq) → PbI₂(s)) is not the correct net ionic equation because it represents a direct combination of Pb²⁺ and I⁻ ions to form PbI₂, but in the given reaction, the iodide ions come from potassium iodide (KI), not from I₂.

Hence, D. is the correct option.

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Comparing these two scenarios, we can conclude that the order of the reaction with respect to Cl₂ is 1. Therefore, the correct answer is (D) 1.

To determine the order of the reaction with respect to Cl₂, we can use the information provided about the effect of concentration changes on the initial rate.

Let's analyze the given data:

When the initial concentrations of both reactants, NO and Cl₂, are tripled, the initial rate increases by a factor of 27. This indicates that the rate is proportional to the cube of the initial concentration of both reactants.

When only the initial concentration of Cl₂ is tripled, the initial rate increases by a factor of 3. This indicates that the rate is directly proportional to the initial concentration of Cl₂.

Comparing these two scenarios, we can conclude that the order of the reaction with respect to Cl₂ is 1.

Therefore, the correct answer is (D) 1.

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Diluting the solution with an additional 100 grams of water will increase the boiling point and decrease the freezing point of the solution.

When a solution is diluted with an additional 100 grams of water, the boiling point and freezing point of the solution will both be affected.

Boiling Point:

The addition of more water to the solution increases the total volume of the solution. As a result, the concentration of solute particles in the solution decreases. According to Raoult's law, the vapor pressure of the solvent above the solution is directly proportional to the mole fraction of the solvent in the solution.

With a decrease in the concentration of solute particles, the mole fraction of the solvent increases, leading to a decrease in the vapor pressure of the solution. As a consequence, the boiling point of the solution increases.

Therefore, when the solution is diluted with additional water, the boiling point of the solution will be higher compared to the original, more concentrated solution.

Freezing Point:

Similar to the boiling point, the addition of more water increases the total volume of the solution and decreases the concentration of solute particles. According to the colligative properties of solutions, such as the freezing point depression, a decrease in the concentration of solute particles leads to a decrease in the freezing point of the solution.

Hence, when the solution is diluted with additional water, the freezing point of the solution will be lower compared to the original, more concentrated solution.

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When an object is placed at a distance of 25 cm from the lens of focal length 20 cm, the image formed is virtual, erect and enlarged.

A virtual image is an image that appears to be behind the lens, and it is formed by light rays that do not actually pass through it but appear to diverge from it. The image is erect because it is the same size as the object, and it is enlarged because it is closer to the lens than the object.

The image formed by the first lens acts as the object for the second lens. The second lens has a focal length of 25 cm, and the final image is formed 60 cm past the second lens. Using the lens formula, the position of the image formed by the first lens is given by: 1/f = 1/v - 1/u Where f is the focal length of the lens, u is the object distance from the lens and v is the image distance from the lens.

Using the values given, we have: 1/20 = 1/v - 1/25So, 1/v = 1/20 + 1/25 = 9/1000v = 1000/9 = 111.11 cmThis means that the image formed by the first lens is 111.11 cm behind the first lens.

This image acts as the object for the second lens, and we can use the same formula to find the position of the final image. Using the same formula, we have: 1/25 = 1/v' - 1/111.11So, 1/v' = 1/25 + 1/111.11 = 4.84/1000v' = 1000/4.84 = 206.61 cm. Therefore, the final image is formed 206.61 cm past the first lens.

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The enthalpy change (ΔH°) for the given process, Co₃O₄ (s) → 3 Co (s) + 2 O₂ (g), is +891.2 kJ.

To calculate ΔH° for the given process using Hess's Law, we need to manipulate the provided equations and their enthalpy changes to obtain the reactions;

Reverse the first reaction; Coo (s) → Co (s) + 0.5 O₂ (g) with ΔH° = +237.9 kJ.

Multiply the first reaction by 3; 3 Coo (s) → 3 Co (s) + 1.5 O₂ (g) with ΔH° = 3 × (+237.9) kJ = +713.7 kJ.

