Chapter - 5, Periodic Classification of Elements, Science, Class 10
ShivamParmar17
4,498 views
29 slides
Jun 25, 2020
Slide 1 of 29
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
About This Presentation
I have expertise in making educational and other PPTs. Email me for more PPTs at a very reasonable price that perfectly fits in your budget.
Email: [email protected]
Chapter-5, Periodic Classification of Elements, Science Class10
CLASSIFICATION
DOBEREINER’S TRIAD
LIMITATIONS
NEWLAND’...
Slide Content
CHAPTER –5
PERIODICCLASSIFICATION
OFELEMENTS
BY SHIVAM PARMAR
(ENTREPRENEUR&TEACHER)
1
PERIODICCLASSIFICATION
OFELEMENTS
BY SHIVAM PARMAR
(ENTREPRENEUR&TEACHER)
1
CLASSIFICATION
Placing similar groups and species together is known
asClassification. Classification is needed to easily
understand the properties of different elements in a
periodic table.
2
Placing similar groups and species together is known
asClassification. Classification is needed to easily
understand the properties of different elements in a
periodic table.
2
DOBEREINER’S TRIAD
Dobereiner’striadconsider three elements,
in which atomic mass of central element is
the arithmetic mean to two other elements.
3
Dobereiner’striadconsider three elements,
in which atomic mass of central element is
the arithmetic mean to two other elements.
3
LIMITATIONS
•Dobereneir’s idea of
classification of elements
into triads did not receive
wide acceptance as he
could arrange only 9
elements in triad form.
4
•Dobereneir’s idea of
classification of elements
into triads did not receive
wide acceptance as he
could arrange only 9
elements in triad form.
4
NEWLAND’S
LAW OF
OCTAVES
•Newland an English chemist gaveLaw of Octaves.
•Till then 56 elements were known.
•Law of Octaves says that “If elements are arranged
by the increasing order of their atomic masses,
property of every eighth element (starting from
first element) repeats”.
5
LAW OF
OCTAVES
•Newland an English chemist gaveLaw of Octaves.
•Till then 56 elements were known.
•Law of Octaves says that “If elements are arranged
by the increasing order of their atomic masses,
property of every eighth element (starting from
first element) repeats”.
5
CHARACTERISTICS OF LAW OF OCTAVES
•It contains the elements
starting from hydrogen and
ends at thorium.
•Properties of every eighth
element follow of that of first
element.
6
•It contains the elements
starting from hydrogen and
ends at thorium.
•Properties of every eighth
element follow of that of first
element.
6
LIMITATIONS OF NEWLANDS LAW OF OCTAVES
•Similarity in properties of elements as per the law was seen up to
calcium only.
•Only 56 elements known that time were talked about.
•At many places, 2 elements were placed in a single slot (Co and Ni).
•Placing of iron far away from cobalt and nickel, which have similar
properties as iron, could also not be explained.
7
•Similarity in properties of elements as per the law was seen up to
calcium only.
•Only 56 elements known that time were talked about.
•At many places, 2 elements were placed in a single slot (Co and Ni).
•Placing of iron far away from cobalt and nickel, which have similar
properties as iron, could also not be explained.
7
MENDELEEV’S PERIODIC TABLE
•Dmitry Mendeleev a Russian chemist in 1869 gaveMendeleev’s
Periodic Table.
•Till then 63 elements were known.
•Mendeleev arranged elements in increasing order of their atomic
mass.
•He tried to put elements with similar properties in a group.
•Due to this we find empty boxes in his table.
8
•Dmitry Mendeleev a Russian chemist in 1869 gaveMendeleev’s
Periodic Table.
•Till then 63 elements were known.
•Mendeleev arranged elements in increasing order of their atomic
mass.
•He tried to put elements with similar properties in a group.
•Due to this we find empty boxes in his table.
8
MENDELEEV’S PERIODIC TABLE
9
9
PROPERTIES OF GROUPS STUDIED BY MENDELEEV
(a)Formation of Oxides:
Oxides are compounds of elements with oxygen.
