The number of valence electrons found in an atom of a group a element is equal to

Answer: D) boiling

Explanation:

In order to separate a mixture of alcohol and water the mixture can be heated until the alcohol boils. The boiling point of alcohol is lower than water. The alcohol will boil off leaving the water.

Final answer:

The experiment utilizes the physical property of boiling points to separate a mixture of alcohol and water through distillation, demonstrating how substances with different volatilities can be separated without altering their chemical properties. The correct answer is D) boiling.

Explanation:

The experiment demonstrates the physical property of boiling points by utilizing temperature to separate a mixture of alcohol and water. This is because alcohol and water have different boiling points, which allows them to be separated through a process known as distillation. Distillation relies on the fact that the substance with the lower boiling point (in this case, alcohol) will vaporize first, and then it can be condensed back into a liquid and collected separately from water. This method is a physical process that does not alter the chemical properties of the substances involved.

Therefore, the correct answer to the question is D) boiling. This property is crucial for separating mixtures into their component substances by taking advantage of their different volatilities, a measure of how easily a substance converts to gas at a given temperature.

Final answer:

Sodium atoms are oxidized when they lose an electron and change into sodium cations upon contact with water. This forms positively charged Na+ ions that are surrounded by water molecules in a process known as dissociation.

Explanation:

When elemental sodium is added to water, the sodium atoms ionize spontaneously. This transformation from an uncharged Na to Na+ means that the Na atoms have been oxidized. An oxidation process involves the loss of electrons, changing the sodium atom into a sodium cation.

A sodium atom (Na) has equal numbers of protons and electrons, making it uncharged. Once an electron is lost, the sodium cation (Na+) has one more proton than electrons, thus acquiring an overall positive charge.

Dissociation in water occurs when atoms or groups of atoms break off from molecules and form ions. For example, when table salt (NaCl) is added to water, it dissociates into Na+ and Cl− ions.

During this process, spheres of hydration form around the ions, with water molecules orienting themselves around the positive sodium ion and negative chloride ion due to their polar natures.

Scientists know that atoms of elements are all divisible.

Atomic structure refers to the structure of atom which consists of a nucleus in the  center with protons and neutrons being present inside the nucleus .Protons are positively charged sub atomic particles while the neutrons are sub atomic particles which are electrically neutral.

Outside the nucleus , in circular orbits there are electrons revolving around the nucleus with negative charge on each electron .The history of atomic structure dates back to the time of Democritus who proposed that matter is made up of atoms.

The study of atom gives a great insight about the wide range of chemical reactions , chemical bonds and their physical properties.To explain the atomic structure , various atomic models were proposed like Dalton's atomic theory ,Thomson's atomic model and Rutherford's atomic model and Bohr's atomic model.

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Final answer:

The hydrogen sulfate ion (HSO4-) will form a slightly basic solution when dissolved in water because it reacts to produce hydroxide ions (OH-) which increases the pH above 7.

Explanation:

The hydrogen sulfate ion (HSO4-) is the conjugate base of sulfuric acid (H2SO4) and the conjugate acid of sulfate (SO42-). When HSO4- is dissolved in water, it can react with water to form hydrogen sulfate (H2SO4) and hydroxide ions (OH-), which causes the solution to be basic. This is due to the fact that it slightly ionizes to produce OH- ions. Based on the reactions and comparative strengths of acids and bases, HSO4- being a conjugate base of a strong acid is a very weak base and will therefore form a solution that is slightly basic, provided that the resulting concentration of OH- ions is greater than that of H3O+ ions in the water.

Final answer:

To find the empirical formula of a xenon fluoride compound, first calculate the mass of fluorine that reacted, then determine the mol amounts of both xenon and fluorine, and finally, simplify their ratio. The calculations reveal that the empirical formula of the compound is XeF₆.

Explanation:

To determine the empirical formula of the xenon fluoride compound formed when xenon (Xe) reacts with fluorine, we first need to figure out the mass of fluorine that reacted with xenon. Given that the original mass of xenon is 5.08 g and the final mass of the xenon fluoride compound is 9.49 g, the mass of fluorine that reacted can be calculated as 9.49 g - 5.08 g = 4.41 g.

