metallicbondingfix-230531114810-8ca180d7.pdf
Isomorphisme
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About This Presentation
Orbitales métalliques, liaisons métalliques
Slide Content
METALLIC BONDING
IkatanKimia
IkatanKimia
METALS
The properties of metals
Metals have high melting points
Metals conduct heat and
electricity
Metals are hard, not brittle
Metals are shining/lustrous
Metals have high melting points
Metals conduct heat and
electricity
Metals are hard, not brittle
Metals are shining/lustrous
sea of electrons
metal ions
The atoms in a pure metal are in tightly-
packed layers, which form
a regular latticestructure.
The outer electrons of the metal atoms
separate from the atoms
and create a ‘sea of electrons’.
These electrons are delocalized,
and so are free to move through
the whole structure.
The metal atoms become positively charged ions and
are attracted to the sea of electrons. This attraction is
called metallic bonding.
metal ions
The atoms in a pure metal are in tightly-
packed layers, which form
a regular latticestructure.
The outer electrons of the metal atoms
separate from the atoms
and create a ‘sea of electrons’.
These electrons are delocalized,
and so are free to move through
the whole structure.
The metal atoms become positively charged ions and
are attracted to the sea of electrons. This attraction is
called metallic bonding.
Metals often have high melting points
and boiling points. Gold, for example,
has a melting point of 1064 °C and a
boiling point of 2807 °C.
The properties of metals are related to their
structure.
In metal extraction and other industrial processes, furnaces often run
continuously to maintain the high temperatures needed to work with molten
metals.
This property is due to the strong attraction
between the positively-charged metal ions
and the sea of electrons.
Why do metals have high
melting points?
and boiling points. Gold, for example,
has a melting point of 1064 °C and a
boiling point of 2807 °C.
The properties of metals are related to their
structure.
In metal extraction and other industrial processes, furnaces often run
continuously to maintain the high temperatures needed to work with molten
metals.
This property is due to the strong attraction
between the positively-charged metal ions
and the sea of electrons.
Why do metals have high
melting points?
Semakinkuatikatanlogammakasemakintinggipula
titikleburdantitikdidihnya.
Logam Titiklebur(
o
C)Titikdidih(
o
C)
Na 97,8 892
Mg 651 1107
Al 660 2467
Logam Jari2 atom
logam(pm)
KationlogamJari2 kation
logam(pm)
Titiklebur
(
o
C)
Titikdidih
(
o
C)
Li 157 Li
+
106 180 1330
Na 191 Na
+
132 97,8 892
K 235 K
+
165 63,7 774
Rb 250 Rb
+
175 38,9 688
Cs 272 Cs
+
188 29,7 690
titikleburdantitikdidihnya.
Logam Titiklebur(
o
C)Titikdidih(
o
C)
Na 97,8 892
Mg 651 1107
Al 660 2467
Logam Jari2 atom
logam(pm)
KationlogamJari2 kation
logam(pm)
Titiklebur
(
o
C)
Titikdidih
(
o
C)
Li 157 Li
+
106 180 1330
Na 191 Na
+
132 97,8 892
K 235 K
+
165 63,7 774
Rb 250 Rb
+
175 38,9 688
Cs 272 Cs
+
188 29,7 690
Delocalized electrons in metallic bonding
allow metals to conduct heat and
electricity.
For example, when a metal is heated,
electrons are able to gain kinetic energy in
hotter areas of the metal and are able to
quickly transfer it to other parts of the metal
lattice because of their freedom of
movement. Heat causes the electrons to
move faster and the ‘bumping’ of these
electrons with each other and the electrons
transfers the heat
heat
How do metals conduct heat and
electricity?
allow metals to conduct heat and
electricity.
For example, when a metal is heated,
electrons are able to gain kinetic energy in
hotter areas of the metal and are able to
quickly transfer it to other parts of the metal
lattice because of their freedom of
movement. Heat causes the electrons to
move faster and the ‘bumping’ of these
electrons with each other and the electrons
transfers the heat
heat
How do metals conduct heat and
electricity?
How do metals conduct heat
and electricity?
When an electric field is applied to a
metal, one end of the metal becomes
positive and the other becomes
negative. All the electrons experience a
force toward the positive end. The
movement of electrons is an electric
current.
and electricity?