Reverse the second reaction; Co₃O₄ (s) → 3 Coo (s) + 0.5 O₂ (g) with ΔH° = -(-177.5) kJ = +177.5 kJ.

Add the manipulated reactions together;

3 Coo (s) + 0.5 O2 (g) → 3 Co (s) + 1.5 O₂ (g) with ΔH° = +713.7 kJ

Co₃O₄ (s) → 3 Coo (s) + 0.5 O₂ (g) with ΔH° = +177.5 kJ

Cancel out the common species on both sides;

Co3O4 (s) → 3 Co (s) + O2 (g) with ΔH°

= +713.7 kJ + 177.5 kJ

= +891.2 kJ.

Therefore, the ΔH° is +891.2 kJ.

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The maximum wavelength of light required to break a chlorine-chlorine single bond is approximately 4.947 x 10⁻⁷ meters or 494.7 nm (nanometers), rounded to four significant digits.

We can use the relationship between energy, wavelength, and speed of light to determine the maximum wavelength of light necessary to break a chlorine-chlorine single bond.

The equation which gives the energy of a photon is:

E = hc/λ

where:

E is the photon's energy.

Planck's constant, h, is (6.626 x 10⁻³⁴ Js)

2.998 x 10⁸ m/s is the speed of light, or c.

λ is the wavelength of light

We are aware that a chlorine-chlorine single bond must be broken with 242 kJ/mol of energy. This can be changed to joules per molecule as follows:

[tex]242 kJ/mol = \frac{242 \times 10^3 J}{(6.022 \times 10^{23} molecules/mol)} \approx 4.015 \times 10^{-19} J/molecule[/tex]

The equation can now be rearranged to find the maximum wavelength:

λ = hc/E

Putting in the values:

[tex]\lambda = \frac {(6.626 \times 10^{-34} Js)(2.998 \times 10^8 m/s)}{(4.015 \times 10^{-19} J/molecule)}[/tex]

Calculating the result:

[tex]\lambda \approx 4.947 \times 10^{-7} meters[/tex]

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Approximately 4.44 × [tex]10^{26[/tex] photons of this microwave radiation must be absorbed to warm 250 mL of water from 23.1 ºC to its boiling point .

a. To calculate the energy of a single photon of microwave radiation, we can use the equation E = hc/λ, where E is the energy of the photon, h is Planck's constant (6.626 × 10^-34 J·s), c is the speed of light (2.998 × 10^8 m/s), and λ is the wavelength of the radiation.

Converting the wavelength to meters, we have λ = 12.2 cm = 0.122 m.

Using the equation, E = (6.626 × 10^-34 J·s × 2.998 × 10^8 m/s) / 0.122 m = 1.632 × 10^-24 J.

Therefore, the energy of a single photon of this microwave radiation is 1.632 × 10^-24 J.

b. To calculate the number of photons required to warm 250 mL of water, we need to determine the heat energy required to raise the temperature from 23.1 ºC to its boiling point (100 ºC). The heat energy can be calculated using the formula Q = mcΔT, where Q is the heat energy, m is the mass of water, c is the specific heat capacity of water (4.184 J/g·ºC), and ΔT is the change in temperature.

First, we need to convert the mass of water to grams. Since 1 mL of water is approximately equal to 1 gram, 250 mL of water is equal to 250 grams.

Next, we calculate the heat energy:

Q = (250 g) × (4.184 J/g·ºC) × (100 ºC - 23.1 ºC) = 723,280 J.

To find the number of photons, we divide the total energy (723,280 J) by the energy of a single photon:

Number of photons = 723,280 J / (1.632 ×[tex]10^{-24[/tex] J) ≈ 4.44 × 10^26 photons.

Converting the wavelength to meters, we have λ = 12.2 cm = 0.122 m.

Using the equation, E = (6.626 × [tex]10^{-34[/tex] J·s × 2.998 × [tex]10^8[/tex] m/s) / 0.122 m = 1.632 × [tex]10^{-24[/tex] J.

