Chemical Elements – Electron Shell

Electron Affinity and Electronegativity of Cobalt

Electron Affinity of Cobalt is 63.7 kJ/mol.

Electronegativity of Cobalt is 1.88.

First Ionization Energy of Cobalt is 7.881 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Cobalt in the gas phase, for example, gives off energy when it gains an electron to form an ion of Cobalt.

Co + e^– → Co^–        – ∆H = Affinity = 63.7 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Cobalt is:

χ = 1.88

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Cobalt

First Ionization Energy of Cobalt is 7.881 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Cobalt atom, for example, requires the following ionization energy to remove the outermost electron.

Co + IE → Co⁺ + e⁻        IE = 7.881 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Cobalt – Properties

Element	Cobalt
Atomic Number	27
Symbol	Co
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	58.9332
Density at STP [g/cm3]	8.9
Electron Configuration	[Ar] 3d7 4s2
Possible Oxidation States	+2,3
Electron Affinity [kJ/mol]	63.7
Electronegativity [Pauling scale]	1.88
1st Ionization Energy [eV]	7.881
Year of Discovery	1735
Discoverer	Brandt, Georg
Thermal properties
Melting Point [Celsius scale]	1495
Boiling Point [Celsius scale]	2927
Thermal Conductivity [W/m K]	100
Specific Heat [J/g K]	0.42
Heat of Fusion [kJ/mol]	16.19
Heat of Vaporization [kJ/mol]	376.5

 

Cobalt in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Nickel

Electron Affinity of Nickel is 112 kJ/mol.

Electronegativity of Nickel is 1.91.

First Ionization Energy of Nickel is 7.6398 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Nickel in the gas phase, for example, gives off energy when it gains an electron to form an ion of Nickel.

Ni + e^– → Ni^–        – ∆H = Affinity = 112 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Nickel is:

χ = 1.91

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Nickel

First Ionization Energy of Nickel is 7.6398 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Nickel atom, for example, requires the following ionization energy to remove the outermost electron.

Ni + IE → Ni⁺ + e⁻        IE = 7.6398 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Nickel – Properties

Element	Nickel
Atomic Number	28
Symbol	Ni
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	58.6934
Density at STP [g/cm3]	8.908
Electron Configuration	[Ar] 3d8 4s2
Possible Oxidation States	+2,3
Electron Affinity [kJ/mol]	112
Electronegativity [Pauling scale]	1.91
1st Ionization Energy [eV]	7.6398
Year of Discovery	1751
Discoverer	Cronstedt, Alex Fredrik
Thermal properties
Melting Point [Celsius scale]	1455
Boiling Point [Celsius scale]	2913
Thermal Conductivity [W/m K]	90.7
Specific Heat [J/g K]	0.44
Heat of Fusion [kJ/mol]	17.47
Heat of Vaporization [kJ/mol]	370.4

 

Nickel in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Manganese

Electron Affinity of Manganese is — kJ/mol.

Electronegativity of Manganese is 1.55.

First Ionization Energy of Manganese is 7.434 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Manganese in the gas phase, for example, gives off energy when it gains an electron to form an ion of Manganese.

Mn + e^– → Mn^–        – ∆H = Affinity = — kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Manganese is:

χ = 1.55

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Manganese

First Ionization Energy of Manganese is 7.434 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Manganese atom, for example, requires the following ionization energy to remove the outermost electron.

Mn + IE → Mn⁺ + e⁻        IE = 7.434 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Manganese – Properties

Element	Manganese
Atomic Number	25
Symbol	Mn
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	54.938049
Density at STP [g/cm3]	7.47
Electron Configuration	[Ar] 3d5 4s2
Possible Oxidation States	+2,3,4,7
Electron Affinity [kJ/mol]	—
Electronegativity [Pauling scale]	1.55
1st Ionization Energy [eV]	7.434
Year of Discovery	1774
Discoverer	Gahn, Johan Gottlieb
Thermal properties
Melting Point [Celsius scale]	1246
Boiling Point [Celsius scale]	2061
Thermal Conductivity [W/m K]	7.82
Specific Heat [J/g K]	0.48
Heat of Fusion [kJ/mol]	12.05
Heat of Vaporization [kJ/mol]	266

 

Manganese in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Iron

Electron Affinity of Iron is 15.7 kJ/mol.

Electronegativity of Iron is 1.83.

First Ionization Energy of Iron is 7.9024 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Iron in the gas phase, for example, gives off energy when it gains an electron to form an ion of Iron.

Fe + e^– → Fe^–        – ∆H = Affinity = 15.7 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Iron is:

χ = 1.83

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Iron

First Ionization Energy of Iron is 7.9024 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Iron atom, for example, requires the following ionization energy to remove the outermost electron.

