The chemical equation below shows the decomposition of nitrogen triiodide (NI3) into nitrogen (N2) and iodine (I2). 2NI3 mc030-1.jpg N2 + 3I2 The molar mass of I2 is 253.80 g/mol, and the molar mass of NI3 is 394.71 g/mol. How many moles of I2 will form 3.58 g of NI3?

the answer is USA and Russia

Ans: B) United States and Russia

Energy sources can be broadly classified into two categories: Renewable and non-renewable sources.

Renewable sources are those that can be naturally replenished like, solar energy, wind, hydrothermal etc

In contrast, non-renewable sources of energy are a finite resources and cannot be replenished. Fossil fuels like coal, oil, gas are all non-renewable sources. Coal is the most widely used source of energy with the United States and Russia being the two countries that have nearly 50% of the global coal reserves.

The pressure of a refrigerant cylinder containing saturated refrigerant is primarily determined by the temperature and the density of the refrigerant, according to the Clausius-Clapeyron equation. Other factors include the vaporization-condensation equilibrium and the sum of hydrostatic and atmospheric pressures.

The pressure of a refrigerant cylinder containing saturated refrigerant is determined by several factors, but primarily by the temperature and the density of the refrigerant. This is according to the Clausius-Clapeyron equation, which describes the relationship between a substance's vapor pressure and its temperature.

In scenarios involving supercritical fluids, such as a sample of water in a sealed container at a specific temperature, the pressure is determined by the vaporization-condensation equilibrium. This leaves us with a mixture of liquid and vapor, and a distinct pressure determined by the dense liquid and the less dense gas.

In addition, the pressure of a gas (assuming it behaves ideally) is also influenced by the hydrostatic pressure in the cylinder plus both the pressure of the vapour (due to vapor pressure of water) and the atmospheric pressure. An example would be a gas exerting pressure in a column of mercury, where the total pressure is the sum of the hydrostatic pressure due to the column of mercury and atmospheric pressure.

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According to law of conservation of mass, equal masses have the same velocity, hence both the cars have the same velocity.

According to law of conservation of mass, it is evident that mass is neither created nor destroyed rather it is restored at the end of a chemical reaction .

Law of conservation of mass and energy are related as mass and energy are directly proportional which is indicated by the equation E=mc².Concept of conservation of mass is widely used in field of chemistry, fluid dynamics.In chemical reactions, mass is always conserved.

Law needs to be modified in accordance with laws of quantum mechanics under the principle of mass and energy equivalence.This law was proposed by Antoine Lavoisier in the year 1789.

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At standard temperature and pressure, burning hydrogen gas reacts with oxygen to produce water vapor in a ratio where 12 liters of oxygen would produce 24 liters of water vapor, according to the stoichiometric relationship in the chemical equation.

When hydrogen burns, water vapor is produced according to the balanced chemical equation . This tells us that 2 volumes of hydrogen react with 1 volume of oxygen to produce 2 volumes of water vapor. Therefore, if 12 liters of oxygen are consumed at STP (standard temperature and pressure), an equivalent stoichiometric ratio would apply, and hence 24 liters of water vapor would be produced, because the ratio of oxygen to water vapor in the equation is 1:2.

Coal is considered a fossil fuel because it originates from the remains of plants that lived 300 to 400 million years ago. Over time, these plant remains were subjected to high pressure and temperature, transforming them into a carbon-rich fuel source called coal. The burning of coal as an energy source releases significant amounts of CO2.

Coal is categorized as a fossil fuel due to its origins. It was formed from the remains of trees, ferns, and other plant life that lived 300 to 400 million years ago. These organic materials, over time and under the pressure of overlying sediment, were transformed into a carbon-rich material known as coal.

Primarily, during the Carboniferous period, plants underwent rapid growth in swampy areas. After their life cycle, these plants do not entirely decompose and rot, but instead, create peat. As additional layers of sediment build-up and the heat and pressure increase, this peat gradually transforms into different types of coal, namely lignite, sub-bituminous coal, bituminous coal, and anthracite. This process of coal formation is known as coalification.

A key aspect of fossil fuels like coal is their high carbon content. When burned, they release significant amounts of energy, which makes them valuable resources for electricity generation and industrial processes. However, the combustion of coal also releases large amounts of CO2, a significant contributor to global warming.

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Answer:

The relationship between initial temperature and final temperature is 2.

Explanation:

The reaction of:

HCl + NaOH → H₂O + NaCl + ΔH

Produce heat (ΔH). This heat is evidenced in the increasing of temperature in the system.

If you add 100 mL of 0,50M of both NaOH and HCl you will produce heat, that increase the temperature of the system in X°C.

Now, the addition of 200mL of 0,50M of both NaOH and HCl will produce twice the initial heat increasing the temperature of the system in 2X°C.

That means the relationship between initial temperature and final temperature is 2.

I hope it helps!

The correct statement from the given list of statements would be a rock will weigh more on Earth than on the moon, therefore the correct answer is option B.

Newton's Second Law states that The resultant force acting on an object is proportional to the rate of change in momentum.

The weight of any object uses the multiplication of the Mars and the gravity of the respective planet in our case the weight is measured with respect to the gravity of the earth

Weight  = Mass × (acceleration due to gravity)

As given in the problem mem we have to find the correct statement from the given list of the statements.

The acceleration due to gravity is greater on the earth as compared to the moon.

Thus, a rock will weigh more on Earth than on the moon, therefore the correct answer is option B.

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The number of electrons that can have a quantum number of n = 2 in an atom is eight. This total includes two electrons in the 2s subshell and six electrons in the 2p subshell.

The number of electrons that can have a quantum number of n = 2 in an atom is determined by the possible sets of quantum numbers for the n = 2 shell and the number of electrons the subshells can accommodate. Given n = 2 for the shell, the rules for quantum numbers limit ℓ (the angular momentum quantum number) to be 0 or 1. There are two subshells for n = 2, which are the 2s and 2p subshells.

The 2s subshell (ℓ = 0) can have two electrons, one with spin projection +1/2 and one with -1/2. The 2p subshell (ℓ = 1) has three possible values for the magnetic quantum number, mℓ, which are -1, 0, and +1. Since each of these can be paired with two possible spins, +1/2 and -1/2, this means there can be six electrons in the 2p subshell (2(2ℓ + 1) where ℓ = 1). Combining the capacities of the two subshells, the n = 2 shell can hold a total of eight electrons.

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To calculate how much energy 20 grams of water needs to increase its temperature from 283 °C to 303 °C, we can use the Heat Transfer equation. After converting the temperature to Kelvin and performing the calculation, we find that the water needs to absorb 1673.6 Joules of energy.

To calculate how much energy must be absorbed for water to increase its temperature, we can use the formula for Heat Transfer: Q = mcΔT. Where Q is the heat transferred, m is the mass of the object (water in this case), c is the specific heat capacity of the substance, and ΔT is the change in temperature. For water, the specific heat capacity (c) is 4.184 J/g °C.

First, we need to convert the temperature from Celsius to Kelvin by adding 273 to each temperature: 283 °C becomes 556 K and 303 °C becomes 576 K. The change in temperature (ΔT) is the final temperature minus the initial temperature (576 K - 556 K = 20 K).

Therefore, the heat equation becomes: Q = (20 g)(4.184 J/g °C)(20 K).

Calculating this gives Q = 1673.6 Joules. So, the water needs to absorb 1673.6 Joules of energy to increase its temperature from 283 °C to 303 °C.

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The energy required to increase the temperature of 20 grams of water from 283°C to 303°C can be calculated using the specific heat formula. By inserting the known values into the formula, it was determined that the process requires an input of 1673.6 Joules.

To work out the energy absorbed by water to increase its temperature, you need to use the heat capacity or specific heat formula q = mcΔT. Here, 'q' is the heat energy absorbed or released, 'm' is the mass of the substance, 'c' is the specific heat, and 'ΔT' is the change in temperature.

In the question, the mass 'm' is 20 grams of water, and the change in temperature 'ΔT' is the difference between final and initial temperatures, 303°C - 283°C = 20°C. From the reference provided, the specific heat 'c' for water is 4.184 J/g °C. Substituting these values into the formula, we get:

q = (20 g) x (4.184 J/g °C) x (20 °C) = 1673.6 J.

Therefore, 1673.6 Joules of energy must be absorbed by 20.0 grams of water to increase its temperature from 283°C to 303°C.

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a minimum amount of [tex]\(56.67 \, \text{mL}\)[/tex] of water to dissolve [tex]\(51 \, \text{g}\)[/tex] of [tex]\(NaNO_3\)[/tex] at [tex]\(40^\circ \text{C}\)[/tex].

To find the minimum amount of water needed to dissolve [tex]\(51 \, \text{g}\)[/tex] of [tex]\(NaNO_3\)[/tex] at [tex]\(40^\circ \text{C}\)[/tex], we can use the solubility of [tex]\(NaNO_3\)[/tex] in water at that temperature.

At [tex]\(40^\circ \text{C}\)[/tex], the solubility of [tex]\(NaNO_3\)[/tex] is approximately [tex]\(90.0 \, \text{g}\) per \(100 \, \text{mL}\)[/tex] of water.

Given that you have [tex]\(51 \, \text{g}\)[/tex] of [tex]\(NaNO_3\)[/tex], you can set up a proportion to find out how much water would be needed to dissolve it:

[tex]\[\frac{51 \, \text{g}}{x \, \text{mL}} = \frac{90.0 \, \text{g}}{100 \, \text{mL}}\][/tex]

Where x represents the volume of water needed.

Solving for x:

[tex]\[x = \frac{51 \, \text{g} \times 100 \, \text{mL}}{90.0 \, \text{g}}\][/tex]

[tex]\[x = 56.67 \, \text{mL}\][/tex]

So, you would need a minimum of [tex]\(56.67 \, \text{mL}\)[/tex] of water to dissolve [tex]\(51 \, \text{g}\)[/tex] of [tex]\(NaNO_3\)[/tex] at [tex]\(40^\circ \text{C}\)[/tex].

The mass of a piece of aluminum with a volume of 264 mL and a density of 2.70 g/mL is calculated to be 712.8 grams.