Therefore, the energy of a single photon of this microwave radiation is 1.632 × [tex]10^{-24[/tex] J.

b. To calculate the number of photons required to warm 250 mL of water, we need to determine the heat energy required to raise the temperature from 23.1 ºC to its boiling point (100 ºC). The heat energy can be calculated using the formula Q = mcΔT, where Q is the heat energy, m is the mass of water, c is the specific heat capacity of water (4.184 J/g·ºC), and ΔT is the change in temperature.

First, we need to convert the mass of water to grams. Since 1 mL of water is approximately equal to 1 gram, 250 mL of water is equal to 250 grams.

Next, we calculate the heat energy:

Q = (250 g) × (4.184 J/g·ºC) × (100 ºC - 23.1 ºC) = 723,280 J.

To find the number of photons, we divide the total energy (723,280 J) by the energy of a single photon (1.632 × [tex]10^{-24[/tex] J):

Number of photons = 723,280 J / (1.632 × [tex]10^{-24[/tex] J) ≈ 4.44 × [tex]10^{26[/tex] photons.

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Answer: Exploratorium Senior Scientist Paul Doherty explains why not—the orbit of the moon is tilted relative to the orbit of the Earth around the sun, so the moon often passes below or above Earth. At those times, it does not cross the line between the sun and the Earth, and therefore does not create a solar eclipse.

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(a) The expression for the pressure gradient in the x direction is given by -∂p/∂x = ρ(u∂u/∂x) - μ(∂[tex]^2u[/tex]/∂x[tex]^2)[/tex].

(b) The combination of constants a, b, and c

To determine the expression for the pressure gradient in the x-direction using the Navier-Stokes equations, we start by writing the x-component of the Navier-Stokes equation for an incompressible flow with zero body forces:

ρ(∂u/∂t + u∂u/∂x + v∂u/∂y + w∂u/∂z) = -∂p/∂x + μ(∂[tex]^2u[/tex]/∂[tex]x^2[/tex] + ∂[tex]^2u[/tex]/∂[tex]y^2[/tex] + ∂[tex]^2u[/tex]/∂[tex]z^2[/tex])

where ρ is the fluid density,

u, v, and w are the velocity components in the x, y, and z directions respectively,

t is time, p is pressure,

μ is the dynamic viscosity,

and (∂/∂x) and (∂[tex]^2/[/tex]∂[tex]x^2[/tex]) denote partial derivatives with respect to x.

Given the velocity components u and v provided, we can see that v and w are both zero. Therefore, the x-component of the Navier-Stokes equation simplifies to:

ρ(∂u/∂t + u∂u/∂x) = -∂p/∂x + μ(∂[tex]^2u[/tex]/∂[tex]x^2)[/tex]

Since the flow is steady (there is no time dependence) and we are interested in the expression for the pressure gradient (∂p/∂x), we can neglect the (∂u/∂t) term.

The equation then becomes:

ρ(u∂u/∂x) = -∂p/∂x + μ(∂[tex]^2u[/tex]/∂[tex]x^2[/tex])

Rearranging the terms, we get:

-∂p/∂x = ρ(u∂u/∂x) - μ(∂[tex]^2u[/tex]/∂[tex]x^2[/tex])

Now, let's address part (b) of the question. We are looking for a combination of constants a, b, and c that will make the shearing stress,  τ[tex]_{xyz},[/tex] zero at y = 0 where the velocity is zero.

The shearing stress τ[tex]_{xyz}[/tex] is given by:

τ[tex]_{xyz}[/tex]= μ(∂u/∂y + ∂v/∂x)

Since v is zero and we are interested in the point y = 0, the expression simplifies to:

τ[tex]_{xyz}[/tex] = μ(∂u/∂y)

Evaluating this expression at y = 0, we have:

τ_xyz|y=0

           = μ(∂u/∂y)|y

           =0

Given u = ay - b(cy - [tex]y^2[/tex]), we can find (∂u/∂y)|y=0 by taking the partial derivative with respect to y and evaluating it at y = 0:

(∂u/∂y)|y=0

             = a - b(c - 2y)|y

             =0

            = a - b(c - 0)

            = a - bc

Therefore, for the shearing stress to be zero at y = 0, we need:

τ[tex]_{xyz}[/tex]|y=0

        = μ(∂u/∂y)|y

        =0

This implies that a - bc = 0, or a = bc.