For example:
Li
2O , Na
2O and K
2O resembles to R
2
•MgO, CaO, ZnOresembles to RO.
10
(a)Formation of Oxides:
Oxides are compounds of elements with oxygen.
For example:
Li
2O , Na
2O and K
2O resembles to R
2
•MgO, CaO, ZnOresembles to RO.
10
(b) Formation of Hydrides:
•Hydrides are compounds of elements with hydrogen.
•The horizontal rows present in the periodic table are called periods.
•The vertical columns present in it are called groups. There were total eight
groups in Mendeleev’s periodic table, I to VIII.
•Properties of elements in a particular period show regular gradation (i.e.
increase or decrease) from left to right.
•Groups I to VII are subdivided into A and B subgroups. Groups VIII don’t have
any subgroups.
•All the elements in a particular group have similar properties. They show
regular gradation in their physical properties and chemical reactivities.
11
•Hydrides are compounds of elements with hydrogen.
•The horizontal rows present in the periodic table are called periods.
•The vertical columns present in it are called groups. There were total eight
groups in Mendeleev’s periodic table, I to VIII.
•Properties of elements in a particular period show regular gradation (i.e.
increase or decrease) from left to right.
•Groups I to VII are subdivided into A and B subgroups. Groups VIII don’t have
any subgroups.
•All the elements in a particular group have similar properties. They show
regular gradation in their physical properties and chemical reactivities.
11
LIMITATIONS OF MENDELEEV’S
PERIODIC TABLE
1. Position of Isotopes
•Isotopes are atoms of same element having different atomic masses
but have similar chemical properties.
•Isotopes are placed together by Mendeleev as they have similar
properties. But then this violated the arrangement scheme of
increasing atomic masses.
•Mendeleev could not explain that problem.
12
PERIODIC TABLE
1. Position of Isotopes
•Isotopes are atoms of same element having different atomic masses
but have similar chemical properties.
•Isotopes are placed together by Mendeleev as they have similar
properties. But then this violated the arrangement scheme of
increasing atomic masses.
•Mendeleev could not explain that problem.
12
2. Anomalous pairs of elements
At some locations,
elements were put in
order of decreasing
atomic mass.
For example; Co, Ni
and Te, I.
13
At some locations,
elements were put in
order of decreasing
atomic mass.
For example; Co, Ni
and Te, I.
13
3. Position of hydrogen
Properties of H are similar
to group 1 as well as group
7. But Mendeleev placed it
in group 1 without any
proper explanation.
14
Properties of H are similar
to group 1 as well as group
7. But Mendeleev placed it
in group 1 without any
proper explanation.
14
MERITS OF MENDELEEV’S PERIODIC CLASSIFICATION
Earlier 63 elements were known.
Mendeleev discovered Prediction of new elements.
Mendeleev’s periodic table had some blank spaces in it.
For example, he proposed the existence of some unknown elements
Eka –boron → Scandium, Eka –aluminium → Gallium, Eka –silicon →
Germanium
15
Earlier 63 elements were known.
Mendeleev discovered Prediction of new elements.
Mendeleev’s periodic table had some blank spaces in it.
For example, he proposed the existence of some unknown elements
Eka –boron → Scandium, Eka –aluminium → Gallium, Eka –silicon →
Germanium
15
MODERN PERIODIC LAW
•The physical and chemical properties of elements are the periodic
function of their atomic numbers.
Cause of periodicity–It is due to the repetition of same outer shell
electronic configuration at a certain regular interval.
Modern Periodic Table-
D. Mendeleev discovered the modern periodic table in the year 1869.
According to modern periodic law, “properties of an element are the
periodic function of their increasing atomic number”.
16
•The physical and chemical properties of elements are the periodic
function of their atomic numbers.
Cause of periodicity–It is due to the repetition of same outer shell
electronic configuration at a certain regular interval.
