Chemical Elements – Thermal Properties

Francium – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Francium is — J/g K.

Latent Heat of Fusion of Francium is — kJ/mol.

Latent Heat of Vaporization of Francium is — kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Francium – Properties

Element	Francium
Atomic Number	87
Symbol	Fr
Element Category	Alkali Metal
Phase at STP	Solid
Atomic Mass [amu]	223
Density at STP [g/cm3]	—
Electron Configuration	[Rn] 7s1
Possible Oxidation States	+1
Electron Affinity [kJ/mol]	—
Electronegativity [Pauling scale]	0.7
1st Ionization Energy [eV]	3.94
Year of Discovery	1939
Discoverer	Perey, Marguerite
Thermal properties
Melting Point [Celsius scale]	27
Boiling Point [Celsius scale]	677
Thermal Conductivity [W/m K]	—
Specific Heat [J/g K]	—
Heat of Fusion [kJ/mol]	—
Heat of Vaporization [kJ/mol]	—

 

Francium 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

–
–
–

Radium – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Radium is 0.12 J/g K.

Latent Heat of Fusion of Radium is — kJ/mol.

Latent Heat of Vaporization of Radium is — kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Radium – Properties

Element	Radium
Atomic Number	88
Symbol	Ra
Element Category	Alkaline Earth Metal
Phase at STP	Solid
Atomic Mass [amu]	226
Density at STP [g/cm3]	5
Electron Configuration	[Rn] 7s2
Possible Oxidation States	+2
Electron Affinity [kJ/mol]	—
Electronegativity [Pauling scale]	0.9
1st Ionization Energy [eV]	5.2789
Year of Discovery	1898
Discoverer	Curie, Marie & Pierre
Thermal properties
Melting Point [Celsius scale]	700
Boiling Point [Celsius scale]	1140
Thermal Conductivity [W/m K]	19
Specific Heat [J/g K]	0.12
Heat of Fusion [kJ/mol]	—
Heat of Vaporization [kJ/mol]	—

 

Radium 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

–
–
–

Astatine – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Astatine is — J/g K.

Latent Heat of Fusion of Astatine is — kJ/mol.

Latent Heat of Vaporization of Astatine is — kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Astatine – Properties

Element	Astatine
Atomic Number	85
Symbol	At
Element Category	Metalloids
Phase at STP	Solid
Atomic Mass [amu]	210
Density at STP [g/cm3]	—
Electron Configuration	[Hg] 6p5
Possible Oxidation States
Electron Affinity [kJ/mol]	270.1
Electronegativity [Pauling scale]	2.2
1st Ionization Energy [eV]	9.5
Year of Discovery	1940
Discoverer	Corson, Dale R. & Mackenzie, K. R.
Thermal properties
Melting Point [Celsius scale]	302
Boiling Point [Celsius scale]	337
Thermal Conductivity [W/m K]	2
Specific Heat [J/g K]	—
Heat of Fusion [kJ/mol]	—
Heat of Vaporization [kJ/mol]	—

 

Astatine 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

–
–
–

Radon – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Radon is 0.09 J/g K.

Latent Heat of Fusion of Radon is 2.89 kJ/mol.

Latent Heat of Vaporization of Radon is 16.4 kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Radon – Properties

Element	Radon
Atomic Number	86
Symbol	Rn
Element Category	Noble Gas
Phase at STP	Gas
Atomic Mass [amu]	222
Density at STP [g/cm3]	9.73
Electron Configuration	[Hg] 6p6
Possible Oxidation States	0
Electron Affinity [kJ/mol]	—
Electronegativity [Pauling scale]	—
1st Ionization Energy [eV]	10.7485
Year of Discovery	1900
Discoverer	Dorn, Friedrich Ernst
Thermal properties
Melting Point [Celsius scale]	-71
Boiling Point [Celsius scale]	-61.8
Thermal Conductivity [W/m K]	0.00361
Specific Heat [J/g K]	0.09
Heat of Fusion [kJ/mol]	2.89
Heat of Vaporization [kJ/mol]	16.4

 

Radon 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

–
–
–

Bismuth – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Bismuth is 0.12 J/g K.

Latent Heat of Fusion of Bismuth is 11.3 kJ/mol.

Latent Heat of Vaporization of Bismuth is 104.8 kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Bismuth – Properties

Element	Bismuth
Atomic Number	83
Symbol	Bi
Element Category	Poor Metal
Phase at STP	Solid
Atomic Mass [amu]	208.9804
Density at STP [g/cm3]	9.78
Electron Configuration	[Hg] 6p3
Possible Oxidation States	+3,5
Electron Affinity [kJ/mol]	91.2
Electronegativity [Pauling scale]	2.02
1st Ionization Energy [eV]	7.289
Year of Discovery	unknown
Discoverer	Geoffroy, Claude
Thermal properties
Melting Point [Celsius scale]	271
Boiling Point [Celsius scale]	1560
Thermal Conductivity [W/m K]	8
Specific Heat [J/g K]	0.12
Heat of Fusion [kJ/mol]	11.3
Heat of Vaporization [kJ/mol]	104.8

 

Bismuth 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

–
–
–

Polonium – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Polonium is 0.12 J/g K.

Latent Heat of Fusion of Polonium is — kJ/mol.

