Chemistry: Atoms First
Chemistry: Atoms First
2nd Edition
ISBN: 9780073511184
Author: Julia Burdge, Jason Overby Professor
Publisher: McGraw-Hill Education
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Chapter 3, Problem 3.103QP

Determine the number of impaired electrons in each of the following atoms in the ground state and identify each as diamagnetic or paramagnetic: (a) Rb, (b) As, (c) I, (d) Cr, (e) Zn.

(a)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

The number of unpaired electrons in the given atoms with its diamagnetic or paramagnetic behaviour should be given by knowing their ground-state electron configurations.

Concept Introduction:

An orbital is an area of space in which electrons are orderly filled.  The maximum capacity in any type of orbital is two electrons.  An atomic orbital is defined as the region of space in which the probability of finding the electrons is highest.  It is subdivided into four orbitals such as s, p, d and f orbitals which depend upon the number of electrons present in the nucleus of a particular atom.

There are three basic principles in which orbitals are filled by the electrons.

  1. 1. Aufbau principle: In German, the word 'aufbau' means 'building up'.  The electrons are arranged in various orbitals in the order of increasing energies.
  2. 2. Pauli exclusion principle: An electron does not have all the four quantum numbers.
  3. 3. Hund’s rule: Each orbital is singly engaged with one electron having the maximum same spin capacity after that only pairing occurs.

The electron configuration is the allocation of electrons of an atom in atomic orbitals.  Electronic configuration of a particular atom is written by following the three basic principles.  If all the atomic orbitals are filled by electrons, then the atom is diamagnetic in nature.  Diamagnetic atoms are repelled by the magnetic field.  If one or more unpaired electrons are present in an atom, then that atom is paramagnetic in nature.  Paramagnetic atoms are attracted to the magnetic field.

To find: Count the number of unpaired electrons in Rb and get its magnetic behavior

Answer to Problem 3.103QP

The number of unpaired electron in Rb is 1.  It is paramagnetic in nature

Explanation of Solution

Rb is placed in IA group of the periodic table.  Its atomic number is 37.  Therefore, Rb has 37 electrons in its shells.  Rb is a s-block element.  So, its outermost electrons are located in s-shell.

The noble gas core for Rb is [Kr], where atomic number of Kr is 36.  So, the order of filling beyond the noble gas core is 5s. The electrons in Rb beyond its noble gas core are (37 – 36) = 1 electron.  The one electron enters into the 5s-shell.

All the electrons are placed in the atomic orbitals by following Aufbau principle, Pauli exclusion principle and Hund’s rule.

Chemistry: Atoms First, Chapter 3, Problem 3.103QP , additional homework tip 1

The one electron of Rb occupy the atomic orbitals from lowest energy to highest energy orbitals.  The maximum capacity of each orbital has two electrons which have opposite spins.  s-atomic orbitals have a single shell.  The one electron is going into the 5s-atomic orbital.  Blue colored orbital corresponds to 5s-atomic orbital.

The unpaired electron is present in 5s-atomic orbital.  There is only one unpaired electron in 5s-atomic orbital in the case of Rb-atom.  Therefore, Rb is paramagnetic in nature.

(b)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

The number of unpaired electrons in the given atoms with its diamagnetic or paramagnetic behaviour should be given by knowing their ground-state electron configurations.

Concept Introduction:

An orbital is an area of space in which electrons are orderly filled.  The maximum capacity in any type of orbital is two electrons.  An atomic orbital is defined as the region of space in which the probability of finding the electrons is highest.  It is subdivided into four orbitals such as s, p, d and f orbitals which depend upon the number of electrons present in the nucleus of a particular atom.

There are three basic principles in which orbitals are filled by the electrons.

  1. 1. Aufbau principle: In German, the word 'aufbau' means 'building up'.  The electrons are arranged in various orbitals in the order of increasing energies.
  2. 2. Pauli exclusion principle: An electron does not have all the four quantum numbers.
  3. 3. Hund’s rule: Each orbital is singly engaged with one electron having the maximum same spin capacity after that only pairing occurs.

The electron configuration is the allocation of electrons of an atom in atomic orbitals.  Electronic configuration of a particular atom is written by following the three basic principles.  If all the atomic orbitals are filled by electrons, then the atom is diamagnetic in nature.  Diamagnetic atoms are repelled by the magnetic field.  If one or more unpaired electrons are present in an atom, then that atom is paramagnetic in nature.  Paramagnetic atoms are attracted to the magnetic field.

To find: Count the number of unpaired electrons in As and get its magnetic behavior

Answer to Problem 3.103QP

The number of unpaired electron in As is 1.  It is paramagnetic in nature

Explanation of Solution

Arsenic (As) is placed in VA group of the periodic table. Its atomic number is 33.  Therefore, arsenic has 33 electrons in its shells.  Arsenic (As) is a p-block element.  So, its outermost electrons are located in a p-subshell.

The noble gas core for As is [Ar], where atomic number of Ar is 18.  So, the order of filling beyond the noble gas core is 4s, 3d and 4p. The electrons in As beyond its noble gas core are (33 – 18) = 15 electrons.  These 15 electrons enter into the 4s, 3d and 4p subshells.