Modern Periodic Table-
D. Mendeleev discovered the modern periodic table in the year 1869.
According to modern periodic law, “properties of an element are the
periodic function of their increasing atomic number”.
16
17
PROPERTIES OF MODERN PERIODIC TABLE
•Isotopes are placed at one place in the same group.
•There is no element between hydrogen and helium as atomic
masses always comes in whole numbers.
•Atomic number is represented by Z, and it is equal to the number
of protons in the nucleus of the atom.
•It also consists of 18 vertical columns known asGroupsand 7
horizontal rows known asPeriods.
•Elements having same number of valence electrons are placed in
the same group.
18
•Isotopes are placed at one place in the same group.
•There is no element between hydrogen and helium as atomic
masses always comes in whole numbers.
•Atomic number is represented by Z, and it is equal to the number
of protons in the nucleus of the atom.
•It also consists of 18 vertical columns known asGroupsand 7
horizontal rows known asPeriods.
•Elements having same number of valence electrons are placed in
the same group.
18
PROPERTIES OF MODERN PERIODIC TABLE
As we go down in a
group, number of shell
increases.
Elements having same
number of occupied
shells are placed in
same period.
Each period has a new
electronic shell getting
filled.
Number of elements
placed in a particular
period depends on the
point how electrons are
filled into various shell.
To find out the number
of electrons in a shell,
2n
2
formula can be
used, where is n is shell
number.
K Shell n = 1 or 2n
2
=
2(1)
2
= 2
L shell n = 2 or 2n
2
=
2(2)
2
= 8
Valence electron also
determines the number
of bonds which is
formed by an element.
19
As we go down in a
group, number of shell
increases.
Elements having same
number of occupied
shells are placed in
same period.
Each period has a new
electronic shell getting
filled.
Number of elements
placed in a particular
period depends on the
point how electrons are
filled into various shell.
To find out the number
of electrons in a shell,
2n
2
formula can be
used, where is n is shell
number.
K Shell n = 1 or 2n
2
=
2(1)
2
= 2
L shell n = 2 or 2n
2
=
2(2)
2
= 8
Valence electron also
determines the number
of bonds which is
formed by an element.
19
NOBLE GASES
•The elements in the eighteenth group, helium (He), neon (Ne), argon
(Ar), krypton (Kr), xenon (Xe), and the radioactive radon (Rn) are called
noble gases.
•They are all odourless, colourless and monatomic gases with very low
chemical reactivity.
•Since their valence shell is considered to be “full”, they have little
tendency to participate in chemical reactions.
•When discovered and identified, scientists thought they are exceedingly
rare, as well as chemically inert, and therefore these gases were also
given the names ‘rare’ or ‘inert’ gases.
•Number of valence electrons = 8
20
•The elements in the eighteenth group, helium (He), neon (Ne), argon
(Ar), krypton (Kr), xenon (Xe), and the radioactive radon (Rn) are called
noble gases.
•They are all odourless, colourless and monatomic gases with very low
chemical reactivity.
•Since their valence shell is considered to be “full”, they have little
tendency to participate in chemical reactions.
•When discovered and identified, scientists thought they are exceedingly
rare, as well as chemically inert, and therefore these gases were also
given the names ‘rare’ or ‘inert’ gases.
•Number of valence electrons = 8
20
POSITION OF ELEMENTS IN THE MODERN
PERIODIC TABLE
The modern periodic table is also classified into
metals, nonmetals and metalloids.
METALS -
•Metals are electropositive as they form bonds by losing
electrons.
•In general cases, oxides of metals are basic in nature.
21
PERIODIC TABLE
The modern periodic table is also classified into
metals, nonmetals and metalloids.
METALS -
•Metals are electropositive as they form bonds by losing
electrons.
•In general cases, oxides of metals are basic in nature.
21
NON-METALS
Non-metals are
electronegative as
they form bonds by
gaining electrons.
In general cases,
oxides of non-metals
are acidic in nature.