Next, we calculate the molar amounts of xenon and fluorine in the compound. The molar mass of xenon (Xe) is approximately 131.29 g/mol, and the molar mass of fluorine (F) is approximately 19.00 g/mol. Therefore, the molar amount of xenon is 5.08 g / 131.29 g/mol = 0.0387 mol, and the molar amount of fluorine is 4.41 g / 19.00 g/mol = 0.232 mol.

Then, to find the empirical formula, we divide the molar amounts of both elements by the smallest value to simplify the ratio. This gives us a molar ratio of Xe:F approximated to 1:6, leading to the empirical formula of XeF₆.

A compound is a pure substance formed by chemically bonding two or more different elements in a fixed ratio. It can only be broken down into simpler substances through chemical processes.

An compound is a substance in which atoms of two or more elements are combined in a fixed proportion. A compound is a pure substance composed of atoms of two or more different chemical elements bonded in some fixed ratio, forming molecules of that substance. These atoms are held together by chemical bonds and the compound has properties different from the individual elements that compose it. Compounds can be separated into simpler substances and elements only through chemical methods, not by physical means such as filtering or distillation.

Lithium sulfate is Li2SO4

Strontium chlorate is Sr(ClO3)2

Strontium sulfate is SrSO4

So the complete balanced chemical reaction for this is:

Li2SO4 (aq) +  Sr(ClO3)2 (aq) -->  SrSO4 (s)  +  2 LiClO3 (aq)

This is a type of double replacement reaction since there is an exchange of ions.

In a precipitation reaction between aqueous lithium sulfate and strontium chlorate, strontium sulfate precipitates while lithium chlorate remains aqueous. The balanced molecular equation for this reaction is: Li2SO4 (aq) + Sr(ClO3)2 (aq) → SrSO4 (s) + 2 LiClO3 (aq).

When aqueous lithium sulfate (Li2SO4) is mixed with aqueous strontium chlorate (Sr(ClO3)2), one product that forms is strontium sulfate (SrSO4), which crystalizes due to its insolubility in water. The other product is lithium chlorate (LiClO3), which remains aqueous due to its high solubility.

The balanced molecular equation representing this precipitation is: Li2SO4 (aq) + Sr(ClO3)2 (aq) → SrSO4 (s) + 2 LiClO3 (aq).

This equation reflects the conversion of the reactants, lithium sulfate and strontium chlorate, into the products, strontium sulfate (a precipitate) and lithium chlorate.

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 Atomic Weight of Oxygen is 16 g/mol 

Use the equation n=m/MM

You know m (mass) and MM (molar mass), sub in into the equation.


Ans: 2.2 mol

Answer :  The correct option is, (A) Aldehyde

Explanation :

Alcohol group : It is the class of organic compound in which the hydroxy (-OH) group is attached to a hydrocarbon is known as alcohols.

The general representation of alcohol are, [tex]R-OH[/tex].

For example : [tex]CH_3-CH_2-OH[/tex] is obtained when one hydrogen atom is replaced by [tex]-OH[/tex] group.

Amino acid : Amino acid are the acid that contains two functional groups which are carboxylic group, [tex]-COOH[/tex] and ammine group, [tex]-NH_2[/tex].

The bond present between the two amino acid is a peptide bond. The peptide bond is formed between the nitrogen of one amino acid and carbon of another amino acid.

Ester group : It is the class of organic compound in which the [tex]-COO[/tex] group is attached to a hydrocarbon is known as ester.

The general formula of ester are, [tex]R-COO-R^'[/tex]. It is directly attached to the two alkyl group of carbon.

Aldehyde group : It is the class of organic compound in which the (-CHO) group is attached to a hydrocarbon is known as aldehyde.

The general representation of aldehyde are, [tex]R-CHO[/tex].