Put all the 15 electrons in the atomic orbitals by following Aufbau principle, Pauli exclusion principle and Hund’s rule.

Chemistry: Atoms First, Chapter 3, Problem 3.103QP , additional homework tip 2

All the 15 electrons of arsenic (As) occupy the atomic orbitals from lowest energy to highest energy orbitals.  The maximum capacity of each orbital has two electrons which have opposite spins.  s-atomic orbitals have a single shell whereas p-atomic orbitals have three sub-shells.  d-atomic orbitals have five sub-shells.  The 15 electrons are going into the 4s-atomic orbitals first, followed by 3d-atomic orbitals which is again followed by 4p- atomic orbitals.  Blue colored orbital corresponds to 4s-atomic orbital.  Black colored orbital corresponds to 3d-atomic orbital.  Red colored orbital corresponds to 4p-atomic orbitals.

The unpaired electrons are present in 4p-atomic orbital.  There are three unpaired electrons in 4p-atomic orbital in the case of As-atom.  Therefore, As is paramagnetic in nature.

(c)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

The number of unpaired electrons in the given atoms with its diamagnetic or paramagnetic behaviour should be given by knowing their ground-state electron configurations.

Concept Introduction:

An orbital is an area of space in which electrons are orderly filled.  The maximum capacity in any type of orbital is two electrons.  An atomic orbital is defined as the region of space in which the probability of finding the electrons is highest.  It is subdivided into four orbitals such as s, p, d and f orbitals which depend upon the number of electrons present in the nucleus of a particular atom.

There are three basic principles in which orbitals are filled by the electrons.

  1. 1. Aufbau principle: In German, the word 'aufbau' means 'building up'.  The electrons are arranged in various orbitals in the order of increasing energies.
  2. 2. Pauli exclusion principle: An electron does not have all the four quantum numbers.
  3. 3. Hund’s rule: Each orbital is singly engaged with one electron having the maximum same spin capacity after that only pairing occurs.

The electron configuration is the allocation of electrons of an atom in atomic orbitals.  Electronic configuration of a particular atom is written by following the three basic principles.  If all the atomic orbitals are filled by electrons, then the atom is diamagnetic in nature.  Diamagnetic atoms are repelled by the magnetic field.  If one or more unpaired electrons are present in an atom, then that atom is paramagnetic in nature.  Paramagnetic atoms are attracted to the magnetic field.

To find: Count the number of unpaired electrons in I and get its magnetic behaviour

Answer to Problem 3.103QP

The number of unpaired electron in I is 1.  It is paramagnetic in nature

Explanation of Solution

Iodine (I) is placed in VIIA group of the periodic table. Its atomic number is 53.  Therefore, iodine has 53 electrons in its shells.  Iodine (I) is a p-block element.  So, its outermost electrons are located in a p-subshell.

The noble gas core for I is [Kr], where atomic number of Kr is 36.  So, the order of filling beyond the noble gas core is 5s, 4d and 5p. The electrons in I beyond its noble gas core is (53 – 36) = 17 electrons.  These 17 electrons enter into the 5s, 4d and 5p subshells.

Put all the 17 electrons in the atomic orbitals by following Aufbau principle, Pauli exclusion principle and Hund’s rule.

Chemistry: Atoms First, Chapter 3, Problem 3.103QP , additional homework tip 3

All the 17 electrons of iodine (I) occupy the atomic orbitals from lowest energy to highest energy orbitals.  The maximum capacity of each orbital has two electrons which have opposite spins.  s-atomic orbitals have a single shell whereas p-atomic orbitals have three sub-shells.  d-atomic orbitals have five sub-shells.  The 17 electrons are going into the 5s-atomic orbitals first, followed by 4d-atomic orbitals which is again followed by 5p-atomic orbitals.  Blue colored orbital corresponds to 5s-atomic orbital.  Black colored orbital corresponds to 4d-atomic orbital.  Red colored orbital corresponds to 5p-atomic orbitals.

The unpaired electron is present in 5p-atomic orbital.  There is only one unpaired electron in 5p-atomic orbital in the case of I-atom.  Therefore, I is paramagnetic in nature.

(d)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

The number of unpaired electrons in the given atoms with its diamagnetic or paramagnetic behaviour should be given by knowing their ground-state electron configurations.

Concept Introduction:

An orbital is an area of space in which electrons are orderly filled.  The maximum capacity in any type of orbital is two electrons.  An atomic orbital is defined as the region of space in which the probability of finding the electrons is highest.  It is subdivided into four orbitals such as s, p, d and f orbitals which depend upon the number of electrons present in the nucleus of a particular atom.

There are three basic principles in which orbitals are filled by the electrons.

  1. 1. Aufbau principle: In German, the word 'aufbau' means 'building up'.  The electrons are arranged in various orbitals in the order of increasing energies.
  2. 2. Pauli exclusion principle: An electron does not have all the four quantum numbers.
  3. 3. Hund’s rule: Each orbital is singly engaged with one electron having the maximum same spin capacity after that only pairing occurs.