In summary:

(a) The expression for the pressure gradient in the x direction is given by

-∂p/∂x = ρ(u∂u/∂x) - μ(∂[tex]^2u[/tex]/∂x[tex]^2)[/tex].

(b) The combination of constants a, b, and c

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Difference of 0.37 represents a difference of 10^(0.37) = 2.28 times more acidity in the rain falling in New England than in the rain produced by the weather system moving through the American Midwest.

In order to calculate the pH of a 1.67 × 10–2 M solution of aminoethanol, we need to make use of the acid dissociation constant (Ka) of the acid H2A:H2A (aq) ⇌ H+ (aq) + HA– (aq)Ka = [H+][HA–] / [H2A]pH = pKa + log ([A–] / [HA])At equilibrium, [H2A] = [A–] + [H+]Aminoethanol is an amphoteric compound, and can act as both an acid and a base. When dissolved in water, it undergoes the following equilibrium:Aminoethanol + H2O ⇌ NH3+CH2CH2OH + OH–Applying the acid dissociation constant of water and simplifying the expression:NH3+CH2CH2OH ⇌ NH3+ + CH2CH2OH–Ka = Kw / KbKb = Kw / KaBases are defined as substances that accept protons (H+), so the conjugate base of aminoethanol is NH2CH2CH2O–:NH2CH2CH2OH + H+ ⇌ NH3+CH2CH2OHThe pKa of NH3+CH2CH2OH is 9.69, so the Kb of NH2CH2CH2O– can be calculated:pKa + pKb = pKw14.00 + pKb = 14.00Kb = 4.16 × 10–6The concentration of OH– can be calculated from the Kb value:Kb = [OH–][NH3+CH2CH2OH] / [NH2CH2CH2O–][OH–] = Kb[NH2CH2CH2O–] / [NH3+CH2CH2OH][OH–] = Kb[NH2CH2CH2O–] / [NH3+CH2CH2OH] = (4.16 × 10–6)(1.67 × 10–2) / (1.67 × 10–2) = 4.16 × 10–8pOH = –log[OH–] = –log(4.16 × 10–8) = 7.38pH + pOH = 14.00pH = 14.00 – 7.38 = 6.62The pH of the solution is 6.62.b. To calculate the OH– concentration in a 4.25 × 10–4 M solution of aminoethanol, we can use the same approach as in part a, but we need to use the concentration value given and solve for [OH–]:NH3+CH2CH2OH + H2O ⇌ NH3+ + CH2CH2OH–Kb = Kw / KaKb = [OH–][NH3+CH2CH2OH] / [NH2CH2CH2O–][OH–] = Kb[NH2CH2CH2O–] / [NH3+CH2CH2OH][OH–] = Kb[NH2CH2CH2O–] / [NH3+CH2CH2OH] = (4.16 × 10–6)(4.25 × 10–4) / (4.25 × 10–4) = 4.16 × 10–8pOH = –log[OH–] = –log(4.16 × 10–8) = 7.38pH + pOH = 14.00pH = 14.00 – 7.38 = 6.62The OH– concentration in the solution is 4.16 × 10–8 M.c. The difference in pH between the two rain samples is 5.04 – 4.67 = 0.37.The pH scale is logarithmic, so a difference of 1.0 in pH represents a tenfold difference in acidity. Therefore, a difference of 0.37 represents a difference of 10^(0.37) = 2.28 times more acidity in the rain falling in New England than in the rain produced by the weather system moving through the American Midwest.