22
Non-metals are
electronegative as
they form bonds by
gaining electrons.
In general cases,
oxides of non-metals
are acidic in nature.
22
METALLOIDS
The elements which show
the properties of both
metals and nonmetals are
called metalloids or
semimetals.
For example –Boron, silicon,
germanium, arsenic,
antimony, tellurium, and
polonium.
23
The elements which show
the properties of both
metals and nonmetals are
called metalloids or
semimetals.
For example –Boron, silicon,
germanium, arsenic,
antimony, tellurium, and
polonium.
23
TRENDS IN MODERN PERIODIC TABLE
•Valency and Valence Electrons-On
moving left to right in a period,
valency increases and then it
decreases. But it remains same
down in a group. As we move from
left to right in a period, valence
electron increases and remain same
as we go down the group.
24
•Valency and Valence Electrons-On
moving left to right in a period,
valency increases and then it
decreases. But it remains same
down in a group. As we move from
left to right in a period, valence
electron increases and remain same
as we go down the group.
24
•Atomic Size-It decreases left to right in a period as the
nuclearcharge increases due to large positive charges on
the nucleus. Atomicsize increases down in a group due
to decrease in nuclear charges andaddition of new shell.
25
nuclearcharge increases due to large positive charges on
the nucleus. Atomicsize increases down in a group due
to decrease in nuclear charges andaddition of new shell.
25
•Metallic Character-Ability of atom to lose the electron is known
asMetallicCharacter. Metallic character decreases from left to right in a
period. This is due to increase in nuclear charge. But non-metallic
character increases left to right in a period. And metallic character
increases down the group as the size increases it can easily lose electron.
•Ionization Energyis the energy required to remove an electron from an
isolated gaseous atom. Ionization energy increases as we move left to
right in a period. This is due to increase in nuclear charge as we move left
to right in a period. But down in a group ionization energy decreases due
to decrease in nuclear charge but there are some exceptional cases.
26
asMetallicCharacter. Metallic character decreases from left to right in a
period. This is due to increase in nuclear charge. But non-metallic
character increases left to right in a period. And metallic character
increases down the group as the size increases it can easily lose electron.
•Ionization Energyis the energy required to remove an electron from an
isolated gaseous atom. Ionization energy increases as we move left to
right in a period. This is due to increase in nuclear charge as we move left
to right in a period. But down in a group ionization energy decreases due
to decrease in nuclear charge but there are some exceptional cases.
26
•Electropositive Characterdecreases from left to right in a
periodic table and increases down the group. This is due to
decrease in metallic character from left to right in a period.
•Basic Character of Oxidesincreases down the group as atomic
radius increases and ionization energy decreases. This is due to
increase in metallic character or electro positivity of elements.
Acidic character of oxides decreases as non-metallic character of
elements decreases from top to bottom.
27
periodic table and increases down the group. This is due to
decrease in metallic character from left to right in a period.
•Basic Character of Oxidesincreases down the group as atomic
radius increases and ionization energy decreases. This is due to
increase in metallic character or electro positivity of elements.
Acidic character of oxides decreases as non-metallic character of
elements decreases from top to bottom.
27
28
Thank You
29
29
Download
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 4,498
- Slides 29
- Favorites 34
- Age 1986 days
Related Slideshows
11
8-top-ai-courses-for-customer-support-representatives-in-2025.pptx
JeroenErne2
47 views
10
7-essential-ai-courses-for-call-center-supervisors-in-2025.pptx
JeroenErne2
46 views
13
25-essential-ai-courses-for-user-support-specialists-in-2025.pptx
JeroenErne2
37 views
11
8-essential-ai-courses-for-insurance-customer-service-representatives-in-2025.pptx
JeroenErne2
34 views
21
Know for Certain
DaveSinNM
21 views
17
PPT OPD LES 3ertt4t4tqqqe23e3e3rq2qq232.pptx
novasedanayoga46
26 views