(a)
Interpretation:
The total number of electrons that can be accommodated in orbital of
Concept Introduction:
Electrons are present outside the nucleus of an atom. These electrons are restricted to some specific regions around the nucleus of an atom. Electrons do move rapidly in the space about the nucleus is divided into subspaces that are known as shells, subshells and orbitals.
Electron shells are the space region that is present around the nucleus and this contains electrons that possess approximately same energy and which spend most of their time in the same distance from nucleus. Electron shells are numbered as 1, 2, 3, and so on. The energy of electron increases as the distance between the nucleus and electron shell increases. Electron shell can accommodate electrons and it varies because higher the electron shell number, more is the number of electrons that can be present in it.
Electron subshell is the space region in the electron shell which contains the electrons that have same energy. The number of electron subshell present for each electron shell depends upon the shell number. Electrons are added to the electron subshell in the electron shell. The number of electron subshell that is present in an electron shell depends only on the shell number. If the shell number is 1, then there is only one electron subshell. If the shell number is 2 means then there is two electron subshells and so on.
Electron orbital is the space region in electron subshell where the electrons with specific energy are most likely to be found. An electron orbital can hold only two electrons irrespective of the other considerations. “s” subshell has one orbital, “p” subshell has three orbital, “d” subshell has five orbital and “f” subshell has seven orbitals.
Each and every orbitals have distinct shape. This does not depend upon the shell number. “s” orbital is spherical shape, “p” orbital has two lobes, “d” orbitals have four lobes, and “f” orbital has eight lobes.
Electrons that are present within an orbital “move about” in an orbital. Electron spins on its own either in clockwise or anticlockwise direction. In an orbital, the two electrons that are present will have opposite spin. If one electron spins in clockwise direction, the other electron will spin in anticlockwise direction in an orbital. For two electrons present in the same orbital, this is the most favorable state energetically.
(b)
Interpretation:
The total number of electrons that can be accommodated in orbital of
Concept Introduction:
Electrons are present outside the nucleus of an atom. These electrons are restricted to some specific regions around the nucleus of an atom. Electrons do move rapidly in the space about the nucleus is divided into subspaces that are known as shells, subshells and orbitals.
Electron shells are the space region that is present around the nucleus and this contains electrons that possess approximately same energy and which spend most of their time in the same distance from nucleus. Electron shells are numbered as 1, 2, 3, and so on. The energy of electron increases as the distance between the nucleus and electron shell increases. Electron shell can accommodate electrons and it varies because higher the electron shell number, more is the number of electrons that can be present in it.
Electron subshell is the space region in the electron shell which contains the electrons that have same energy. The number of electron subshell present for each electron shell depends upon the shell number. Electrons are added to the electron subshell in the electron shell. The number of electron subshell that is present in an electron shell depends only on the shell number. If the shell number is 1, then there is only one electron subshell. If the shell number is 2 means then there is two electron subshells and so on.
Electron orbital is the space region in electron subshell where the electrons with specific energy are most likely to be found. An electron orbital can hold only two electrons irrespective of the other considerations. “s” subshell has one orbital, “p” subshell has three orbital, “d” subshell has five orbital and “f” subshell has seven orbitals.
Each and every orbitals have distinct shape. This does not depend upon the shell number. “s” orbital is spherical shape, “p” orbital has two lobes, “d” orbitals have four lobes, and “f” orbital has eight lobes.
Electrons that are present within an orbital “move about” in an orbital. Electron spins on its own either in clockwise or anticlockwise direction. In an orbital, the two electrons that are present will have opposite spin. If one electron spins in clockwise direction, the other electron will spin in anticlockwise direction in an orbital. For two electrons present in the same orbital, this is the most favorable state energetically.
(c)
Interpretation:
The total number of electrons that can be accommodated in orbital of
Concept Introduction:
Electrons are present outside the nucleus of an atom. These electrons are restricted to some specific regions around the nucleus of an atom. Electrons do move rapidly in the space about the nucleus is divided into subspaces that are known as shells, subshells and orbitals.
Electron shells are the space region that is present around the nucleus and this contains electrons that possess approximately same energy and which spend most of their time in the same distance from nucleus. Electron shells are numbered as 1, 2, 3, and so on. The energy of electron increases as the distance between the nucleus and electron shell increases. Electron shell can accommodate electrons and it varies because higher the electron shell number, more is the number of electrons that can be present in it.
Electron subshell is the space region in the electron shell which contains the electrons that have same energy. The number of electron subshell present for each electron shell depends upon the shell number. Electrons are added to the electron subshell in the electron shell. The number of electron subshell that is present in an electron shell depends only on the shell number. If the shell number is 1, then there is only one electron subshell. If the shell number is 2 means then there is two electron subshells and so on.
Electron orbital is the space region in electron subshell where the electrons with specific energy are most likely to be found. An electron orbital can hold only two electrons irrespective of the other considerations. “s” subshell has one orbital, “p” subshell has three orbital, “d” subshell has five orbital and “f” subshell has seven orbitals.
Each and every orbitals have distinct shape. This does not depend upon the shell number. “s” orbital is spherical shape, “p” orbital has two lobes, “d” orbitals have four lobes, and “f” orbital has eight lobes.