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The laboratory procedure best illustrates the law of conservation of mass is  Option c "Burning 2.4 g of Mg in an open crucible to produce 2 g of MgO and unused reactants"

According to the law of conservation of mass, within an isolated system, mass remains constant and cannot be generated or annihilated, but rather undergoes transformations from one state to another.

For instance, by subjecting 32 grams of sulfur (S) and 56 grams of iron (Fe) to heat, they combine to form 88 grams of iron sulfide (FeS) alongside any unreacted starting materials.

Hence, the cumulative mass of the reactants, namely 32 grams of sulfur and 56 grams of iron, adds up to 88 grams, which aligns with the combined mass of the resultant product.

In this manner, it becomes evident that mass is neither eradicated nor brought into existence; rather, it seamlessly converts from one manifestation to another.

Consequently, the example involving the heating of 32 grams of sulfur and 56 grams of iron to yield 88 grams of iron sulfide, along with any remaining unreacted substances, aptly exemplifies the principle of the conservation of mass.

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Complete question:

Which of the following laboratory procedures best illustrates the law of conservation of mass?

a. Calculating the number of atoms in 11 g of Na

Using 250 g of impure Cu to obtain 200 g of pure Cu

b. Heating 32 g of S and 56 g of Fe to produce 88 g of FeS and unused reactants

c. Burning 2.4 g of Mg in an open crucible to produce 2 g of MgO and unused reactants

Answer: B

Explanation:

B. It is correct because iron is more reactive than silver [1]. When iron (III) nitrate solution comes in contact with silver, the iron ions and silver ions will exchange. The more reactive metal will displace the less reactive metal from its compound. In this case, iron is more reactive than silver, so iron ions will displace silver ions from silver nitrate to form iron nitrate and silver. This reaction will produce iron nitrate and silver as products [2][3].

The prediction made by Niko, stating that iron and silver nitrate will form when silver is placed into an iron (III) nitrate solution, is incorrect. This is because silver is less reactive than iron, and the reaction should not produce iron and silver nitrate as products.

The prediction made by Niko is incorrect. When evaluating the reactivity of metals, it is important to consider the reactivity series. The reactivity series ranks metals based on their tendency to undergo redox reactions. In the reactivity series, iron is typically more reactive than silver.

Iron (III) nitrate is a compound consisting of iron ions  and nitrate ions . Silver nitrate, on the other hand, consists of silver ions and nitrate ions . When silver is placed into an iron (III) nitrate solution, a single replacement reaction can occur. However, since silver is less reactive than iron according to the reactivity series, it cannot displace iron from its compound.

Instead, if a reaction occurs, it would involve the displacement of silver by iron, resulting in the formation of iron nitrate and the deposition of silver metal. The correct prediction would be that iron displaces silver, not the formation of iron and silver nitrate as suggested by Niko.

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The authors of the research paper "Molecular Anatomy of a Trafficking Organelle" (Cell, 2006, Vol. 127; 831–846) chose to examine synaptic vesicles due to their crucial role in neuronal communication and synaptic transmission.

Synaptic vesicles are specialized organelles found in neurons that store and release neurotransmitters, which are essential for transmitting signals between nerve cells. They play a vital role in synaptic transmission, a fundamental process underlying brain function. The authors likely chose to focus on synaptic vesicles because understanding their molecular anatomy and trafficking mechanisms is crucial for unraveling the intricate processes involved in neuronal communication.

By studying synaptic vesicles, researchers can gain insights into how these vesicles are formed, transported, and targeted to specific regions within neurons. Investigating the molecular components and mechanisms involved in synaptic vesicle trafficking can provide valuable knowledge about neuronal function, synaptic plasticity, and neurotransmission. Furthermore, studying synaptic vesicles can contribute to our understanding of various neurological disorders associated with synaptic dysfunction, such as Alzheimer's disease, Parkinson's disease, and epilepsy. Therefore, the choice to examine synaptic vesicles in this research paper was likely driven by their significance in neuronal physiology and their potential implications for understanding and treating neurological disorders.