Latent Heat of Vaporization of Polonium is — kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Polonium – Properties

Element	Polonium
Atomic Number	84
Symbol	Po
Element Category	Metalloids
Phase at STP	Solid
Atomic Mass [amu]	209
Density at STP [g/cm3]	9.196
Electron Configuration	[Hg] 6p4
Possible Oxidation States	+2,4
Electron Affinity [kJ/mol]	183.3
Electronegativity [Pauling scale]	2
1st Ionization Energy [eV]	8.4167
Year of Discovery	1898
Discoverer	Curie, Marie & Pierre
Thermal properties
Melting Point [Celsius scale]	254
Boiling Point [Celsius scale]	962
Thermal Conductivity [W/m K]	—
Specific Heat [J/g K]	0.12
Heat of Fusion [kJ/mol]	—
Heat of Vaporization [kJ/mol]	—

 

Polonium 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

–
–
–

Thallium – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Thallium is 0.13 J/g K.

Latent Heat of Fusion of Thallium is 4.142 kJ/mol.

Latent Heat of Vaporization of Thallium is 164.1 kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Thallium – Properties

Element	Thallium
Atomic Number	81
Symbol	Tl
Element Category	Poor Metal
Phase at STP	Solid
Atomic Mass [amu]	204.3833
Density at STP [g/cm3]	11.85
Electron Configuration	[Hg] 6p1
Possible Oxidation States	+1,3
Electron Affinity [kJ/mol]	19.2
Electronegativity [Pauling scale]	1.62
1st Ionization Energy [eV]	6.1083
Year of Discovery	1861
Discoverer	Crookes, William
Thermal properties
Melting Point [Celsius scale]	303
Boiling Point [Celsius scale]	1457
Thermal Conductivity [W/m K]	46
Specific Heat [J/g K]	0.13
Heat of Fusion [kJ/mol]	4.142
Heat of Vaporization [kJ/mol]	164.1

 

Thallium 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

–
–
–

Lead – Specific Heat, Latent Heat of Fusion, Latent Heat of Vaporization

Specific heat of Lead is 0.13 J/g K.

Latent Heat of Fusion of Lead is 4.799 kJ/mol.

Latent Heat of Vaporization of Lead is 177.7 kJ/mol.

Specific Heat

Specific heat, or specific heat capacity, is a property related to internal energy that is very important in thermodynamics. The intensive properties c_v and c_p are defined for pure, simple compressible substances as partial derivatives of the internal energy u(T, v) and enthalpy h(T, p), respectively:

where the subscripts v and p denote the variables held fixed during differentiation. The properties c_v and c_p are referred to as specific heats(or heat capacities) because under certain special conditions, they relate the temperature change of a system to the amount of energy added by heat transfer. Their SI units are J/kg.K or J/mol K.

Different substances are affected to different magnitudes by the addition of heat. When a given amount of heat is added to different substances, their temperatures increase by different amounts.

Heat capacity is an extensive property of matter, meaning it is proportional to the size of the system. Heat capacity C has the unit of energy per degree or energy per kelvin. When expressing the same phenomenon as an intensive property, the heat capacity is divided by the amount of substance, mass, or volume. Thus the quantity is independent of the size or extent of the sample.

 

Latent Heat of Vaporization

In general, when a material changes phase from solid to liquid or from liquid to gas, a certain amount of energy is involved in this change of phase. In the case of liquid to gas phase change, this amount of energy is known as the enthalpy of vaporization (symbol ∆H_vap; unit: J), also known as the (latent) heat of vaporization or heat of evaporation. As an example, see the figure, which describes the phase transitions of water.

Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the gas (the pΔV work). When latent heat is added, no temperature change occurs. The enthalpy of vaporization is a function of the pressure at which that transformation takes place.

Latent Heat of Fusion

In the case of solid to liquid phase change, the change in enthalpy required to change its state is known as the enthalpy of fusion (symbol ∆H_fus; unit: J), also known as the (latent) heat of fusion. Latent heat is the amount of heat added to or removed from a substance to produce a phase change. This energy breaks down the attractive intermolecular forces and must provide the energy necessary to expand the system (the pΔV work).

The liquid phase has higher internal energy than the solid phase. This means energy must be supplied to a solid to melt it. Energy is released from a liquid when it freezes because the molecules in the liquid experience weaker intermolecular forces and have higher potential energy (a kind of bond-dissociation energy for intermolecular forces).

The temperature at which the phase transition occurs is the melting point.

When latent heat is added, no temperature change occurs. The enthalpy of fusion is a function of the pressure at which that transformation takes place. By convention, the pressure is assumed to be 1 atm (101.325 kPa) unless otherwise specified.

Lead – Properties

Element	Lead
Atomic Number	82
Symbol	Pb
Element Category	Poor Metal
Phase at STP	Solid
Atomic Mass [amu]	207.2
Density at STP [g/cm3]	11.34
Electron Configuration	[Hg] 6p2
Possible Oxidation States	+2,4
Electron Affinity [kJ/mol]	35.1
Electronegativity [Pauling scale]	2.33
1st Ionization Energy [eV]	7.4167
Year of Discovery	unknown
Discoverer	unknown
Thermal properties
Melting Point [Celsius scale]	327.5
Boiling Point [Celsius scale]	1740
Thermal Conductivity [W/m K]	35
Specific Heat [J/g K]	0.13
Heat of Fusion [kJ/mol]	4.799
Heat of Vaporization [kJ/mol]	177.7

 

Lead 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

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