For example : [tex]CH_3-CH_2-CHO[/tex] is obtained when one hydrogen atom is replaced by [tex]-CHO[/tex] group.

Hence, the correct option is, (A) Aldehyde

The number of protons plus the number of neutrons is the mass number.

The ionic charge depends on the number of electrons.

The atomic number is the number of protons.

Atoms can have different isotopic masses, but there is no such thing as atomic isotope number.

The  property of methane which  is a chemical property is its ability to oxidize in air.

These properties are defined as those properties which become evident during or after a chemical reaction after the identity of the substance is changed during chemical reaction.

These properties cannot be determined externally just by viewing the substance ,these change immensely after a substance undergoes a chemical change.These are used for identification of unknown substances and for building up chemical classifications.

The major chemical properties are flammability,toxicity,reactivity,acidity and heat of combustion.For a chemical property to be apparent , it is necessary that the structure of the substance is altered.

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first you divide them together and get an answer of 10 then you times it by 5 and your answer is   50 ml

Answer:

oxygen (O)

Explanation:

Oxygen is electrically neutral atom will have an electron configuration of 1 s 22 s 22 p 4. Therefore, option B is correct.

The distribution of electrons in an element's atomic orbitals is described by the element's electron configuration. Atomic electron configurations adhere to a standard nomenclature in which all atomic subshells that contain electrons are arranged in a sequence with the number of electrons they each hold expressed in superscript.

One orbital can house a maximum of two electrons, and there are four different types of orbitals (s, p, d, and f). More electrons can be held in the p, d, and f orbitals since they contain various sublevels. According to its location on the periodic table, each element's electron configuration is distinct.

The arrangement of electrons within an atom's orbitals is known as its electronic configuration. Each neutral atom contains an equal number of electrons, which is a fixed number.

Thus, option B is correct.

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The thing that makes the orbitals surrounding an atom's nucleus special is that the energy level changes as the electrons occupy space farther away from the nucleus. The s, p, d, and f orbitals are distinct because the nucleus is dropped as their energy rise and their bonds weaken.

Generally speaking, an atom's electrons have a lot of special characteristics, such as how they orbit the nucleus.

The electrons that it contains

Additionally, the energy level that changes when electrons occupy space farther from the nucleus

The s, p, d, and f orbitals are distinct because the nucleus is dropped as their energy rise and their bonds weaken.

Answer: 1.A false positive and 2.A false negative.

Explanation:

A false positive the classic example is the contamination of almost any sample with sodium ions which gives an intense yellow line even when the sodium is present as only impurity.

A false negative here sodium ions is the culprit that masks other emissions unless the emissions are resolved spectroscopically rather than simply visually.

Answer:

B. I, II, III, and IV

Explanation:

A chemical change occurs when the original substances (the reactants) are changed into a new substance or substances (the products). A chemical change can be indicated by a color change, gas formation, solid formation, or a temperature change. I, II, III, and IV all indicate that a chemical change has occurred when Hannah mixes the two chemicals

A chemical change occurs when she mixes the two chemicals together. The chemicals change color from colorless to purple, a brown solid forms in the bottom of the beaker and a yellow gas forms

Chemical synthesis, or, alternatively, chemical breakdown into two or more separate molecules, occurs when one material reacts with another to create a new substance.

These processes are referred to as chemical reactions, and they are often irreversible, barring additional chemical reactions. When one chemical material changes into one or more others, as when iron rusts, this is referred to as a chemical transformation.

Chemical reactions produce changes in the way that atoms and molecules are ordered, which leads to the formation of new substances with new characteristics.

Thus, option B is correct.

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A [tex]\boxed{{\text{bonding}}}[/tex] molecular orbital is lower in energy than the atomic orbital of which it is composed.

Further Explanation:

Atomic Orbital:

The wave nature of electrons present in any atom is expressed by a mathematical function, known as atomic orbital. This wave function is used for determining the probability to find electrons in specific region around atomic nucleus.

Molecular orbitals:

These orbitals are formed by permitted interactions between atomic orbitals. Such orbitals are formed only if symmetries of bonded atomic orbitals match with each other. The number of atomic orbitals results in formation of same number of molecular orbitals.So if n atomic orbitals combine with each other,n molecular orbitals will result.

Following molecular orbitals are formed by interaction between atomic orbitals:

1. Bonding molecular orbitals

These orbitals are formed by constructive interference of waves of different atomic orbitals. Such orbitals are used to depict attractions between atomic orbitals. When electrons are placed in bonding molecular orbitals, this leads to bond strengthening and stabilization of resulting molecule. Hence such orbitals have lower energy, even less than that of combining atomic orbitals.

2. Antibonding molecular orbitals

These orbitals are formed by destructive interference of waves of different atomic orbitals. When electrons are placed in antibonding molecular orbitals, these experience greater repulsion, thereby resulting in repulsion between the combining nuclei.Suchelectrons tend to destabilize it so the energy of the anti-bonding molecular orbitals is higher.

3. Nonbonding molecular orbitals

The energy of such orbitals remains unaffectedif electrons are added or removedfrom them. These orbitals are considered equivalent to lone pairsrepresented in Lewis structures. The only difference is nonbonding molecular orbitals are used up in molecular orbital theory.

Therefore bonding molecular orbitals have lower energy than combining atomic orbitals.

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Answer details:

Grade: High School

Subject: Chemistry

Chapter: Chemical bonding and molecular structure

Keywords: atomic orbitals, molecular orbitals, Lewis structures, lone pairs, bonding, antibonding, nonbonding, molecular orbitals, constructive interference, destructive interference, electrons, energy.

D. Increasing collisions of gas molecules will increase energy between them.

Adding a limited amount of  NaOH and then an excess amount is because initially, a metal hydroxide may form which gets soluble when more base will be added and then form a metal complex.

Qualitative Analysis can be described as the determination of non-numerical information about a chemical species, a reaction, etc. Qualitative analysis is often easier, faster, and cheaper to perform.

In qualitative analysis, we commonly add the base in drops, and then in addition will be done in excess. When the base is added in drops, then metal hydroxide is formed and this metal hydroxide is often insoluble.

After the formation of metal hydroxide, the base can be added in excess so that the metal hydroxide which was formed first will dissolve in the excess base by forming a metal complex.

For example,

[tex]CuCl_2(aq) + 2NaOH(aq) \longrightarrow Cu(OH)_2(s) + 2NaCl(aq)\\Cu(OH)_2(s) + 2OH^-(aq) \longrightarrow[Cu(OH)4]^{2+}(aq)[/tex]

This same strategy can be used with the addition of ammonia NH₃(aq).

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Adding limited and then an excess amount of NaOH and NH₃(aq) helps in selective titration and neutralization reactions when dealing with mixtures. It ensures accurate stoichiometry and the formation of desired products while maintaining appropriate conditions such as pH.

In the described experiment, adding a limited and then an excess amount of NaOH as well as NH₃ is a strategy used to perform selective titrations in the presence of multiple reactive species. The use of NaOH in limited amounts allows for the neutralization of specific components, such as acids in a mixture, while minimizing interference from other components. For NH₃, since it is a weak base and would react to form ammonium ions (NH₄⁺ ), adding NaOH in excess ensures that any conjugate acid forms of amines present are converted back to the free base, making it easier to extract due to its non-polar nature.

When dealing with a mixture containing NH₄⁺  ions, their titration with NaOH can be problematic due to a poorly-defined end point. This is because NH₄⁺ is a weak acid with a very low acid dissociation constant (Ka), resulting in an end point that is difficult to detect accurately. By adding NaOH in varying amounts, chemists are able to control the reactions and attain the correct stoichiometry needed for analytical purposes or product formation.

Moreover, buffers such as the HC₂H₃O₂/NaC₂H₃O₂ buffer help to maintain pH levels when strong bases are added, preventing significant pH changes by converting the OH⁻ ions into water instead of simply increasing the basicity of the solution.