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Answer:

ruthenium (Ru), rhodium (Rh), palladium (Pd), osmium (Os), iridium (Ir), platinum (Pt), gold (Au), silver (Ag).

Explanation:

The term "Noble Metals" traditionally refers to a group of metals that are resistant to corrosion and oxidation in moist or chemically aggressive environments. The elements commonly considered noble metals are Gold, Platinum, Palladium, Palladium, etc.

Gold is perhaps the most well-known noble metal. It is highly resistant to corrosion and oxidation. Platinum is another widely recognized noble metal. It is extremely resistant to corrosion and has a high melting point.

Palladium is a noble metal that exhibits excellent chemical stability and resistance to corrosion.

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The statement that corresponds to the drawing of a girl in a record store with headphones on is " Ella oye música." The correct statement is B.

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extracting energy from nuclear fuels is more expensive than extracting energy from fossil fuels

Answer:

a. i. 5.092 × 10²⁰ Hz ii. 588.98554 nm ii. 10667809.11 rad/m

b. i. 5.087 × 10²⁰ Hz ii. 589.58286 nm iii. 10657001.3 rad/m

Explanation:

refractive index, n = λ/λ'  where λ = wavelength in vacuum = and λ' = wavelength in air

a. For λ = 589.15788 nm,

i. Frequency,

f = c/λ where c = speed of light in vacuum = 3 × 10⁸ m/s and λ = 589.15788 nm = 589.15788 × 10⁻⁹ m

So, f = 3 × 10⁸ m/s ÷ 589.15788 × 10⁻⁹ m

= 0.005092 × 10¹⁷ /s

= 5.092 × 10²⁰ /s

= 5.092 × 10²⁰ Hz

ii. Wavelength,

Since n = λ/λ'  where λ = wavelength in vacuum = and λ' = wavelength in air

and n = 1.0002926

λ' = λ/n

= 589.15788 nm/1.0002926

= 588.98554 nm

k = 2π/λ'

= 2π/588.98554 nm

= 0.01066780911 rad/nm

= 0.01066780911 rad/nm × 10⁹ nm/1m

= 10667809.11 rad/m

b. For λ = 589.755 37 nm.,

i. Frequency,

f = c/λ where c = speed of light in vacuum = 3 × 10⁸ m/s and λ = 589.755 37 nm. = 589.755 37 × 10⁻⁹ m

So, f = 3 × 10⁸ m/s ÷ 589.755 37 × 10⁻⁹ m

= 0.005087 × 10¹⁷ /s

= 5.087 × 10²⁰ /s

= 5.087 × 10²⁰ Hz

ii. Wavelength,

Since n = λ/λ'  where λ = wavelength in vacuum = and λ' = wavelength in air

and n = 1.0002926

λ' = λ/n

= 589.755 37 nm./1.0002926

= 589.58286 nm

k = 2π/λ'

= 2π/589.58286 nm

= 0.0106570013 rad/nm

= 0.0106570013  rad/nm × 10⁹ nm/1m

= 10657001.3 rad/m

When more than one gas is present in a container, each gas exerts pressure, which is known as partial pressure. The partial pressure refers to the pressure of any gas inside the container. The partial pressure of the helium in kpa is 101.

Partial pressure is the pressure that one gas in a gas mixture will exert if it occupies the same volume on its own. In a mixture, every gas exerts a particular pressure. The partial pressures of the various gases in a mixture of an ideal gas add up to its total pressure.

The overall pressure exerted by a mixture of gases is equal to the sum of the partial pressures, according to Dalton's law of partial pressures.

P total= P₁ + P₂ + P₃ …

Here,

205 = pf + pCl + pHe

pHe = 205 - (pf + pCl)

pHe = 205 - (89+15) = 101 kpa

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The aqueous solutions of the following salts are:

(a) [tex]K_2CO_3[/tex]: Basic

(b) [tex]CaCl_2[/tex]: Neutral

(c) [tex]KH_2PO_4[/tex]: Acidic

(d) [tex](NH_4)_2CO_3[/tex]: Acidic

(a) [tex]K_2CO_3[/tex]:

The cation, [tex]K^+[/tex] (potassium ion), is derived from a strong base (KOH), which does not hydrolyze in water. Therefore, it does not contribute to the acidity or basicity of the solution. The anion, [tex]CO_3^{2-[/tex] (carbonate ion), is derived from a weak acid [tex]H_2CO_3[/tex], which can hydrolyze in water.

The hydrolysis of [tex]CO_3^{2-[/tex] can be represented as follows:

[tex]CO_3^{2-} + H_2O[/tex] ⇌ [tex]HCO_3^- + OH^-[/tex]

Since the hydrolysis of [tex]CO_3^{2-[/tex] results in the formation of [tex]OH^-[/tex] ions, the solution will be basic.

(b) [tex]CaCl_2[/tex]:

Both the cation, [tex]Ca_2^+[/tex] (calcium ion), and the anion, [tex]Cl^-[/tex] (chloride ion), are derived from strong acids and bases (HCl and [tex]Ca(OH)_2[/tex]). As a result, they do not undergo hydrolysis in water. Therefore, the solution will be neutral.

(c) [tex]KH_2PO_4[/tex]:

The cation, [tex]K_+[/tex] (potassium ion), does not undergo hydrolysis in water. The anion, [tex]H_2PO_4^-[/tex] (dihydrogen phosphate ion), can hydrolyze in water.

The hydrolysis of [tex]H_2PO_4^-[/tex] can be represented as follows:

H2PO4- + H2O ⇌ [tex]HPO_4^{2-} + H_2PO_4^- + H_3O^+[/tex]

Since the hydrolysis of [tex]H_2PO_4^-[/tex] results in the formation of [tex]H_3O^+[/tex] ions, the solution will be acidic.

(d) [tex](NH_4)_2CO_3[/tex]:

Both the cation, [tex]NH_4^+[/tex] (ammonium ion), and the anion, [tex]CO_3^{2-[/tex] (carbonate ion), can hydrolyze in water.

The hydrolysis of [tex]NH_4^+[/tex] can be represented as follows:

[tex]NH_4^+ + H_2O[/tex] ⇌ [tex]NH_3 + H_3O^+[/tex]

Since the hydrolysis of [tex]NH_4^+[/tex] results in the formation of [tex]H_3O^+[/tex] ions, the solution will be acidic.

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Answer:

a

Explanation:

i am wrong haha

Answer:

are u out of time ?

Explanation:

Oxygen is likely to decrease in a small, shallow tide pool at low tide.

When the tide goes out, the water in a tide pool becomes shallower and more exposed to the sun. This causes the water to heat up and the oxygen levels to decrease. The decrease in oxygen can be harmful to the organisms that live in the tide pool, as they need oxygen to survive.

The other properties are not likely to decrease in a small, shallow tide pool at low tide. Carbon dioxide levels may increase as the water heats up, but they are not likely to decrease.

Temperature is likely to increase, not decrease. Acidity is not likely to change significantly. Salinity is also not likely to change significantly.

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Answer:

5.56 × 10^23 molecules

Explanation:

The number of molecules in a molecule can be calculated by multiplying the number of moles in that molecule by Avagadro's number (6.02 × 10^23)

Using mole = mass/molar mass

Molar mass of N2O4 = 14(2) + 16(4)

= 28 + 64

= 92g/mol

mole = 85.0/92

= 0.9239

= 0.924mol

number of molecules of N2O4 (nA) = 0.924 × 6.02 × 10^23

= 5.56 × 10^23 molecules

Answer:

CuCl₂ is the excessive reactant and NaNO₃ the limiting reactant, 13.7g of NaCl can be formed.

Explanation:

Based on the reaction:

CuCl₂ + 2NaNO₃ → 2NaCl + Cu(NO₃)₂

To solve the problem we must convert the mass of each reactant in order to find limiting reactant as follows:

Moles CuCl₂ -Molar mass: 134.45g/mol-:

35g * (1mol / 134.45g) = 0.26 moles

Moles NaNO₃ -Molar mass: 84.99g/mol-:

20g * (1mol / 84.99g) = 0.235 moles

For a complete reaction of 0.235 moles of NaNO₃ there are required:

0.235 moles NaNO₃ * (1 mol CuCl₂ / 2 mol NaNO₃) = 0.118 moles CuCl₂

As there are 0.26 moles CuCl₂,

As 2 moles of NaNO₃ produce 2 moles of NaCl, he moles of NaCl produced are: 0.235 moles NaCl. The mass is:

Mass NaCl -Molar mass: 58.44g/mol-:

0.235 moles NaCl * (58.44g / mol) =

The expected hybridization of the central atom varies depending on the molecular geometry of the molecule or ion.

(a) NO3− - sp2 hybridization

(b) CCl4 - sp3 hybridization

(c) NCl3 - sp3 hybridization

(d) NO2− - sp2 hybridization

(e) OCN− (carbon is the central atom) - sp hybridization

(f) SeCl2 - sp3 hybridization

(a) NO3−:

The central atom in NO3− is nitrogen (N). Nitrogen is bonded to three oxygen (O) atoms. The nitrogen atom forms three sigma bonds with the three oxygen atoms, resulting in a trigonal planar molecular geometry. In a trigonal planar geometry, the nitrogen atom is sp2 hybridized.

(b) CCl4:

The central atom in CCl4 is carbon (C). Carbon is bonded to four chlorine (Cl) atoms. The carbon atom forms four sigma bonds with the four chlorine atoms, resulting in a tetrahedral molecular geometry. In a tetrahedral geometry, the carbon atom is sp3 hybridized.

(c) NCl3:

The central atom in NCl3 is nitrogen (N). Nitrogen is bonded to three chlorine (Cl) atoms. The nitrogen atom forms three sigma bonds with the three chlorine atoms, resulting in a trigonal pyramidal molecular geometry. In a trigonal pyramidal geometry, the nitrogen atom is sp3 hybridized.

(d) NO2−:

The central atom in NO2− is nitrogen (N). Nitrogen is bonded to two oxygen (O) atoms and has one lone pair of electrons. The nitrogen atom forms two sigma bonds with the two oxygen atoms, resulting in a bent molecular geometry. In a bent geometry, the nitrogen atom is sp2 hybridized.

(e) OCN− (carbon is the central atom):

The central atom in OCN− is carbon (C). Carbon is bonded to an oxygen (O) atom, a carbon (C) atom, and has one lone pair of electrons. The carbon atom forms two sigma bonds with the oxygen and carbon atoms, resulting in a linear molecular geometry. In a linear geometry, the carbon atom is sp hybridized.

(f) SeCl2:

The central atom in SeCl2 is selenium (Se). Selenium is bonded to two chlorine (Cl) atoms and has two lone pairs of electrons. The selenium atom forms two sigma bonds with the two chlorine atoms, resulting in a bent molecular geometry. In a bent geometry, the selenium atom is sp3 hybridized.

The expected hybridization of the central atom varies depending on the molecular geometry of the molecule or ion. The hybridization determines the arrangement of the atomic orbitals and is related to the geometry of the molecule.

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Answer:

dfdfaxc b

Explanation:

Answer: See explanation

Explanation:

The sun is a star that's made up of several gases. It is known to be the most vital source of energy to living things.

Despite the importance of the sun in our lives, it's still harmful when one is exposed to it. They rays of light that's given our by the sun can be harmful to us.

Being exposed to the sun can cause sunburn and this can result in the damage of skin cells and development of cancer. Also, sunlight can lead to early aging as the skin ages faster when one is exposed to the sun.

Furthermore, exposure to sunlight can lead to eye injuries the tissue in our eyes can be damaged by the UV rays. Lastly, it also brings about lowered immune system.

Answer:

The Answer is gonna be C. the same amount in nuclear fusion reactions as it is in chemical reactions