Fe + IE → Fe⁺ + e⁻        IE = 7.9024 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Iron – Properties

Element	Iron
Atomic Number	26
Symbol	Fe
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	55.845
Density at STP [g/cm3]	7.874
Electron Configuration	[Ar] 3d6 4s2
Possible Oxidation States	+2,3
Electron Affinity [kJ/mol]	15.7
Electronegativity [Pauling scale]	1.83
1st Ionization Energy [eV]	7.9024
Year of Discovery	unknown
Discoverer	unknown
Thermal properties
Melting Point [Celsius scale]	1538
Boiling Point [Celsius scale]	2861
Thermal Conductivity [W/m K]	80.2
Specific Heat [J/g K]	0.44
Heat of Fusion [kJ/mol]	13.8
Heat of Vaporization [kJ/mol]	349.6

 

Iron in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Vanadium

Electron Affinity of Vanadium is 50.6 kJ/mol.

Electronegativity of Vanadium is 1.63.

First Ionization Energy of Vanadium is 6.7463 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Vanadium in the gas phase, for example, gives off energy when it gains an electron to form an ion of Vanadium.

V + e^– → V^–        – ∆H = Affinity = 50.6 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Vanadium is:

χ = 1.63

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Vanadium

First Ionization Energy of Vanadium is 6.7463 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Vanadium atom, for example, requires the following ionization energy to remove the outermost electron.

V + IE → V⁺ + e⁻        IE = 6.7463 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Vanadium – Properties

Element	Vanadium
Atomic Number	23
Symbol	V
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	50.9415
Density at STP [g/cm3]	6.11
Electron Configuration	[Ar] 3d3 4s2
Possible Oxidation States	+2,3,4,5
Electron Affinity [kJ/mol]	50.6
Electronegativity [Pauling scale]	1.63
1st Ionization Energy [eV]	6.7463
Year of Discovery	1801
Discoverer	Del Rio, Andrés Manuel (1801) & Sefström, Nils Gabriel (1830)
Thermal properties
Melting Point [Celsius scale]	1910
Boiling Point [Celsius scale]	3407
Thermal Conductivity [W/m K]	30.7
Specific Heat [J/g K]	0.49
Heat of Fusion [kJ/mol]	20.9
Heat of Vaporization [kJ/mol]	0.452

 

Vanadium in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Chromium

Electron Affinity of Chromium is 64.3 kJ/mol.

Electronegativity of Chromium is 1.66.

First Ionization Energy of Chromium is 6.7666 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Chromium in the gas phase, for example, gives off energy when it gains an electron to form an ion of Chromium.

Cr + e^– → Cr^–        – ∆H = Affinity = 64.3 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Chromium is:

χ = 1.66

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Chromium

First Ionization Energy of Chromium is 6.7666 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Chromium atom, for example, requires the following ionization energy to remove the outermost electron.

Cr + IE → Cr⁺ + e⁻        IE = 6.7666 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Chromium – Properties

Element	Chromium
Atomic Number	24
Symbol	Cr
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	51.9961
Density at STP [g/cm3]	7.14
Electron Configuration	[Ar] 3d5 4s1
Possible Oxidation States	+2,3,6
Electron Affinity [kJ/mol]	64.3
Electronegativity [Pauling scale]	1.66
1st Ionization Energy [eV]	6.7666
Year of Discovery	1797
Discoverer	Vauquelin
Thermal properties
Melting Point [Celsius scale]	1907
Boiling Point [Celsius scale]	2671
Thermal Conductivity [W/m K]	93.7
Specific Heat [J/g K]	0.45
Heat of Fusion [kJ/mol]	16.9
Heat of Vaporization [kJ/mol]	344.3

 

Chromium in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Scandium

Electron Affinity of Scandium is 18.1 kJ/mol.

Electronegativity of Scandium is 1.36.

First Ionization Energy of Scandium is 6.5614 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Scandium in the gas phase, for example, gives off energy when it gains an electron to form an ion of Scandium.

Sc + e^– → Sc^–        – ∆H = Affinity = 18.1 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Scandium is:

χ = 1.36

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Scandium

First Ionization Energy of Scandium is 6.5614 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Scandium atom, for example, requires the following ionization energy to remove the outermost electron.