Electrons that are present within an orbital “move about” in an orbital. Electron spins on its own either in clockwise or anticlockwise direction. In an orbital, the two electrons that are present will have opposite spin. If one electron spins in clockwise direction, the other electron will spin in anticlockwise direction in an orbital. For two electrons present in the same orbital, this is the most favorable state energetically.
(d)
Interpretation:
The total number of electrons that can be accommodated in orbital of
Concept Introduction:
Electrons are present outside the nucleus of an atom. These electrons are restricted to some specific regions around the nucleus of an atom. Electrons do move rapidly in the space about the nucleus is divided into subspaces that are known as shells, subshells and orbitals.
Electron shells are the space region that is present around the nucleus and this contains electrons that possess approximately same energy and which spend most of their time in the same distance from nucleus. Electron shells are numbered as 1, 2, 3, and so on. The energy of electron increases as the distance between the nucleus and electron shell increases. Electron shell can accommodate electrons and it varies because higher the electron shell number, more is the number of electrons that can be present in it.
Electron subshell is the space region in the electron shell which contains the electrons that have same energy. The number of electron subshell present for each electron shell depends upon the shell number. Electrons are added to the electron subshell in the electron shell. The number of electron subshell that is present in an electron shell depends only on the shell number. If the shell number is 1, then there is only one electron subshell. If the shell number is 2 means then there is two electron subshells and so on.
Electron orbital is the space region in electron subshell where the electrons with specific energy are most likely to be found. An electron orbital can hold only two electrons irrespective of the other considerations. “s” subshell has one orbital, “p” subshell has three orbital, “d” subshell has five orbital and “f” subshell has seven orbitals.
Each and every orbitals have distinct shape. This does not depend upon the shell number. “s” orbital is spherical shape, “p” orbital has two lobes, “d” orbitals have four lobes, and “f” orbital has eight lobes.
Electrons that are present within an orbital “move about” in an orbital. Electron spins on its own either in clockwise or anticlockwise direction. In an orbital, the two electrons that are present will have opposite spin. If one electron spins in clockwise direction, the other electron will spin in anticlockwise direction in an orbital. For two electrons present in the same orbital, this is the most favorable state energetically.
Want to see the full answer?
Check out a sample textbook solutionChapter 3 Solutions
General, Organic, and Biological Chemistry Seventh Edition
- Give the number of orbitals in (a) n=3(b) a 4p sublevel. (c) an f sublevel. (d) a d sublevel.arrow_forwardAlthough a hydrogen atom has only one electron, the hydrogen atom possesses a complete set of available orbitals. What purpose do these additional orbitals serve?arrow_forward• sketch the shapes of s and p orbitals and recognize orbitals by their shapes.arrow_forward
- For each of the following elements, which set of orbitals is last to till in the ground state? a. radium b. iodine c. gold d. uraniumarrow_forward6.36 Why are there no 2d orbitals?arrow_forwardHow many electrons in an atom can have the following quantum designation? (a) 1s (b) 4d, m l =0(c) n=5,l=2arrow_forward
- Your text describes the probability map for an s orbital using an analogy to the earth’s atmosphere. Explain this analogy.arrow_forwardThe “Chemistry in Focus" segment The Chemistry of Bohrium discusses element 107. bohrium (Bh). What is the expected electron configuration of Bh?arrow_forwardWhich orbital is the first be filled in any atom? Why?arrow_forward
- Indicate whether each of the following statements is true or false. a. An orbital has a definite size and shape, which are related to the energy of the electrons it could contain. b. All the orbitals in a subshell have the same energy. c. All subshells accommodate the same number of electrons. d. A 2p subshell and a 3p subshell contain the same number of orbitals.arrow_forwardThe following shapes each represent an orbital of an atom in a hypothetical universe. The small circle is the location of the nucleus in each orbital. a If you placed an electron in each orbital, which one would be higher in energy? b When an electron makes a transition from the orbital represented on the right to the orbital on the left, would you expect energy to be absorbed or released? c Draw a sketch of an orbital of the same type that would be higher in energy than either of the two pictured orbitals.arrow_forwardIdentify the two atoms with the same number of electrons in their outermost energy level. a. Na/K b. K/Ca c. Na/Mg d. Ca/Naarrow_forward
- General, Organic, and Biological ChemistryChemistryISBN:9781285853918Author:H. Stephen StokerPublisher:Cengage LearningChemistry: Principles and ReactionsChemistryISBN:9781305079373Author:William L. Masterton, Cecile N. HurleyPublisher:Cengage LearningGeneral Chemistry - Standalone book (MindTap Cour...ChemistryISBN:9781305580343Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; DarrellPublisher:Cengage Learning
- Introductory Chemistry: A FoundationChemistryISBN:9781285199030Author:Steven S. Zumdahl, Donald J. DeCostePublisher:Cengage LearningChemistry for Today: General, Organic, and Bioche...ChemistryISBN:9781305960060Author:Spencer L. Seager, Michael R. Slabaugh, Maren S. HansenPublisher:Cengage LearningIntroductory Chemistry: An Active Learning Approa...ChemistryISBN:9781305079250Author:Mark S. Cracolice, Ed PetersPublisher:Cengage Learning