Synopsis – Grade 9 Science Term II
Chapter 1: Atoms and Molecules Law of conservation of mass: Mass can neither be created nor can it be destroyed in a
chemical reaction.
Law of constant proportion: A chemical substance always contains the same elements in a
fixed proportion by mass, irrespective of the source of compound.
Atom: The smallest particle which is the building block of matter.
The symbol of the element is made from one or two letters of the English or the Latin name
of the element.
Atomic mass: The sum of the protons and neutrons in an element gives its atomic mass. The
atomic mass of an atom of an element is also known as its relative atomic mass, since it is
determined relative to the mass of C-12 isotope.
Molecule: It is formed when two or more atoms of the same element or different elements
get combined chemically.
Atomicity: The number of atoms that combine to form a molecule is called the atomicity of
the molecule.
Ion: A charged species in which an atom or a group of atoms possess a net electric charge
(positive or negative).
Cations → Positively charged ion
Anion → Negatively charged ion
Chemical formula: Representation of the composition of a molecule in terms of the
symbols of elements present in that molecule.
Molecular mass: It is the sum of the atomic masses of all the atoms present in a molecule of
that substance.
Formula unit mass: It is the sum of the atomic masses of all the atoms present in a formula
unit of that substance.
Mole: The mole is a unit of measurement for the amount of substance. One mole of a
substance is the quantity of the substance containing 6.022 1023
numbers of particles
(atoms, molecules, or ions).
Chapter 2: Structure of the Atom
Atoms are not indivisible and are composed of three fundamental particles. These particles
are electrons, protons, and neutrons.
Electrons: These are the negatively charged particle and were discovered by J. J. Thomson,
by cathode ray experiment.
Canal rays are positively charged radiations consisting of protons.
Protons: These are the positively-charged particles and were discovered by E. Goldstein.
Neutron: These are electrically-neutral particle and were discovered by J. Chadwick.
Various atomic models:
Thomson's atomic model: Thomson thought that an atom is a sphere of positive charge
in which electrons are embedded. An atom as a whole is electrically neutral because the
negative and positive charges are equal in magnitude.
Rutherford's atomic model: All the positive charges (i.e., protons) were present at the
centre of the atom, inside the nucleus, and the electrons were present in circular orbits
around the nucleus. The electrons are not at rest and keep moving continuously in these
circular orbits. The size of the nucleus is very small as compared to that of the atom.
Bohr’s atomic model: The electrons present around the nucleus revolve in specific orbits
called energy levels. He also stated that the electrons do not release energy while
revolving. The shells in which the electrons are present are known as K, L, M, N, and so
on (or 1, 2, 3, 4, and so on), as proposed by Bohr and Bury. Each shell contains a specific
number of electrons, which can be calculated using the formula 2n2.
Atomic Models
Dalton’s atomic model Thomson’s atomic model
Rutherford’s atomic model Bohr’s atomic model
Valency: It is defined as the combining capacity of the atom of an element. It depends upon
the number of electrons present in the outermost shell of its atom.
Atomic number of an element is equal to the number of protons present in the atom and
atomic mass is equal to the sum of the number of protons and neutrons present in it.
Isotopes: These are the atoms having the same atomic number and different atomic masses.
Isobars: These are the atoms having the same atomic mass and different atomic numbers.
Chapter 3: Diversity in Living Organisms
Diversity: It refers to the variety and variability among living organisms from all sources
including land, water, and other ecosystems.
Classification: It refers to the identification, naming, and grouping of organisms into a
formal system based on similarities in internal and external structures or evolutionary history
Characteristic: A feature that helps identify or describe a person or a thing.
Principles of classification
Nature of cell (Fundamental characteristic): prokaryotes and eukaryotes
Cellularity: unicellular and multicellular
Mode of nutrition: autotrophs and heterotrophs
Classification and evolution
Primitive organism or lower organism has a simple body structure and ancient body
design
Advanced organism or higher organism has a complex body structure and organisation
Evolution: The process of gradual and continuous change in primitive or simple
organisms to give rise to advanced organisms
Biodiversity: The variety of life forms present in various ecosystems
Hierarchy of classification: Kingdom Phylum (for animals)/ Division (for plants)
Class Order Family Genus Species.
Mnemonic to learn this hierarchy: Kids Prefer Cheese Over Fried Green Spinach
Species is the basic unit of classification
Carolus Linnaeus developed the hierarchy of classification. Linnaeus also developed the
concept of binomial nomenclature
Binomial nomenclature In this system, the name of a species is made up of two words:
the genus name and the species name. E.g. Rosa indica
R.H. Whittaker (in 1969) proposed a five-kingdom classification of living organisms
The five kingdoms proposed by Whittaker along with their features are
Kingdom Special feature Example of organisms
Kingdom Monera Prokaryotic and unicellular
organisms.
bacteria, blue-green algae, or
cyanobacteria
Kingdom Protista Unicellular, eukaryotic organism Amoeba, Paramecium, diatoms etc
Kingdom Fungi Multicellular eukaryotic
heterotrophic (saprophytic)
organisms with citinious cell wall
Yeast, mushroom, Penicillium,
Aspergillus, etc
Kingdom Plantae
Multicellular eukaryotic
autotrophic organisms with
cellulosic cell wall
All plants
Kingdom Animalia
Multicellular eukaryotic
heterotrophic organisms with no
cell wall
All animals
Kingdom Plantae: It includes five divisions:
Division Thallophyta: Includes Spirogyra, Cladophora, Ulva
Plant body is not differentiated into true root, stem, and leaves
Division Bryophyta (also called amphibians of plant kingdom):
o Includes mosses, Riccia, Marchantia,
o Specialised vascular tissues (such as xylem) for the conduction of water are absent
o Body is differentiated into stem and leaf like structures
o Naked embryo i.e. spores are present.
Division Pteridophyta: o Includes ferns, Marsilea, Equisetum
o Specialised vascular tissues for the conduction of water are absent
o Naked embryo i.e. spores are present
Cryptogams: Plants that do not have well differentiated reproductive organs and produce
naked embryo (spores) are called cryptogams. Thallophyta, Bryophyta and Pteridophyta all
possess naked embryo.
Phanerogams: Plants that have well developed reproductive organs that finally make seeds
are called Phanerogams. Gymnosperms and angiosperms belong to Phanerogams.
Division Gymnospermae:
o Includes Pinus, cedar, fir, Juniper, Cycas, etc:
o Seed bearing, non-flowering plants.
o Bear naked seeds, not enclosed inside fruits.
Division Angiospermae: Includes all flowering plants:
Flowering plants in which seeds are enclosed inside fruits.
Seeds develop inside the ovary, which develops into a fruit
o Monocotyledons: Seeds that have one cotyledon. E.g. maize, wheat etc
o Dicotyledons: Seeds that have two cotyledons. E.g. Sunflower, gram etc
Kingdom Animalia
Kingdom Animalia can be divided into two major groups on the basis of the presence or
absence of notochord: non-chordata and chordata
Non-chordata can be further divided into the following phyla:
Phylum Porifera: Includes sponges such as Spongilla, Euplectella, etc:
o Cellular level of organisation
o Mainly found in marine habitats
o Posses canal system for circulating water.
Phylum Coelenterata: Includes sponges such as Spongilla, Euplectella, etc
o Tissue level of organisation
o Body cavity (coelom) is absent
o Diploblastic i.e body is made of two layers of cells.
Phylum Platyhelminthes: Includes flatworms, liver flukes and planarians
o Bilateral symmetry
o Triploblastic i.e. three layers of cells are present
o Body cavity is absent
Phylum Nematoda (Aschelminthes): Includes roundworms - Ascaris
o Bilaterally symmetrical
o Triploblastic
o Pseudocoelom (false coelom) is present
Phylum Annelida: Includes segmented worms such as earthworms and leeches
o Bilaterally symmetrical
o Triploblastic
o Body is segmented
Phylum Arthropoda: Includes crabs, prawns, insects, spiders, scorpions, etc
o Largest group of the animal kingdom.
o Bilaterally symmetrical and segmented
o Coelomic cavity is blood-filled
o Presence of Jointed legs
Phylum Mollusca: Includes snails, octopus, Pila, etc
o Bilaterally symmetrical, little segmentation
o Coelomic cavity is reduced
o Open circulatory system and kidney like organ for excretion is present.
Phylum Echinodermata: Includes marine animals such as starfishes, sea urchins, etc
o Spiny skinned organisms
o Free living marine organisms
o Triploblastic and coelomate
o Skeleton is made of calcium carbonate
Chordata can be further divided into sub-phyla Protochordata and Vertebrata
Protochordata: Includes Herdmania and Amphioxus
o Triploblastic, and have a coelom cavity
o Bilaterally symmetrical
o Notochord at some stages of life is present.
o Notochord is a flexible rod like structure that forms the supporting axis of the body in
the chordates.
Vertebrata: The sub-phylum Vertebrata is further divided into five classes:
Class Pisces: Includes all fishes
o Exclusively aquatic animals
o Body is streamlined and covered with scales
o They are cold blooded animals
o Heart is two chambered
o Skeleton is bony or cartilaginous
o Oviparous. They lay eggs in water.
Class Amphibia: Includes frogs, toads, and salamanders
o Scales are absent
o Cold blooded animals
o Heart is three chambered
o Oviparous. They lay eggs in water
o Have a dual mode of life (in water and land); respire through gills, skin and lungs
Class Reptilia: Includes reptiles such as lizard, snake, turtle, etc
o Cold blooded animals
o Most of them have three chambered heart (Crocodiles have four chambered heart)
o Skin is covered with scales
o These animals are completely terrestrial. They breath through lungs
o Lay eggs on land (oviparous)
Class Aves: Includes all birds
o Warm-blooded animals with four chambered heart
o They breathe through lungs
o Have feathers and forelimbs modified for flight
o Exclusively egg-laying animals
Class Mammalia: Includes kangaroo, rat, dolphin, elephant, horse, human, tiger, etc
o Warm-blooded animals with four chambered heart
o Most of them are viviparous except for platypus and echidna. They both are
oviparous
o These animals have milk-producing glands (mammary glands) to nourish their young
ones
Chapter 4: Work and Energy
Scientifically, work is done when:
There is a displacement.
Displacement is in any direction except the direction normal to the direction of force.
No work is done when
Net displacement is zero. [No work is done in circular path]
Displacement occurs perpendicularly to the applied force
Work = Force Displacement [along force direction]
W = F s [Unit – Joule, 1 J = 1 N.m]
Unit of energy: Joule
Commercial unit of Energy: kWh 6
1 kWh 3.6 10 J
The energy possessed by a body by virtue of its motion is called kinetic energy.
Kinetic energy of a body = 21
2mv , where m is mass and v is speed of the body.
Proof:
2 2
2 2
2 2
2 2 2
2
2
2
1 10
2 2
v u as
v us
a
v uW ma
a
m v u mv u
when
Energy possessed by a body by virtue of its position or its shape is called potential energy.
Gravitational potential energy = mgh where, m is mass, g acceleration due to gravity, and h is
the height above surface of Earth.
Law of conservation of energy: Energy can neither be created nor destroyed, it is only
converted from one form to other.
Total energy is constant: 21
2m h mv g Constant
Power is the rate of work done. Work done 1 J
P = Unit Watt, 1 W =1 s
Time taken
Chapter 5: Sound
Sound is a mechanical wave and requires a medium to propagate.
It cannot pass through vacuum.
Sound waves are longitudinal waves and propagate by continuous compressions and
rarefactions of the medium.
Longitudinal wave:
Individual particles of the medium move in the direction parallel to the direction of wave
propagation
Transverse wave:
Particle movement is perpendicular to the wave propagation
Characteristics of sound waves
Amplitude – Magnitude of maximum displacement from mean position
Wavelength (λ) – Distance between two consecutive compressions or two consecutive
rarefactions.
Frequency – Number of oscillations per unit time (Unit - Hertz, Hz)
Time period – Time taken by two consecutive compressions or rarefactions to cross a fixed
point
1
Frequency =Time period
Pitch – Higher the frequency, higher the pitch
Loudness – Determined by amplitude
Tone – Sound of single frequency
Speed of sound depends on temperature, pressure, humidity and nature of the material
medium.
Speed increases with increasing temp.
Speed in solid > Speed in liquid > Speed in gas
In air, speed 344 m s–1
at 22 C
Supersonic – More speed than sound
Sonic boom loud noise produced by supersonic object is sonic boom
Echo- Reflection of sound
Sensation of sound persists 1
= 0.1 s10
in the human brain
Minimum distance to hear echo = 344×0.1
=17.2 m2
Reverberation – Persistence of sound by repeated reflection
Uses – Loud speaker, stethoscope, curved ceiling of a concert hall, sound board in a big
hall
Range of hearing for humans: 20 – 20000 Hz
But, rhinoceroses use infrasound
Application of ultrasound : Cleaning, detecting defects in metals, echocardiography,
ultrasonography, to break small kidney stone
SONAR is Sound navigation and Ranging.
Human ear: Pinna collects sound; eardrum vibrates in response to sound
Vibrations are amplified by the three ear bones [hammer, anvil, stirrup (smallest human
bone)]
Chapter 6: Why Do We Fall Ill
Health: A state of physical, mental, and social well-being, which includes a unity and
harmony within the mind, body, and soul of an organism
Disease: Any condition that can lead to discomfort, distress, health problems, and even death
of the affected person
Symptoms: Indications of disease, such as headache, stomach pain, nausea, etc that can only
be felt by the patient
Signs of a disease include fever, vomiting, diarrhoea, etc that can be observed by a physician
Incubation period: The time interval between infection and appearance of symptoms
Causes of diseases
On the basis of its duration - Acute and Chronic
o Acute: Lasts for a short period of time, E.g. Cold, cough, influenza, etc.
o Chronic: Lasts for long periods of time, E.g. Diabetes, kidney stones, etc.
On the basis of causative agents - Infectious and Non-infectious
o Infectious: Diseases such as influenza, cold, etc., which are caused due to infectious
agents
o Non-infectious; Diseases such as high blood pressure, cancer, etc., which are caused
by some internal causes such as excessive weight, genetic defects, etc.
Infectious agents: disease-causing microorganisms which belong to different categories
such as:
Viruses: These are tiny organisms that grow, multiply, or reproduce only inside the host
cells. Diseases caused by viruses include Influenza, cold (Rhinovirus), dengue, AIDS,
SARS etc.
Bacteria: These are unicellular organisms; larger than viruses. Diseases caused by
bacteria include whooping cough, typhoid, cholera, anthrax, etc.
Fungi: These are plant-like organisms; heterotrophic. Diseases caused by Fungi include
Athlete’s foot, candidiasis, ringworms, etc.
Protozoa: These are simple, primitive unicellular organisms which are often found in
water. Diseases caused by Protozoa include amoebiasis, kala azar (Leishmania), malaria,
African sleeping sickness (Trypanosoma), etc.
Multicellular animals like worms - These are parasites that infect the intestines of
human beings and other animals. Diseases caused by worms include diarrhoea, liver rot,
etc.
Communicable diseases: An infectious disease is classified as communicable disease when
it can be transferred from an infected person to a healthy person
Means of disease spread
Air-borne diseases: Transmitted when disease-causing microorganisms are expelled into
the air by coughing, sneezing, talking, etc. E.g. common cold, chicken pox, small pox,
pneumonia, influenza, tuberculosis, etc.
Water-borne diseases: Spreads when the excretions (from an infected person)
containing causal microorganisms get mixed with drinking water and this contaminated
water is consumed. E.g. cholera, typhoid, hepatitis A, etc.
Physical contact: Includes sexually-transmitted diseases. E.g. syphilis, gonorrhoea,
AIDS, etc.
Blood to blood contact: Such contact is established during blood transfusion or
pregnancy (between the mother and her baby). E.g. AIDS can spread through blood
contact
Animals: Animals which transfer disease-causing microorganisms from an infected
person to others are called vectors. E.g. female mosquitoes can transfer the malaria-
causing Plasmodium
Effects of diseases
Local effects: Includes swelling, pain, joint stiffness, etc., occur only at the site of
infection
General effects: Includes fever chills, headaches, fatigue, loss of appetite, etc., occur all
over the body
Inflammation: The process by which the body’s immune system shows response to
protect the body from infection
Prevention of diseases
Antigens: Foreign substances that invade our body
Immunisation: The protection of the body from communicable diseases by
administration of some agent that mimics the microbe.
Vaccine: The suspension of killed microbes that mimics the disease causing microbes.
Vaccines are available against tetanus, polio, measles, hepatitis B, etc.
Chapter 7: Natural Resources
Role of the atmosphere → Atmosphere acts as a heat protector and it plays an important
role in the generation of wind.
Soil: It is a mixture of small rock particles and decayed living organisms.
Humus: A constituent of soil which makes it fertile
Factors that influence soil formation:
Sun: Heats up the rock during the day
Rocks cool during night time
Formation of creaksbreaking of rocks
Water – water in cracks freeze breaks rocks
Water carries rocks friction breaks rocks
Wind – Particles in air erode the rocks
Greenhouse effect: The trapping up of reflected solar radiations by the earth’s atmosphere
and gradual heating up is known as greenhouse effect.
Biogeochemical cycles
Water Cycle
Nitrogen cycle
Carbon cycle
Oxygen cycle
Ozone layer: It is a very important layer of the atmosphere which absorbs the harmful
ultraviolet rays. A hole in the ozone layer has been caused by CFCs which results from
human activities.
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