Sc + IE → Sc⁺ + e⁻        IE = 6.5614 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Scandium – Properties

Element	Scandium
Atomic Number	21
Symbol	Sc
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	44.9559
Density at STP [g/cm3]	2.985
Electron Configuration	[Ar] 3d1 4s2
Possible Oxidation States	+3
Electron Affinity [kJ/mol]	18.1
Electronegativity [Pauling scale]	1.36
1st Ionization Energy [eV]	6.5614
Year of Discovery	1879
Discoverer	Nilson, Lars Fredrik
Thermal properties
Melting Point [Celsius scale]	1541
Boiling Point [Celsius scale]	2830
Thermal Conductivity [W/m K]	15.8
Specific Heat [J/g K]	0.6
Heat of Fusion [kJ/mol]	14.1
Heat of Vaporization [kJ/mol]	314.2

 

Scandium in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–

Electron Affinity and Electronegativity of Titanium

Electron Affinity of Titanium is 7.6 kJ/mol.

Electronegativity of Titanium is 1.54.

First Ionization Energy of Titanium is 6.8282 eV.

Electron Affinity

In chemistry and atomic physics, the electron affinity of an atom or molecule is defined as:

the change in energy (in kJ/mole) of a neutral atom or molecule (in the gaseous phase) when an electron is added to the atom to form a negative ion.

X + e^– → X^– + energy        Affinity = – ∆H

In other words, it can be expressed as the neutral atom’s likelihood of gaining an electron. Note that ionization energies measure the tendency of a neutral atom to resist the loss of electrons. Electron affinities are more difficult to measure than ionization energies.

An atom of Titanium in the gas phase, for example, gives off energy when it gains an electron to form an ion of Titanium.

Ti + e^– → Ti^–        – ∆H = Affinity = 7.6 kJ/mol

Electron affinity is one of the most important parameters that guide chemical reactivity. Molecules with high electron affinity form very stable negative ions which are important in the chemical and health industry as they purify the air, lift mood, and most importantly, act as strong oxidizing agents. To use electron affinities properly, it is essential to keep track of signs. When an electron is added to a neutral atom, energy is released. This affinity is known as the first electron affinity, and these energies are negative. By convention, the negative sign shows a release of energy. However, more energy is required to add an electron to a negative ion which overwhelms any release of energy from the electron attachment process. This affinity is known as the second electron affinity, and these energies are positive.

Halogens have the highest electron affinities among all elements. In fact, the electron affinity of Cl, 3.62 eV is the largest of all the elements. Superhalogens are molecules that have electron affinities (EA) greater than that of Cl, the element with the highest EA (3.62 eV).

It is well known that noble gases have closed electronic shell structure and hence have high ionization potentials and low electron affinities, due to which they are chemically inert and resistant to salt formation under most conditions.

Affinities of Nonmetals vs. Affinities of Metals

• Metals: Metals like to lose valence electrons to form cations to have a fully stable shell. The electron affinity of metals is lower than that of nonmetals. Mercury most weakly attracts an extra electron.
• Nonmetals: Generally, nonmetals have more positive electron affinity than metals. Nonmetals like to gain electrons to form anions to have a fully stable electron shell. Chlorine most strongly attracts extra electrons. The electron affinities of the noble gases have not been conclusively measured, so they may or may not have slightly negative values.

Learn more about electron affinities.

Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom to attract electrons towards this atom. For this purpose, a dimensionless quantity, the Pauling scale, symbol χ, is the most commonly used.

The electronegativity of Titanium is:

χ = 1.54

In general, an atom’s electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it.

As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Even so, the electronegativity of an atom is strongly correlated with the first ionization energy, and negatively correlated with the electron affinity. Electrons with low ionization energies have low electronegativities because their nuclei do not exert a strong attractive force on electrons. Elements with high ionization energies have high electronegativities due to the strong pull exerted by the positive nucleus on the negative electrons. Therefore the electronegativity is greatest at the top-right of the periodic table and decreases toward the bottom-left.

Caesium is the least electronegative element (0.79); fluorine is the most (3.98).

Learn more about electronegativities.

 

First Ionization Energy of Titanium

First Ionization Energy of Titanium is 6.8282 eV.

Ionization energy, also called ionization potential, is the energy necessary to remove an electron from the neutral atom.

X + energy → X⁺ + e⁻

where X is any atom or molecule capable of being ionized, X⁺ is that atom or molecule with an electron removed (positive ion), and e⁻ is the removed electron.

A Titanium atom, for example, requires the following ionization energy to remove the outermost electron.

Ti + IE → Ti⁺ + e⁻        IE = 6.8282 eV

The ionization energy associated with removal of the first electron is most commonly used. The nth ionization energy refers to the amount of energy required to remove an electron from the species with a charge of (n-1).

1st ionization energy

X → X⁺ + e⁻

2nd ionization energy

X⁺ → X²⁺ + e⁻

3rd ionization energy

X²⁺ → X³⁺ + e⁻

Ionization Energy for different Elements

There is ionization energy for each successive electron removed. The electrons that circle the nucleus move in fairly well-defined orbits. Some of these electrons are more tightly bound in the atom than others. For example, only 7.38 eV is required to remove the outermost electron from a lead atom, while 88,000 eV is required to remove the innermost electron. Helps to understand the reactivity of elements (especially metals, which lose electrons).