The electron configuration is the allocation of electrons of an atom in atomic orbitals.  Electronic configuration of a particular atom is written by following the three basic principles.  If all the atomic orbitals are filled by electrons, then the atom is diamagnetic in nature.  Diamagnetic atoms are repelled by the magnetic field.  If one or more unpaired electrons are present in an atom, then that atom is paramagnetic in nature.  Paramagnetic atoms are attracted to the magnetic field.

To find: Count the number of unpaired electrons in Cr and get its magnetic behavior

Answer to Problem 3.103QP

The number of unpaired electron in Cr is 6.  It is paramagnetic in nature

Explanation of Solution

Cr is placed in VIB group of the periodic table.  Its atomic number is 24.  Therefore, Cr has 24 electrons in its shells.  Cr is d-block element.  So, its outermost electrons are located in d-subshells.

The noble gas core for Cr is [Ar], where atomic number of Ar is 18.  So, the order of filling beyond the noble gas core is 4s and 3d. The electrons in Cr beyond its noble gas core are (24 – 18) = 6 electrons.  The six electrons enter into the 4s and 3d-subshells.

Put all the electrons in the atomic orbitals by following Aufbau principle, Pauli exclusion principle and Hund’s rule

Chemistry: Atoms First, Chapter 3, Problem 3.103QP , additional homework tip 4

The six electrons of Cr occupy the atomic orbitals from lowest energy to highest energy orbitals.  The maximum capacity of each orbital has two electrons which have opposite spins.  s-atomic orbitals have a single shell whereas d-atomic orbitals have five subshells.  The six electrons are going into the 4s-atomic orbital followed by 3d-atomic orbital.  Blue colored orbital corresponds to 4s-atomic orbital.  Black colored orbital corresponds to 3d-atomic orbital.  One of the electrons present in 4s-atomic orbital is jumped into the 3d-atomic orbital because half-filled 3d-atomic orbital is more stable.

The unpaired electrons are present in 4s and 3d-atomic orbitals.  There are six unpaired electrons in the case of Cr-atom.  Therefore, Cr is paramagnetic in nature.

(e)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

The number of unpaired electrons in the given atoms with its diamagnetic or paramagnetic behaviour should be given by knowing their ground-state electron configurations.

Concept Introduction:

An orbital is an area of space in which electrons are orderly filled.  The maximum capacity in any type of orbital is two electrons.  An atomic orbital is defined as the region of space in which the probability of finding the electrons is highest.  It is subdivided into four orbitals such as s, p, d and f orbitals which depend upon the number of electrons present in the nucleus of a particular atom.

There are three basic principles in which orbitals are filled by the electrons.

  1. 1. Aufbau principle: In German, the word 'aufbau' means 'building up'.  The electrons are arranged in various orbitals in the order of increasing energies.
  2. 2. Pauli exclusion principle: An electron does not have all the four quantum numbers.
  3. 3. Hund’s rule: Each orbital is singly engaged with one electron having the maximum same spin capacity after that only pairing occurs.

The electron configuration is the allocation of electrons of an atom in atomic orbitals.  Electronic configuration of a particular atom is written by following the three basic principles.  If all the atomic orbitals are filled by electrons, then the atom is diamagnetic in nature.  Diamagnetic atoms are repelled by the magnetic field.  If one or more unpaired electrons are present in an atom, then that atom is paramagnetic in nature.  Paramagnetic atoms are attracted to the magnetic field.

To find: Count the number of unpaired electrons in Zn and get its magnetic behavior

Answer to Problem 3.103QP

There is no unpaired electron in Zn.  It is diamagnetic in nature

Explanation of Solution

Zn is placed in IIB group of the periodic table. Its atomic number is 30.  Therefore, Zn has 30 electrons in its shells.  Zn is a d-block element.  So, its outermost electrons are located in a d-subshell.

The noble gas core for Zn is [Ar], where atomic number of Ar is 18.  So, the order of filling beyond the noble gas core is 4s and 3d. The electrons in Zn beyond its noble gas core are (30 – 18) = 12 electrons.  These 12 electrons enter into the 4s and 3d subshells.

Put all the 12 electrons in the atomic orbitals by following Aufbau principle, Pauli exclusion principle and Hund’s rule.

Chemistry: Atoms First, Chapter 3, Problem 3.103QP , additional homework tip 5

All the 12 electrons of Zn occupy the atomic orbitals from lowest energy to highest energy orbitals.  The maximum capacity of each orbital has two electrons which have opposite spins.  s-atomic orbitals have a single shell whereas d-atomic orbitals have five sub-shells.  The 12 electrons are going into the 4s-atomic orbitals first, followed by 3d-atomic orbitals.  Blue colored orbital corresponds to 4s-atomic orbital.  Black colored orbital corresponds to 3d-atomic orbital.

There is no unpaired electron present in 4s and 3d-atomic orbitals.  Therefore, Zn is diamagnetic in nature.

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Chapter 3 Solutions

Chemistry: Atoms First

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