How do you know a chemical reaction has occurred in a candle?

The answer is A

1.63 × 10-3 g

Hydrophobic substances, which are 'water-fearing,' repel and don't mix with water, while hydrophilic substances are 'water-loving,' attracted to, and dissolve in water due to their polar or charged nature.

The terms hydrophobic and hydrophilic refer to the affinity, or lack thereof, that a molecule has towards water. A hydrophobic substance is one that is 'water-fearing,' meaning it repels water and does not dissolve or get wetted by it. This is often due to a lack of polar or charged groups that can form hydrogen bonds with water molecules. Common hydrophobic substances include nonpolar hydrocarbons and lipids such as fats and cholesterol.

In contrast, a hydrophilic substance is 'water-loving' and is attracted to water. Such substances can dissolve in or be wetted by water due to the presence of polar or charged groups that interact favorably with water. A hydrophile is a molecule like sugar or salt that is readily dissolved by water.

The answer is: The population of paddlefish will decrease, while the population of zooplankton will increase.

The paddlerfish is predator to zooplankton. An decrease in predator (in this example the paddlerfish) will increase the number and genetic variation in a population of zooplankton.

An decrease of food (in this example the paddlerfish) will decrease population of the lampreys.

Hman activity (hunting) decrease population of the paddlerfish.

Final answer:

To solve for the partial pressure of a gas in a mixture that includes water vapor, Dalton's law is used to account for the vapor pressure of water, and the ideal gas law assists in determining the density of water vapor.

Explanation:

To solve a problem involving partial pressure and water vapor pressure, one needs to follow a step-by-step approach. For example, if the water vapor pressure at a specific temperature is provided, such as 2.33 × 10³ Pa at 20.0°C, this value is used as the partial pressure of water vapor in the ideal gas law equation:

PV = nRT,

where P is the pressure, V is the volume, n is the number of moles, R is the universal gas constant, and T is the temperature in Kelvin. To find the density of water vapor in g/m³ which corresponds to the given vapor pressure, one must rearrange the ideal gas law to solve for n/V, which gives the number of moles per cubic meter. The molar mass of water from the periodic table is then used to convert moles to grams, thus obtaining the density. A comparison should be made with the saturation vapor density to verify the result.

An understanding of Dalton's law of partial pressures is integral as it states that the total pressure is the sum of the individual gas pressures. In the case of gas collected over water, the total pressure includes both the gas's pressure and the water vapor's pressure. The actual partial pressure of the gas of interest can be calculated as:

Pg = PTotal - PH₂O

This calculation is vital in contexts where gases are collected over water as in many laboratory settings.

Answer:

Chromium (Cr)

Explanation:

To know this, we first need to know, in which group and period of the periodic table is this element. Then, we can identify the element by calculating the atomic number.

In this case, let's write again the electron configuration:

1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d⁴

Now, with the electron configuration we can know the group in which this element is, the period, and the atomic number which will give us the identity of the element.

The period can be identified, by watching the electron configuration and look into the numbers that accompanies the orbitals (The orbitals are the letters s, p and d), and see which one has the highest number. In this case, we have the 4s² , the number 4 is the highest, so the period of this element is period 4.

Now that we know the period, let's determine the group. The group can be determined, watching the electrons of the last cap of the electron configuration (electrons are the numbers superscripted). Now, if the element pass the 3rd period we have to sum the electrons of the previous d cap. In this case, it was. So, we sum 4 electrons of the d orbytal from the previous cap, and the 2 electrons from the 4s, therefore the group of the element is the group 6 (Or column 6 of the table).

Now we know that it's on group 6 and period 4, the final confirmation will be the atomic number of the element. For this, we have to count all the electrons of all capes in the configuration.

Doing this, we have that the sum of all electrons is:

2+2+6+2+6+2+4 = 24

The atomic number of the element is 24.

So to conclude, the element which electron configuration is 1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d⁴, group 6 and period 4, is Chromium (Cr)

The three dimensional space occupied by the matter is the volume. Here 2.0 liters of volume is equal to 2000 cm³. The correct option is B.

The measure of the capacity that an object holds is defined as the volume. If a beaker can hold 100 mL water then its volume is 100. The ratio of the mass to density of a substance is the volume.