In general, the ionization energy increases moving up a group and moving left to right across a period. Moreover:

• Ionization energy is lowest for the alkali metals which have a single electron outside a closed shell.
• Ionization energy increases across a row on the periodic maximum for the noble gases which have closed shells.

For example, sodium requires only 496 kJ/mol or 5.14 eV/atom to ionize it. On the other hand neon, the noble gas, immediately preceding it in the periodic table, requires 2081 kJ/mol or 21.56 eV/atom.

Learn more about ionization energy.

Titanium – Properties

Element	Titanium
Atomic Number	22
Symbol	Ti
Element Category	Transition Metal
Phase at STP	Solid
Atomic Mass [amu]	47.867
Density at STP [g/cm3]	4.507
Electron Configuration	[Ar] 3d2 4s2
Possible Oxidation States	+2,3,4
Electron Affinity [kJ/mol]	7.6
Electronegativity [Pauling scale]	1.54
1st Ionization Energy [eV]	6.8282
Year of Discovery	1791
Discoverer	Gregor, William
Thermal properties
Melting Point [Celsius scale]	1668
Boiling Point [Celsius scale]	3287
Thermal Conductivity [W/m K]	21.9
Specific Heat [J/g K]	0.52
Heat of Fusion [kJ/mol]	15.45
Heat of Vaporization [kJ/mol]	421

 

Titanium in Periodic Table

Hydro­gen1H

He­lium2He

Lith­ium3Li

Beryl­lium4Be

Boron5B

Carbon6C

Nitro­gen7N

Oxy­gen8O

Fluor­ine9F

Neon10Ne

So­dium11Na

Magne­sium12Mg

Alumin­ium13Al

Sili­con14Si

Phos­phorus15P

Sulfur16S

Chlor­ine17Cl

Argon18Ar

Potas­sium19K

Cal­cium20Ca

Scan­dium21Sc

Tita­nium22Ti

Vana­dium23V

Chrom­ium24Cr

Manga­nese25Mn

Iron26Fe

Cobalt27Co

Nickel28Ni

Copper29Cu

Zinc30Zn

Gallium31Ga

Germa­nium32Ge

Arsenic33As

Sele­nium34Se

Bromine35Br

Kryp­ton36Kr

Rubid­ium37Rb

Stront­ium38Sr

Yttrium39Y

Zirco­nium40Zr

Nio­bium41Nb

Molyb­denum42Mo

Tech­netium43Tc

Ruthe­nium44Ru

Rho­dium45Rh

Pallad­ium46Pd

Silver47Ag

Cad­mium48Cd

Indium49In

Tin50Sn

Anti­mony51Sb

Tellur­ium52Te

Iodine53I

Xenon54Xe

Cae­sium55Cs

Ba­rium56Ba

Lan­thanum57La

Haf­nium72Hf

Tanta­lum73Ta

Tung­sten74W

Rhe­nium75Re

Os­mium76Os

Iridium77Ir

Plat­inum78Pt

Gold79Au

Mer­cury80Hg

Thallium81Tl

Lead82Pb

Bis­muth83Bi

Polo­nium84Po

Asta­tine85At

Radon86Rn

Fran­cium87Fr

Ra­dium88Ra

Actin­ium89Ac

Ruther­fordium104Rf

Dub­nium105Db

Sea­borgium106Sg

Bohr­ium107Bh

Has­sium108Hs

Meit­nerium109Mt

Darm­stadtium110Ds

Roent­genium111Rg

Coper­nicium112Cn

Nihon­ium113Nh

Flerov­ium114Fl

Moscov­ium115Mc

Liver­morium116Lv

Tenness­ine117Ts

Oga­nesson118Og

Cerium58Ce

Praseo­dymium59Pr

Neo­dymium60Nd

Prome­thium61Pm

Sama­rium62Sm

Europ­ium63Eu

Gadolin­ium64Gd

Ter­bium65Tb

Dyspro­sium66Dy

Hol­mium67Ho

Erbium68Er

Thulium69Tm

Ytter­bium70Yb

Lute­tium71Lu

Thor­ium90Th

Protac­tinium91Pa

Ura­nium92U

Neptu­nium93Np

Pluto­nium94Pu

Ameri­cium95Am

Curium96Cm

Berkel­ium97Bk

Califor­nium98Cf

Einstei­nium99Es

Fer­mium100Fm

Mende­levium101Md

Nobel­ium102No

Lawren­cium103Lr

–
–
–