When an electric field is applied to a
metal, one end of the metal becomes
positive and the other becomes
negative. All the electrons experience a
force toward the positive end. The
movement of electrons is an electric
current.
Dayahantarlistriklogamdipengaruhi
duafaktor, yaituenergiionisasidanjari-
jariatom logam
Semakinbesarenergiionisasimaka
semakinsulitlautanelektronterbentuk
sehinggadayahantarlistrikcenderung
lebihrendah
Semakinbesarukuranatom logam,
dayahantarlistriklogamcenderung
semakinrendah
duafaktor, yaituenergiionisasidanjari-
jariatom logam
Semakinbesarenergiionisasimaka
semakinsulitlautanelektronterbentuk
sehinggadayahantarlistrikcenderung
lebihrendah
Semakinbesarukuranatom logam,
dayahantarlistriklogamcenderung
semakinrendah
Metals are usually strong, not brittle. When a metal is hit, the layers of metal
ions are able to slide over each other, and so the structure does not shatter.
Why are metals strong?
The metallic bonds do not break because the delocalized electrons are free to
move throughout the structure.
metal after it is hit
forceforce
This also explains why metals are malleable (easy to shape) and ductile (can be
drawn into wires).
metal before it is hit
ions are able to slide over each other, and so the structure does not shatter.
Why are metals strong?
The metallic bonds do not break because the delocalized electrons are free to
move throughout the structure.
metal after it is hit
forceforce
This also explains why metals are malleable (easy to shape) and ductile (can be
drawn into wires).
metal before it is hit
Malleable
++++
++++
++++
Force
++++
++++
++++
Force
Malleable
Mobile electrons allow atoms to slide
by, sort of like ball bearings in oil.
++++
++++
++++
Force
Mobile electrons allow atoms to slide
by, sort of like ball bearings in oil.
++++
++++
++++
Force
Ionic solids are brittle
+-+-
+- +-
+-+-
+- +-
Force
+-+-
+- +-
+-+-
+- +-
Force
Ionic solids are brittle
Strong Repulsionbreaks a crystal apart,
due to similar ions being next to each
other.
+- +-
+-+-
+- +-
Force
Strong Repulsionbreaks a crystal apart,
due to similar ions being next to each
other.
+- +-
+-+-
+- +-
Force
15
Band Theory for Metals (and Other
Solids)
Thus far, whenever we’ve seen electrons, they’ve
been in orbitals(atomic orbitalsfor atoms, molecular
orbitalsfor molecules). What about the electrons in a
metal?
These solids can be treated in a way similar to
molecular orbital theory; however, instead of MOs, we
will produce states. Consider that, in a metal, there
are no distinct molecules. You could almost say that
an entire piece of metal is a molecule. That’s how
we’ll be treating them:
–We combine atomic orbitalsfrom every atom in the
sample to make states which look rather like very
large molecular orbitals.
Band Theory for Metals (and Other
Solids)
Thus far, whenever we’ve seen electrons, they’ve
been in orbitals(atomic orbitalsfor atoms, molecular
orbitalsfor molecules). What about the electrons in a
metal?
These solids can be treated in a way similar to
molecular orbital theory; however, instead of MOs, we
will produce states. Consider that, in a metal, there
are no distinct molecules. You could almost say that
an entire piece of metal is a molecule. That’s how
we’ll be treating them:
–We combine atomic orbitalsfrom every atom in the
sample to make states which look rather like very
large molecular orbitals.
–As in LCAO-MO theory, the number of states
produced must equal the number of atomic orbitals
combined.
–The Pauli exclusion principle still applies, so each
state can only hold two electrons.
–For a metal to conduct electricity, its electrons must
be able to gain enough extra energy to be excited into
higher energy states.
–The highest energy state when no such excitation has
occurred (i.e. in the ground state metal) is called the
Fermi level.
Band Theory for Metals (and Other Solids)
produced must equal the number of atomic orbitals
combined.
–The Pauli exclusion principle still applies, so each
state can only hold two electrons.
–For a metal to conduct electricity, its electrons must
be able to gain enough extra energy to be excited into
higher energy states.
–The highest energy state when no such excitation has
occurred (i.e. in the ground state metal) is called the
Fermi level.
Band Theory for Metals (and Other Solids)
17
Band Theory for Metals (and Other Solids)
Image adapted from “Chemical Structure and Bonding” by R. L. DeKockand H. B. Gray
So, how do states
get formed, and
what do they look
like?