It can be expressed in mL, L, m³, cm³, etc. The SI unit of volume is m³. The equation used to determine the volume is:

Volume = Mass / Density

1 L = 1000 cm³

The volume in liters can be converted into cubic meters by multiplying it with 1000. Then, 2.0 L is:

2 L = 2 × 1000 = 2000 cm³

Hence the volume 2000 cm³ is equal to 2.0 L.

Thus the correct option is B.

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The new temperature of the given gas is [tex]\boxed{62.4\:^{\circ}\text{C}}[/tex].

Further Explanation:

An ideal gas is a hypothetical gas that is composed of a large number of randomly moving particles that are supposed to have perfectly elastic collisions among themselves. It is just a theoretical concept, and practically no such gas exists. But gases tend to behave almost ideally at a higher temperature and lower pressure.

The expression for the ideal gas equation is as follows:

[tex]\boxed{{\text{PV}} = {\text{nRT}}}[/tex]               …… (1)

Here, P is the pressure of gas.

V is the volume of the gas.

T is the absolute temperature of gas.

n denotes the number of moles of gas.

R is the universal gas constant.

Rearranging equation (1), we get:

[tex]\frac{{PV}}{T} = nR[/tex]

For a particular gas, the number of moles (n) and the universal as constant (R) both are constants.

If a specific gas with [tex]{P_1}[/tex] , [tex]{V_1}[/tex]  and [tex]{T_1}[/tex]  as initial parameters is treated to the final parameters being [tex]{P_2}[/tex] , [tex]{V_2}[/tex]  and [tex]{T_2}[/tex] . So equation (1) becomes

[tex]\frac{{{P_1}{V_1}}}{{{T_1}}} = \frac{{{P_2}{V_2}}}{{{T_2}}}[/tex]                …… (2)

Here,

[tex]{P_1}[/tex]  is the initial pressure of the gas.

[tex]{V_1}[/tex]  is the initial volume of the gas.

[tex]{T_1}[/tex]  is the initial temperature of the gas.

[tex]{P_2}[/tex]  is the final pressure of the gas.

[tex]{V_2}[/tex]  is the final volume of the gas.

[tex]{T_2}[/tex]  is the final temperature of the gas.

Calculation of the final temperature [tex]\left({{{\mathbf{T}}_{\mathbf{2}}}}\right)[/tex] of the gas:

Rearranging equation (2), we get:

[tex]{T_2} = \frac{{{P_2}{V_2}{T_1}}}{{{P_1}{V_1}}}[/tex]                …… (3)

Firstly, [tex]{T_1}[/tex] is to be converted into K. The conversion factor for this is,

[tex]{\text{0 }}^\circ{\text{C}} = {\text{273 K}}[/tex]

So [tex]{T_1}[/tex]  is calculated as follows:

[tex]\begin{aligned}{\text{Temperature}}\left( {\text{K}} \right)&= \left({32 + 273}\right)\;{\text{K}}\\&=305\;{\text{K}}\\\end{aligned}[/tex]

The value of [tex]{P_2}[/tex]  is 901 torr.

The value of [tex]{V_2}[/tex]  is 286 mL.

The value of [tex]{T_1}[/tex]  is 305 K.

The value of [tex]{P_1}[/tex]  is s721 torr.

The value of [tex]{V_1}[/tex]  is 325 mL.

Substitute these values in equation (3).

[tex]\begin{aligned}{T_2}&=\frac{{\left({{\text{901 torr}}}\right)\left({{\text{286 mL}}}\right)\left({{\text{305 K}}}\right)}}{{\left({{\text{721 torr}}}\right)\left({{\text{325 mL}}}\right)}}\\&={\text{335}}{\text{.40693 K}}\\\end{aligned}[/tex]

Conversion Factor:

[tex]{\text{0 K}} = -{\text{273}}^\circ{\text{C}}[/tex]  

So the value of [tex]{T_2}[/tex] [tex]\left({^\circ{\text{C}}}\right)[/tex]  is calculated as follows:

[tex]\begin{aligned}{T_2}&=\left( {{\text{335}}{\text{.40693}}-{\text{273}}}\right){\text{ }}^\circ {\text{C}}\\&={\text{62}}{\text{.40693 }}^\circ{\text{C}}\\&\approx{\mathbf{62}}{\mathbf{.4 ^\circ C}}\\\end{aligned}[/tex]

Learn more:

1. Law of conservation of matter states: https://brainly.com/question/2190120

2. Calculation of volume of gas: https://brainly.com/question/3636135

Answer details:

Grade: Senior School

Subject: Chemistry

Chapter: Ideal gas equation

Keywords: ideal gas, pressure, volume, absolute temperature, equation of state, hypothetical, universal gas constant, moles of gas, initial, final, K, conversion factor, 325 mL, 286 mL, 721 torr, 901 torr, 62.4 degree Celsius.

A foaming antacid tablet fizzing in water is a chemical change because it involves a chemical reaction that produces new substances, namely carbon dioxide gas.

A foaming antacid tablet fizzing in water is considered a chemical change because it involves a chemical reaction that produces new substances. When the tablet comes in contact with water, it reacts with the water to release carbon dioxide gas. This reaction is known as an acid-base reaction, in which the active ingredient in the antacid tablet reacts with the water, producing carbon dioxide gas bubbles.

This chemical reaction can be represented by the following equation:

Active ingredient + Water → Carbon dioxide gas + Other products

The formation of new substances, in this case, the production of carbon dioxide gas, is a characteristic of a chemical change.

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The noble gas notation for chlorine (Cl) is [Ne]3s²3p⁵ and for yttrium (Y) is [Kr]5s²4d¹. This notation represents the core electrons with the symbol of the nearest preceding noble gas and the valence electron configuration thereafter.

To find the electron configuration of an element in noble-gas notation, you locate the nearest noble gas that comes before the element in the periodic table. You use the noble gas to represent the core electrons and then add the remaining valence electron configuration.

For chlorine (Cl), which has 17 electrons, the nearest noble gas is neon (Ne), which has 10 electrons. Therefore, the noble-gas notation for chlorine is [Ne]3s²3p⁵.

For yttrium (Y), with 39 electrons, the nearest noble gas is krypton (Kr), which has 36 electrons. The remaining 3 electrons go into the 5s and 4d orbitals. Therefore, the noble-gas notation for yttrium is [Kr]5s²4d¹.

Answer :

The atomic number of lead is, 82. The chemical symbol of lead is, Pb.

The atomic number of silver is, 47. The chemical symbol of silver is, Ag.

The atomic number of gold is, 79. The chemical symbol of gold is, Au.

Explanation :

Atomic number : It is equal to the number of protons or electrons.

Atomic number = number of protons = number of electrons

Mass number : It is defined as the sum of number of protons and number of neutrons.

Number of neutrons = Mass number - Number of protons

As we know that:

Lead is a metal that belongs to group 14 and period 6. The atomic number of lead is, 82. The chemical symbol of lead is, Pb.

Silver is a transition metal that belongs to group 11 and period 5. The atomic number of silver is, 47. The chemical symbol of silver is, Ag.

Gold is a transition metal that belongs to group 11 and period 6. The atomic number of gold is, 79. The chemical symbol of gold is, Au.

The electrons orbiting around the nucleus in an atom have a negative electric charge.  Together, all of the electrons of an atom create a negative charge that balances the positive electric charge of the protons in the nucleus. Electrons are extremely small.

The answer is electromagnetivity

sorry, don't know

sorry, don't know

The azide ion N3- can actually be represented by 3 resonance structures.

(check attached image for the structures)

Among the three, the Structure 1 is the most important one. While structure 3 almost makes no contribution due to the positive charges located on the adjacent atoms and the overall higher formal charge.

Azide ion has [tex]\boxed{{\text{three}}}[/tex] resonating structures (For structures, refer to the attached image).

Further Explanation:

The bonding between the different atoms in covalent molecules is shown by some diagrams known as the Lewis structures. These also show the presence of lone pairs in the molecule. These are also known as Lewis dot diagrams, electron dot diagrams, Lewis dot structures or Lewis dot formula. In covalent compounds, the geometry, polarity, and reactivity are predicted by these structures.