To calculate the mass of a piece of aluminum with a volume of 264 mL when the density of aluminum is 2.70 g/mL, use the formula:

mass = density × volume

Here, the density (ρ) is given as 2.70 g/mL, and the volume (V) is 264 mL. Plugging these values into the formula gives us:

mass = 2.70 g/mL × 264 mL

When you do the calculation, the result is:

mass = 712.8 grams

Therefore, the mass of the piece of aluminum is 712.8 grams.

The mass of the piece of aluminum is 712.8 grams.

The density (p) is defined as mass (m) divided by volume (V). The formula is:

p = m / V

Given:

Density of aluminum, p = 2.70 g/mL

Volume of aluminum, V = 264 mL

To find the mass (m), rearrange the formula to solve for m:

m = p . V

Now, substitute the given values into the equation:

m = 2.70 g/mL × 264 mL

m = 712.8 g

Final answer:

The hybrid orbital set used by the central atom in NO3- is sp2 hybridization. In sp2 hybridization, the nitrogen atom combines one 2s orbital and two 2p orbitals to form three sp2 hybrid orbitals. These sp2 hybrid orbitals on the nitrogen atom overlap with the p orbitals of the oxygen atoms to form sigma bonds, resulting in the formation of a trigonal planar molecule.

Explanation:

The hybrid orbital set used by the central atom in NO3- is sp2 hybridization.

In NO3- (nitrate ion), the central atom is nitrogen (N) surrounded by three oxygen (O) atoms. According to VSEPR theory, the electron-pair geometry around the central nitrogen atom is trigonal planar, which corresponds to sp2 hybridization. In sp2 hybridization, the nitrogen atom combines one 2s orbital and two 2p orbitals to form three sp2 hybrid orbitals, which are arraned in a trigonal planar geometry.

These sp2 hybrid orbitals on the nitrogen atom overlap with the p orbitals of the oxygen atoms to form sigma bonds, resulting in the formation of a trigonal planar molecule.

Ionic compounds are generally solid at room temperature with high melting and boiling points. They are water soluble and can conduct electricity when melted or dissolved in water.

The physical state of nearly all ionic compounds at room temperature is solid. These substances are generally made up of a representative unit comprising a metal cation and a nonmetal anion arranged in a crystal lattice structure. Ionic compounds, such as sodium chloride, have high melting and boiling temperatures, indicating that a significant amount of energy is required to break the ionic bonds within the crystal lattice. For instance, sodium chloride melts at 801 0C and boils at 1413 0C.

These compounds are typically water soluble, which means they can dissolve in water, dissociating into their respective ions. Furthermore, ionic compounds in solid form do not conduct electricity, but they become electrically conductive when melted or dissolved in water, as the ions are free to move.

At a neutral pH of 7, the amino acid exists in the zwitterionic form, with a positive charge on the nitrogen of the amino group and a negative charge on the oxygen of the carboxyl group. This is due to the molecule's ability to accept or donate protons.

The structure of a molecule at a certain pH is affected by the molecule's ability to accept or donate protons. Amino acids, which are the molecule in question here, contain both carboxyl (-COOH) and amino (-NH2) groups. These groups can either donate or accept protons, depending on the pH of the environment.

At a pH less than 7, the environment is acidic and has a high concentration of protons. The carboxyl group tends to donate a proton and exist as COO-, while the amino group attracts protons and forms NH3+.

At pH 7, the environment is neutral. In this condition, amino acids usually exist in the zwitterionic (dipolar) form, where the carboxyl group is COO- and the amino group is NH3+.

At pH greater than 7, the environment is basic with a lower concentration of protons. Here, the amino group tends to donate a proton and exist mostly as NH2, while the carboxyl group remains COO-.

So, at pH 7, the predominant form of an amino acid would be the zwitterionic form, with a positive charge on the nitrogen of the amino group and a negative charge on the oxygen of the carboxyl group.

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The pressure of hydrogen in a flask heated to 201 °C is calculated using the ideal gas law with the provided density to find the number of moles, converting the temperature to Kelvin, and solving for pressure while assuming constant volume and amount of gas.

To determine the pressure of hydrogen in a flask when heated to 201 °C, we can use the ideal gas law, PV = nRT, where P is pressure, V is volume, n is number of moles, R is the ideal gas constant, and T is temperature in Kelvin. First, calculate the number of moles of hydrogen gas using its density and the molar mass of hydrogen. The molar mass of H2 is approximately 2 g/mol, so 0.135 g in a liter would mean 0.135 g / 2 g/mol = 0.0675 mol. Convert the temperature from degrees Celsius to Kelvin by adding 273.15 (201 °C + 273.15 = 474.15 K).

Assuming the flask's volume and amount of gas remain constant and recalling R is approximately 0.0821 L·atm/(mol·K), the pressure can then be calculated using the rearranged ideal gas law P = (nRT)/V. Inserting the calculated number of moles, the given volume of 1 liter, and the temperature in Kelvin, you can solve for pressure, P.

How does the law of conservation of mass apply  to this reaction: C2H4 + O2 → H2O + CO2?