Consider lithium.
The figure at the
right shows the
MOs produced by
linear combination
of the 2sorbitals
in Li
2, Li
3and Li
4.
Band Theory for Metals (and Other Solids)
Image adapted from “Chemical Structure and Bonding” by R. L. DeKockand H. B. Gray
So, how do states
get formed, and
what do they look
like?
Consider lithium.
The figure at the
right shows the
MOs produced by
linear combination
of the 2sorbitals
in Li
2, Li
3and Li
4.
18
Band Theory for Metals (and Other Solids)
In an alkali metal, the valence sband is only half
full. e.g. sodium
–If there are Natoms of sodium in a sample,
there
will be Nelectrons in 3sorbitals.
–There will be Nstates made from 3sorbitals,
each
able to hold two electrons.
–As such, N/2 states in the 3sband will be full
and N/2 states will be empty (in ground state
Na).
Band Theory for Metals (and Other Solids)
In an alkali metal, the valence sband is only half
full. e.g. sodium
–If there are Natoms of sodium in a sample,
there
will be Nelectrons in 3sorbitals.
–There will be Nstates made from 3sorbitals,
each
able to hold two electrons.
–As such, N/2 states in the 3sband will be full
and N/2 states will be empty (in ground state
Na).
Like all other alkali metals,
sodium conducts
electricity well because the
valence bandis
only half full. It is therefore
easy for electrons
in the valence band to be
excited into empty
higher energy states.
Since these empty higher
energy states are in the same
band, we can say that the
valence band for sodium is
also the conduction band.
Band Theory for Metals (and Other Solids)
sodium conducts
electricity well because the
valence bandis
only half full. It is therefore
easy for electrons
in the valence band to be
excited into empty
higher energy states.
Since these empty higher
energy states are in the same
band, we can say that the
valence band for sodium is
also the conduction band.
Band Theory for Metals (and Other Solids)
20
Band Theory for Metals (and Other Solids)
In an alkaline earth metal, the valence sband
is full.
e.g. beryllium
–If there are Natoms of beryllium in a
sample, there will be 2Nelectrons in 2s
orbitals.
–There will be Nstates made from 2s
orbitals, each able to hold two electrons.
–As such, all states in the 2sband will be full
andnonewill be empty (in ground state Be).
Band Theory for Metals (and Other Solids)
In an alkaline earth metal, the valence sband
is full.
e.g. beryllium
–If there are Natoms of beryllium in a
sample, there will be 2Nelectrons in 2s
orbitals.
–There will be Nstates made from 2s
orbitals, each able to hold two electrons.
–As such, all states in the 2sband will be full
andnonewill be empty (in ground state Be).
So, why are alkaline earth metals
conductors?
–While the 2sband in beryllium
is full, it overlaps
with the 2pband.
–As such, some electrons in
the valence band
can easily be excited into the
conduction band.
–In beryllium, the conduction
band (band containing
the lowest energy empty
states) is the 2pband.
Band Theory for Metals (and Other Solids)
conductors?
–While the 2sband in beryllium
is full, it overlaps
with the 2pband.
–As such, some electrons in
the valence band
can easily be excited into the
conduction band.
–In beryllium, the conduction
band (band containing
the lowest energy empty
states) is the 2pband.
Band Theory for Metals (and Other Solids)
Since the gap between energy levels are
extremely small, radiation of any frequency in
visible region can be absorbed and emitted.
Li
n
Surface lustre
Half-filled 2s
band
Silvery and shiny
extremely small, radiation of any frequency in
visible region can be absorbed and emitted.
Li
n
Surface lustre
Half-filled 2s
band
Silvery and shiny
23
Band Theory for Metals (and Other Solids)
What do the bands look like for
something that doesn’t conduct
electricity? i.e. for an insulator
e.g. diamond
–If there are Natoms of carbon
in a sample,
there will be 4Nvalence
electrons.
–The valence orbitalsof the
carbon atoms
will combine to make two
bands, each
containing 2Nstates.
Band Theory for Metals (and Other Solids)
What do the bands look like for
something that doesn’t conduct
electricity? i.e. for an insulator
e.g. diamond
–If there are Natoms of carbon
in a sample,
there will be 4Nvalence
electrons.