When more than one Lewis structures are possible for a single molecule but no single structure is able to explain all the properties of the molecule then resonance is used. All the structures thus formed are called resonating structures and the phenomenon is known as resonance. The resonance structures have the same placement of atoms but different locations of bond pairs and lone pairs of electrons. Moreover, various resonating structures can be converted to each other by moving lone pairs to bonding positions, and vice-versa.

The general rules that we follow to draw the resonance structures are as follows:

a. The [tex]\pi[/tex] electrons or a lone pair of electrons can change their positions while the position of atoms remains fixed.

b. The count of the valence electrons in all the resonating structure should be same.

c. The transfer of electrons is shown by the curved arrows.

d. The resonating structure must follow octet rule that is all atoms should have 8 electrons

Conditions to determine more contributing resonating structures are as follows:

1. Smaller formal charges are always preferred over the larger one.

2. The stable structure has more delocalization of charges on the atoms.

3. A more negative formal charge must always be located on the most electronegative atom.

The resonating structures of azide ion are shown in the image attached.

Structure III is more stable than the other two. This structure has negative charge on more electronegative atom (N) and more delocalization of charge. While in structure I and II, nitrogen is having a positive charge so unstable.

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2. The correct name of the compound: https://brainly.com/question/9535482

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Grade: Senior School

Subject: Chemistry

Chapter: Resonance

Keywords: resonating structures, azide, N3-, structure I, structure II, structure III, Lewis structures, smaller, larger, electronegative atom.

The chemical formulas for compounds have the information regarding the element present, number of atoms which are present in a compound.

Compound is defined as a chemical substance made up of identical molecules containing atoms from more than one type of chemical element.

Molecule consisting atoms of only one element is not called compound.It is transformed into new substances during chemical reactions. There are four major types of compounds depending on chemical bonding present in them.They are:

1)Molecular compounds where in atoms are joined by covalent bonds.

2) ionic compounds where atoms are joined by ionic bond.

3)Inter-metallic compounds where atoms are held by metallic bonds

4) co-ordination complexes where atoms are held by co-ordinate bonds.

They have a unique chemical structure held together by chemical bonds Compounds have different properties as those of elements because when a compound is formed the properties of the substance are totally altered.

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Answer: The amount of zinc for a given amount are 0.0082 moles.

Explanation:

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

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

We are given:

Given mass of zinc = 0.535 g

Molar mass of zinc = 65.4 g/mol

Putting values in above equation, we get:

[tex]\text{Moles of zinc}=\frac{0.535g}{65.4g/mol}=0.0082mol[/tex]

Hence, the amount of zinc for a given amount are 0.0082 moles

The carbon-carbon bond in ethylene, h2cch2, results from the overlap of sp2 hybrid orbitals.

The correct option is (D).

1. Hybridization in Ethylene:

  - Ethylene [tex](\( \text{H}_2\text{C}=\text{CH}_2 \))[/tex] is a molecule composed of two carbon atoms double-bonded to each other and each carbon atom is also bonded to two hydrogen atoms.

  - The carbon atoms in ethylene undergo sp2 hybridization to form the π bond between them.

2. Explanation of sp2 Hybridization:

  - In sp2 hybridization, one ( s ) orbital and two ( p ) orbitals of the carbon atom combine to form three sp2 hybrid orbitals.

  - These sp2 hybrid orbitals are arranged in a trigonal planar geometry with bond angles of approximately 120 degrees.

  - One of the sp2 hybrid orbitals overlaps with an sp2 orbital from the other carbon atom to form the σ bond between the two carbon atoms.

  - The remaining two sp2 hybrid orbitals on each carbon atom form sigma bonds with hydrogen atoms.

3. Formation of the π Bond:

  - The remaining unhybridized ( p ) orbital on each carbon atom is perpendicular to the plane formed by the sp2 hybrid orbitals.

  - These unhybridized ( p ) orbitals overlap laterally to form the π bond between the carbon atoms.

  - This lateral overlap of the ( p ) orbitals allows for the formation of the π bond, which is responsible for the double bond character between the carbon atoms in ethylene.

