Within an atom, electrons A. are in motion inside the nucleus. B. are in motion outside the nucleus. C. are inside the nucleus and are motionless. D. are outside the nucleus and are motionless

Answer:

Check explanation.

Explanation:

INTRODUCTION: Many researches has been done on atoms. One of them is the one done by Both. Bohr research in 1913 on atom made him to proposed the "Bohr Atomic Model''. With this model, Bohr was able to proposed his quantized shell model.

Bohr made modifications to the Model proposed by Rutherford to solve the stability problem.

RESEARCH PROGRESS: with Bohr research, he was able to explain that the angular momentum of electrons are quantized. He explained that electrons can have stable orbits around the nucleus.

Borh was also able to explain the emission and absorption of energy, when electrons jump from one orbit to another.

The effect of Earth's gravity on objects on the surface of Earth is to pull them toward the center of the planet, creating a downward force known as weight.

Gravity is the force of attraction between two objects with mass, and it is directly proportional to the mass of the objects and inversely proportional to the square of the distance between them. On Earth's surface, all objects experience the gravitational pull of the planet, causing them to be pulled toward the center of the Earth.

The strength of this gravitational force depends on two factors: the mass of the Earth and the distance from the object to the center of the Earth. Earth's mass is constant, so the force of gravity primarily varies with an object's distance from the center of the planet. Objects closer to the Earth's surface experience a stronger gravitational force, while those at higher altitudes experience a weaker force.

This gravitational force gives objects weight, which is a measure of the force of gravity acting on them. Weight is commonly measured in units such as pounds or kilograms. When an object is at rest on the surface of the Earth, it experiences a gravitational force equal to its weight, which is directed toward the center of the Earth.

In summary, Earth's gravity exerts a downward force on objects on its surface, giving them weight and keeping them anchored to the planet. This force is responsible for objects falling when dropped, and it plays a fundamental role in the physics of everyday life.

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To determine if a molecule is polar, ascertain if it contains polar bonds, draw the Lewis structure to visualize molecular geometry, and confirm if the polar bonds sum up to a net dipole moment. Molecules with a net dipole moment are polar. Geometry of the molecule also plays a key role; polar molecules can turn nonpolar if the geometry causes bond dipoles to cancel each other out.

There are a few steps to determine whether a molecule is polar. Firstly, it is important to determine whether the molecule contains polar bonds, which include ions and atoms with differing electronegativities resulting in a bond dipole moment. A polar bond has a partially positive charge on one atom and a partially negative charge on the other.

Drawing the Lewis structure for the molecule can help to visualize the molecular geometry. According to VSEPR theory, a molecule can be nonpolar if its geometry is structured in a way that the bond dipoles cancel each other out, such as in the case of CO₂ which is linear in shape. The opposite side bonds, even though polar, cancel each other out due to their antiparallel arrangement, making the molecule nonpolar. Nevertheless, in contrast, H2O has a bent shape due to lone pairs on the Oxygen atom, leading to an overall dipole moment therefore making the molecule polar.

Lastly, if polar bonds in the molecule add up to form a net dipole moment, the molecule is polar. The dipole moment measures the extent of net charge separation in the molecule and is calculated by summing the bond moments in three-dimensional space.

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The statement is false; hydrogen bonds form between adenine and thymine, and between cytosine and guanine based on the principle of base pairing.

According to the principle of base pairing, hydrogen bonds form specifically between adenine (A) and thymine (T), and between cytosine (C) and guanine (G). Adenine forms two hydrogen bonds with thymine, while cytosine forms three hydrogen bonds with guanine. This specific pairing is crucial for the stability and structure of the DNA double helix.

When you apply for jobs, companies typically require that applicants provide their work history, either on their resume or on a job application, or both.

The job application may ask for information on your most recent jobs, typically two to five positions. Or, the employer may ask for a number of years of experience, typically five to ten years of experience.

Employers generally want information on the company you worked for, your job title, and the dates you were employed there. However, sometimes the employer will ask for a more detailed employment history and more information on the jobs you have held as part of the hiring process. For example, he or she might ask for the name and contact information for your previous supervisors.

Your academic standing is calculated at the end of each term based upon your current and cumulative UCSC GPA. If both your current and cumulative UCSC GPAs are 2.0 or greater, then you are in good academic standing. If either your current or cumulative GPA is less than 2.0, then you are on academic probation. In that event, you should consult with your college academic preceptor about what you need to do to return to good standing. If your current UCSC GPA falls below 1.5 in any term, or if you are already on academic probation and your cumulative UCSC GPA falls below 2.0, then you are subject to disqualification from further enrollment in the university.

Answer: a. The pressure will increase.

Explanation:

Boyle's Law: This law states that pressure is inversely proportional to the volume of the gas at constant temperature and number of moles.

[tex]P\propto \frac{1}{V}[/tex]     (At constant temperature and number of moles)

[tex]{P_1V_1}={P_2V_2}[/tex]

where,

[tex]P_1[/tex] = initial pressure of gas

[tex]P_2[/tex] = final pressure of gas

[tex]V_1[/tex] = initial volume of gas

[tex]V_2[/tex] = final volume of gas

Thus as volume of the container will be reduced, the pressure would increase.

Answer:

a. The pressure will increase.

Explanation:

The percentage yield for the reaction is 84.2%.

Percent yield is the difference in the percent of theoretical yield to the percent of actual yield.

The reaction is

[tex]\rm2Na + O_2 = Na_2O_2[/tex]

Mass of Na = 3.74g

Calculating the moles of Na

[tex]\rm Number\;of \;moles= \dfrac{mass}{molar\;mass}\\\\\\Number\;of \;moles= \dfrac{3.74}{23}= 0.162 \;mol[/tex]

The ratio of mole of Na : (Na₂O₂) = 2:1

[tex]\rm Number\;of \;moles= \dfrac{0.162}{2}= 0.081 \;mol\\\\mass\;of Na_2O_3 = 0.081 \times 78\;g/mol\\\\mass\;of Na_2O_3 = 6.341\;g\\\\\\Yield \;of\;reaction = \dfrac{5.34g}{6.341g} \times 100 = 84.2\%[/tex]

Thus, the percent yield is 84.2%.

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In a double bond, four electrons are shared between two atoms.

When two atoms in a molecule are connected by a double bond, four electrons are involved. This is because a double bond consists of two pairs of electrons that are shared between the atoms. The Lewis structure of a molecule containing a double bond follows specific steps:

Determine the total number of valence electrons available for bonding.

Write a plausible skeletal structure for the molecule with the least electronegative atom typically in the center.

Arrange the electrons to satisfy the octet rule for each atom, which often means forming double or triple bonds to account for all electrons.

Count the number of regions of electron density (lone pairs and bonds) around the central atom. Remember, a single, double, or triple bond counts as one region of electron density.

Ensure the total number of electrons used (bonding plus non-bonding) is equal to the available valence electrons.

Let's consider the molecule of ethene (C2H4) as an example:

Two carbon (C) atoms contribute a total of 8 valence electrons (2 x 4 electrons).

Four hydrogen (H) atoms contribute a total of 4 valence electrons (4 x 1 electron).

The total number of valence electrons is 12.

The Lewis structure shows each carbon atom single-bonded to two hydrogen atoms and double-bonded to each other, with no lone pairs on the carbons, thus satisfying the octet rule.

Final answer:

A 200.0 g sample of hydrogen sulfide gas would occupy a volume of 133.5 liters at STP.

Explanation:

To calculate the volume that a 200.0 g sample of hydrogen sulfide gas would occupy at STP, we need to use the ideal gas law equation: PV = nRT.

First, we need to convert the mass of hydrogen sulfide (H2S) into moles. The molar mass of H2S is 34.08 g/mol. So, 200.0 g of H2S is equal to 200.0 g / 34.08 g/mol = 5.86 mol.

At STP conditions, the pressure (P) is 1 atm and the temperature (T) is 273 K. We can substitute these values along with the molar amount of hydrogen sulfide (n) into the ideal gas law equation to solve for the volume (V).

V = nRT / P = (5.86 mol)(0.0821 L·atm/mol·K)(273 K) / (1 atm) = 133.5 L

Therefore, a 200.0 g sample of hydrogen sulfide gas would occupy a volume of 133.5 liters at STP.

Answer:

0.67m

Explanation:

Final answer:

An electron releases energy by dropping to a lower energy level that is closer to the nucleus. So the correct option is C.

Explanation:

When an electron releases energy, it moves to an energy level that is closer to the atomic nucleus. The correct answer is C: The electron moves to a lower energy level. According to Bohr's Model, as electrons absorb energy, they are able to move to higher energy levels which are further from the nucleus. Conversely, when electrons release energy, they fall back to lower energy levels, which are closer to the nucleus. This is because electrons are attracted to the positive protons in the nucleus, and it takes energy to move them away from the nucleus. When they drop back to a lower energy level, they release energy, often in the form of light, as seen in atomic emission spectra.

True The tiny particles that make up elements are called atoms

Answer: The correct answer is Option A.

Explanation:

Gibbs Free energy is defined as amount of useful work that can be done in the system. It is equal to the enthalpy of the reaction minus the product of entropy of the reaction and absolute temperature.

Mathematically,

[tex]\Delta G=\Delta H-T\Delta S[/tex]

Where,

[tex]\Delta G[/tex] = Gibbs free energy

[tex]\Delta H[/tex] = Enthalpy of the reaction

[tex]\Delta S[/tex] = Entropy of the reaction

T = Absolute temperature

Sign Convention for Gibbs Free energy:

If [tex]\Delta G<0[/tex], it is considered as a Spontaneous reaction.

If [tex]\Delta G>0[/tex], it is considered as a Non-Spontaneous reaction.

If [tex]\Delta G=0[/tex], reaction is in equilibrium.

Hence, the correct answer is Option A.

Final answer:

The change in Gibbs free energy for a spontaneous reaction is ΔG < 0, signaling that the process occurs naturally without external forces, and equilibrium is characterized by ΔG = 0 (Option C).

Explanation:

The change in Gibbs free energy (ΔG) of a spontaneous reaction is described by a negative value, which is option A: ΔG < 0. This negative change indicates a spontaneous process in which a system naturally evolves without external intervention. At equilibrium, ΔG is equal to zero, signifying no net change in the system's state. If ΔG is positive, the reaction is not spontaneous and may only proceed with an input of energy.

These concepts are fundamental in understanding chemical thermodynamics, where ΔG combines enthalpy and entropy changes within a system to determine the spontaneity of reactions under constant temperature and pressure. A spontaneous chemical reaction will have its Gibbs free energy decreasing, typically indicative of exothermic reactions or those that increase the total entropy.