–The valence orbitalsof the
carbon atoms
will combine to make two
bands, each
containing 2Nstates.
24
Band Theory for Metals (and Other Solids)
There are two broad categories
of semiconductors:
–Intrinsic Semiconductors
•Naturally have a moderate band gap.
A small fraction of the electrons in the
valence band can be excited into the
conduction band. They can carry
current.
•The “holes” these electrons leave in
the valence band can also carry
current as other electrons in the
valence band can be excited into
them.
Band Theory for Metals (and Other Solids)
There are two broad categories
of semiconductors:
–Intrinsic Semiconductors
•Naturally have a moderate band gap.
A small fraction of the electrons in the
valence band can be excited into the
conduction band. They can carry
current.
•The “holes” these electrons leave in
the valence band can also carry
current as other electrons in the
valence band can be excited into
them.
–Extrinsic Semiconductors
•Have had impurities added in order to increase the
amount of current they can conduct. (impurities
called dopants; process called doping)
•The dopantscan *either* provide extra electrons
*or* provide extra holes:
–A semiconductor doped to have extra electrons is an n-
type semiconductor(‘n’ is for ‘negative’)
–A semiconductor doped to have extra holes is a p-type
semiconductor(‘p’ is for ‘positive)
Band Theory for Metals (and Other Solids)
•Have had impurities added in order to increase the
amount of current they can conduct. (impurities
called dopants; process called doping)
•The dopantscan *either* provide extra electrons
*or* provide extra holes:
–A semiconductor doped to have extra electrons is an n-
type semiconductor(‘n’ is for ‘negative’)
–A semiconductor doped to have extra holes is a p-type
semiconductor(‘p’ is for ‘positive)
Band Theory for Metals (and Other Solids)
SemikonduktorTipep
Semikonduktortipep diperoleh
dengancaramendopingatom-atom
yang bervalensisatutingkatlebih
rendahkedalamsemikonduktor
Penambahanpengotorbervalensitiga
sepertiB, Al atauGa(akseptor
elektron) kedalamsemikonduktor
intrinsik(Si) menghasilkandefesiensi
elektronvalensiyang disebut‘lubang’
(bermuatanpositif)
Defesiensielektronataulubang
tersebutberadapadatingkatfermi..
Elektronpadapita valensiakan
mengisironggatersebut, sehingga
aliranelektrondapatmencapaipita
konduksi
26
Semikonduktortipep diperoleh
dengancaramendopingatom-atom
yang bervalensisatutingkatlebih
rendahkedalamsemikonduktor
Penambahanpengotorbervalensitiga
sepertiB, Al atauGa(akseptor
elektron) kedalamsemikonduktor
intrinsik(Si) menghasilkandefesiensi
elektronvalensiyang disebut‘lubang’
(bermuatanpositif)
Defesiensielektronataulubang
tersebutberadapadatingkatfermi..
Elektronpadapita valensiakan
mengisironggatersebut, sehingga
aliranelektrondapatmencapaipita
konduksi
26
SemikonduktorTipen
Semikonduktortipen diperoleh
dengancaramendopingatom-
atom bervalensisatutingkatlebih
tinggikedalamsemikonduktor.
Penambahanpengotor
bervalensilima sepertiSb, As
atauP menyumbangkanelektron
bebas(donor free elektron).
Elektronbebasituberadapada
tingkatfermidandapatmasukke
pita konduksi. Kekosongannya
digantikanolehelektrondaripita
valensi, sehinggaterjadialiran
elektron. Akibatnyakonduktifitas
semikonduktorinstrinsik
bertambah.
27
Semikonduktortipen diperoleh
dengancaramendopingatom-
atom bervalensisatutingkatlebih
tinggikedalamsemikonduktor.
Penambahanpengotor
bervalensilima sepertiSb, As
atauP menyumbangkanelektron
bebas(donor free elektron).
Elektronbebasituberadapada
tingkatfermidandapatmasukke
pita konduksi. Kekosongannya
digantikanolehelektrondaripita
valensi, sehinggaterjadialiran
elektron. Akibatnyakonduktifitas
semikonduktorinstrinsik
bertambah.
27
Metallic Radius
Metallic radius(r) is defined as half of the
internucleardistance between adjacent
atoms in a metal crystal.
Metallic radius(r) is defined as half of the
internucleardistance between adjacent
atoms in a metal crystal.
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