4. Conclusion:

  - Thus, the π bond in ethylene results from the overlap of unhybridized ( p ) atomic orbitals, making option D) sp2 hybrid orbitals the correct answer.

complete question given below:

The π bond in ethylene, H2C=CH2, results from the overlap of ________. A) sp3 hybrid orbitals B) s atomic orbitals C) sp hybrid orbitals D) sp2 hybrid orbitals E) p atomic orbitals

The energy of a gamma ray photon can be calculated using Planck's equation. Given the frequency of 5.02*10^20 Hz, substituting this and Planck's constant into the equation results in an energy of approximately 3.33 × 10^-13 Joules.

The energy of a gamma ray photon can be calculated using Planck's equation: E = hf, where 'E' stands for energy, 'h' is Planck's constant and 'f' is the frequency of the radiation.

The value of Planck's constant is 6.626 × 10^−34 J⋅s (Joules times seconds), and the frequency provided is 5.02*10^20 Hz. Substituting these values into the Planck's equation:

E = (6.626 × 10−34 J⋅s) (5.02 × 1020 Hz) = 3.33 × 10-13 J (Joules)

Thus, the energy of the given gamma ray photon is approximately 3.33 × 10-13 Joules.

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Sulfur is the element that has the same number of valence electrons as oxygen, as both belong to Group 6A of the periodic table.

The element that has the same number of valence electrons as oxygen is sulfur (c). Oxygen is in Group 6A on the periodic table, which means it has six valence electrons. Sulfur, which is also in Group 6A, has the same number of valence electrons as oxygen. The completion of the valence shell is of great importance because it determines the bonding behavior and reactivity of an element. This is a part of the periodic table's systematic organization, where elements in the same group have identical valence electron configurations and exhibit similar chemical properties.

Answer:

[tex]0.00826\ molar.[/tex]

Explanation:

The balanced reaction is:

[tex]2AgNO_3+MgCl_2-->2AgCl+Mg(NO_3)_2[/tex]

We know, number of moles = [tex]\dfrac{Given\ mass}{Molar\ mass}.[/tex]

Therefore, moles of AgCl formed=[tex]\dfrac{0.1183}{143}=0.000827\ moles.[/tex]        ( Molar mass of AgCl is 143 gm)

From the balanced equation 1 mol of [tex]MgCl_2[/tex] forms 2 mol of AgCl.

Therefore, 0.000827 mol of AgCl was formed by

[tex]\dfrac{0.000827}{2}=0.0004135\ mol[/tex]

Now concentration of [tex]MgCl_2=\dfrac{moles\ of\ MgCl_2}{Volume\ in\ Liters}=\dfrac{0.000413}{0.050}\ molar=0.00826\ molar.[/tex]

Hence, this is the required solution.

The concentration of magnesium ions in the original MgCl₂ solution is 8.25 x 10⁻³ M, determined by using stoichiometry and principles of gravimetric analysis.

We first calculated the moles of AgCl formed and connected it back to MgCl₂. The final concentration is found by dividing the moles by the total volume.

To determine the concentration of magnesium ions (Mg²⁺) in the original MgCl₂ solution, we use stoichiometry and principles of gravimetric analysis. First, we need to find the moles of AgCl precipitated:

Mass of AgCl = 0.1183 g
Molar Mass of AgCl = 143.32 g/mol
Moles of AgCl = 0.1183 g / 143.32 g/mol = 8.25 x 10⁻⁴ mol

Since the reaction between AgNO₃ and MgCl₂ is:

2 AgNO₃ + MgCl₂ → 2 AgCl + Mg(NO₃)₂

The moles of AgCl equals the moles of Cl⁻, which also equals the moles of MgCl₂.

Initial combined volume = 50.0 mL + 50.0 mL = 100.0 mL

So, the concentration of Mg²⁺ is:

[Mg²⁺] = (moles of MgCl₂) / (total volume in L)
= (8.25 x 10⁻⁴ mol) / (0.100 L)
= 8.25 x 10⁻³ M

Thus, the concentration of magnesium ions in the original MgCl₂ solution is 8.25 x 10⁻³ M.

Answer: Glaciers

Explanation: