Elements in the same group on the periodic table have the same number of electrons

number of protons

number of neutrons

number of valence electrons

Answers

Answer 1

Answer: Elements in the same group have the same number of valence electrons labelled in Roman numerals.

Also, From left side-Right side of the periodic is in the following order - Alkali Metals, Alkali Earth Metals, Halogens then Noble gases in the Far right of the periodic table

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Which statement about exothermic reactions is accurate? a.As reactants form products, the potential energy decreases.b.As reactants form products, the potential energy increases.c.Thermal energy is transferred from the product to the reacting substances.d.Thermal energy is transferred from the surroundings to the reacting substances.

Which type of reaction releases the greatest amount of energy per mole of reactant?(1) combustion (2) decomposition (3) nuclear fusion (4) oxidation-reduction

Answers

Nuclear fusion.

Nuclear fusion reactions release a lot of energy

Explanation:

In natural philosophy, the nuclear reaction could be a reaction during which 2 or additional atomic nuclei identical enough to create one or additional completely different atomic nuclei and subatomic particles (neutrons or protons). The distinction in mass between the reactants and product is manifested because the unharness of enormous amounts of energy.

(3) nuclear fusion. Nuclear fusion reactions release a lot of energy

21 Which mathematical expression represents the heat of reaction for a chemical reaction?(1) (the heat of fusion) – (the heat of vaporization)(2) (the heat of vaporization) – (the heat of fusion)
(3) (the potential energy of the products) – (the potential energy of the reactants)
(4) (the potential energy of the reactants) – (the potential energy of the products)

Answers

Correct Answer: Option 3 i.e. (the potential energy of the products) – (the potential energy of the reactants)

Reason:
Heat of reaction for a chemical reaction is the change in the enthalpy of a chemical reaction that occurs at a constant pressure. This can be measured on the basis of potential energy of reactants and products. Mathematically, it is expressed as:

Heat of reaction = ΔH = ΣH products - ΣHr reactants.

The answer is (3) the potential energy of the products - the potential energy of the reactants. The reaction energy production can be represented by the change of energy of products and reactants.

Which equation represents the reaction of acetic (ethanoic) acid with water? A. CH3COO- + H2O CH3COOH + OH- B. CH3COOH + H2O CH3COO- + H3O+ C. CH3COO- + H2O CH3COO2- + H3O+ D. CH3COOH + H2O CH3COOH2+ + OH-

Answers

"CH3COOH + H2O CH3COO- + H3O+" is the equation among the choices given in the question represents the reaction of acetic (ethanoic) acid with water. The correct option among all the options that are given in the question is the second option or option "B". I hope that the answer has helped you.

Answer:

B. CH3COOH + H2O CH3COO- + H3O+

Explanation: hope this helped :)

The amount by which a machine multiplies an effort force is called ____.a. efficiency factor
b. fulcrum
c. mechanical advantage
d. resistance force

Answers

c. mechanical advantage

Answer:

Mechanical Advantage

Explanation:

Which of the following elements is stable?a. Boron, atomic number 5
b. Carbon, atomic number 6
c. Neon, atomic number 10
d. Fluorine, atomic number 9

Answers

Answer:

Neon, atomic number 10, is stable.

Explanation:

Valencia electrons are the electrons found in the last electronic layer (called valence orbitals). These electrons are what determine the ability of the atom to form bonds. When an element joins another, it does so through its valence electrons.

The noble gases include the elements of group 18 of the periodic table. The noble gases are characterized by their very low chemical reactivity because they are very stable. This is because they have the full valence layer (complying with the octet rule, that is, they have 8 electrons at their last energy level, with the exception of helium that has 2 electrons), causing them to have a low tendency to capture or release electrons . That is why they are also called inert gases.

The Neon, whose atomic number is 10, belongs to the group of noble gases. So this element is stable.

Neon is the most stable because it has 8 valence electrons. when an element has full number of valence electrons, they become stable.

Radical chlorination of pentane is a poor way to prepare 1-chloropentane, but radical chlorination of neopentane, (CH3)4C, is a good way to prepare neopentyl chloride, (CH3)3CCH2Cl. Why? ...?

Answers

Because it’s random that CH3CH2CH2CH2CH3 losing a (·H), so by reaction with Cl2, it canform many isomers, such as CH3CH2CH2CHClCH3, CH3CH2CHClCH2CH3,CH3CH2CH2CH2CH2Cl, so a poor way to prepare 1-chloropentane.While for (CH3)4C, each of the H atom are equivalent. So no matter which one be substituted,only one product, (CH3)CCH2Cl, can be prepared.

Final answer:

Radical chlorination of pentane and neopentane results in different yields of the desired products due to the selectivity of the reaction. With neopentane, the reaction is very selective, producing a higher yield of neopentyl chloride, while with pentane, the reaction isn't selective, leading to various isomers and a lower yield of 1-chloropentane.

Explanation:

Radical chlorination of pentane isn't an efficient method to prepare 1-chloropentane because it doesn't give a high yield of the desired product. This is due to it being a non-selective process, leading to the formation of several isomeric products. In the case of pentane, several different hydrogens can be replaced creating many possible isomers of chloropentane.

On the other hand, radical chlorination of neopentane or (CH3)4C is a good way to prepare neopentyl chloride or (CH3)3CCH2Cl. This is because neopentane has a far greater proportion of equivalent tertiary hydrogens. When chlorination occurs, it's most likely to happen at these sites, producing a higher yield of the desired neopentyl chloride product with less chance of isomer formation.

This difference is due to the selectivity and specificity of the radical chlorination reaction on neopentane versus pentane. Radical chlorination is not very selective with pentane but is quite selective with neopentane due to the type of hydrogens present, thus making it a more ideal reaction.