Topic outline

  • UNIT 1: HEALTHY NUTRITION

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    1.1. INTRODUCTION TO INTEGRATED SCIENCE

    1.1.1. Definition and rationale of integrated science

    human survival depends on knowledge through the exploration of the
    environment. Science provides knowledge while technology provides ways
    of using this knowledge. It is therefore very important to be aware of the
    global dimension of science needed in our lives in order to effectively deal
    with every day situation. The word “integrated” means “to restore the whole,
    to come together, to be a part of, to include.” Integrated science is a subject
    which incorporates the knowledge base of all the science fields, both physical
    and life sciences and these science fields are included in one subject as a
    whole “integrated science” in that the fields of science are not segmented.

    It is a subject which offers experiences which help people to develop an
    operational understanding of the structure of science that should enrich their
    lives and make them more responsible citizens in the society.

    Hence, integrated approach of learning science is appropriate as science
    knowledge is a tool to be used by every person to effectively deal with real
    world problems and life.

    For examples, when you are studying digestion process of animals, you will
    need the knowledge of chemical processes. Another example, in describing
    the physics of light, we show how this applies to the inner workings of our
    eyes, which, in turn, are sensitive to visible light in great part because of the
    chemical composition of our atmosphere.

    1.1.2. Interconnection between science subjects
    The purpose of science is to produce useful models of reality which are used
    to advance the development of technology, leading to better quality of life for
    man and the environment around him.

    There are many branches of science and various ways of classifying them.
    One of the most common ways is to classify the branches into social sciences,
    natural sciences and formal sciences.

    Social sciences deal with the study of human behavior and society. Examples
    of these are psychology and sociology. Natural sciences deal with the study
    of natural phenomena, for example lightning, motion, and earthquakes all
    which can be observed and tested.

    Examples of these are physics, chemistry and biology. Formal sciences deal
    with mathematical concepts and logics. An example of this is mathematics.
    Note:
    –– Chemistry mainly deals with the study of salts, acids and their reactions.
    For a physicist to understand the working mechanism of chemical cells,
    help is sought from a chemist. On the other hand, the reasons behind
    the various colours observed in most of the chemical reactions are
    explained by a physicist.
    –– Petroleum products are dealt with by the chemist, but the transportation
    of such products make use of the principles of physics.
    –– In Biology, the study of living cells and small insects by a biologist
    requires magnification. The concept of magnification using simple or
    compound microscope is a brain child of a physicist. A good physicist

    needs to have good health.

    1.1.3. Relationship between sciences with other subjects
    The concepts of science and other subjects might be expanded or explainable
    in broader senses than you might have been exposed to, this should then
    predict not only the interconnection senses already known, but should also
    predict much broader interconnections. This might be useful to you and our
    future civilization.

    Science is about observation and experimentation of things in the physical
    and natural world. If there no creative ideas, no destructive ideas, just more
    ideas of the same things that exist can this be healthy? There is such a thing
    as inductive reasoning not just deductive reasoning.

    Now, science is the practical application of scientific knowledge. So we
    could have science as a conservative subject, or we could have science as
    a creative (conservative and destructive) subject, then leading to smaller or
    larger sets of science.
    Note:
    –– In Geography, weather forecast, a geographer uses a barometer, wind gauge, etc. which are instruments developed by a physicist.
    –– In Agriculture, the water sprinkler, insecticide sprayer, etc. make use of
    the principles developed by physicists.
    –– In History, the determination of age fossils by historians and
    archaeologists use the principle developed by physicists.
    –– In games and sports, accurate measurement of time, distance, mass,

    and others uses instruments developed by physicists.

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    Food nutrients include macro and micro nutrients. Macro nutrients are
    needed by the body in large quantities. They include proteins, carbohydrates
    and lipids while the micro nutrients are needed in small amount and they
    include mineral salts and vitamins.

    The foods that we eat contain different types of nutrients. It is therefore
    essential that we know the components of the food that we eat in order to
    live healthy lives. There are three main food groups such as: energy giving
    foods, body building foods and protective foods.

    Energy giving foods are necessary to provide energy for cell metabolism.
    They include: carbohydrates and lipids. Some energy giving foods include
    potatoes, banana, rice, maize etc.

    Body building foods are needed to promote growth and tissue repair.
    These include proteins and can be found in the meat, eggs, fish, milk, beans,
    cassava leaves, etc.

    Protective foods allow a good functioning of the body, and protect the body
    against some deficiency diseases. They include minerals and vitamins. The
    minerals can be found in fish, beans, kitchen salt and mineral water; and
    vitamins are found mainly in vegetables and fruits.

    Food nutrients
    Food contains mainly two classes of nutrients, organic and inorganic. The
    inorganic nutrients include mineral salts like calcium, phosphorous and
    others like water. The organic nutrients include proteins, carbohydrates,
    lipids and vitamins.

    The materials that an animal’s cells require but cannot synthesize are called
    essential nutrients. There are four classes of essential nutrients: essential
    amino acids, essential fatty acids, vitamins, and minerals.
    1.2.1. Functions of food nutrients
    a. Minerals

    Mineral are also called micronutrients because we require them in very small
    quantities. They constitute about 1% of an organism by weight. Even though
    they are required in a very small amount, they are nonetheless essential for
    human body processes.

    Table 1.1: Principal minerals

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    Classification of minerals

    The classification of minerals is based upon their requirement rather than
    on their relative importance. Mineral nutrients are needed in a precise

    small amount. The five major minerals needed in human body include

    calcium (Ca2+), phosphorus (H2PO4-), potassium (K+), sodium (Na +) and
    magnesium (Mg2+). Mineral nutrients are grouped into two groups of mineral
    salts: the macronutrients or major elements and the micronutrients or
    trace elements.

    Macronutrient or major elements are minerals needed by humans in a relative
    large amounts (greater than 200 mg/day). Their examples include nitrogen
    (NO3-), phosphorus (H2PO4-), sulfur (SO42-), calcium (Ca2+), sodium (Na+),
    chlorine (Cl-), magnesium (Mg2+), and iron (Fe2+ or Fe3+). Micronutrients or
    trace elements are those which are needed in minute amounts (a few parts
    per million). Examples include manganese (Mn2+), iodine (I-), zinc (Zn2+),
    molybdenum (MoO4-).

    Human body requires mineral nutrients to survive and to carry out daily
    functions and processes. Minerals keep humans healthy and have key roles
    in several body functions. Humans receive minerals by eating plants that
    absorb minerals from the soil and by eating meat and other products from
    animals, which graze on plants. The deficiency of mineral nutrients results
    into body functional disorders and diseases. Most are found in the blood and
    cytoplasm of cells, where they assist basic functions. For example, calcium

    and potassium regulate nerve and muscle activity

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    b. Vitamins

    Like minerals, vitamins are also essential substances for the human body to
    function properly. They are required for metabolism, protecting health and
    for proper growth in children.

    These are referred to as micro-nutrients. This is because our bodies require
    them in very small quantities but they are very important. Depending on the

    vitamin, the required amount ranges from about 0.01 to 100 mg per day.

    Vitamins classification
    There are thirteen vitamins required by human body. They are classified by
    their solubility, whether they dissolve in water or in fats.

    Table 1.3 Water-soluble and fat-soluble vitamins

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    • Water soluble
    These are vitamins C and B. They are called water soluble vitamins because
    they dissolve easily in water. They also dissolve when vegetables containing
    these vitamins are cooked for long time.
    NB: We must never overcook vegetables.

    • Fat soluble.

    These consist of vitamins A, D, E, and K. They are called fat vitamins
    because they dissolve easily in oil and fat.

    NB: We fry vegetables in some oil to be able to benefit from vitamin A, D, E,
    and K in them. If we only oil boil or steam them, our bodies will not be able
    to extract the vitamin in vegetables.

    The vitamins are required for metabolism, protecting health and for proper
    growth in children. Vitamins also assist the formation of hormones, blood
    cells and genetic material.

    Vitamins require no digestion and are absorbed directly from the small

    intestine into the blood stream. Features shared by all vitamins:

    –– They are not digested or broken down for energy
    –– They are not synthesized into the body structures (are essential)
    –– Most are rapidly destroyed by heat.
    –– They are essential for good human health (needed in a very small amount)
    –– They are required for chemical reactions in cells, working in association with enzymes.
    Like minerals, vitamins are also essential substances for the human body to
    function properly. They are required for metabolism, protecting health and

    for proper growth in children.

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    c. Carbohydrates

    They are macronutrients that provide our bodies with energy and warmth.
    The word carbohydrate suggests that these organic compounds are
    hydrates of carbon. Their general formula is Cx (H2O)y . The general function
    of carbohydrates is to provide energy that is used in cellular metabolism.
    Carbohydrates are divided into three groups including the monosaccharides
    (single sugars: glucose, fructose and galactose), disaccharides (double
    sugars: sucrose, maltose and lactose) and polysaccharides (many sugars:
    starch, glycogen and cellulose).

    NB: We need carbohydrates to do work also to keep our bodies warm.

    Table 1.5: Types of disaccharides and their monomers

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    The carbohydrates are energy giving nutrients. They are burned by Oxygen in
    a process of cell respiration to produce energy to be used in cell metabolism.
    The common know monosaccharides of carbohydrates is glucose with
    molecular formula C6H12O6. If is burned by Oxygen, it produces energy as
    shown in equation of cell respiration below: C6H12O6 +6 O26 CO2 +6 H2O+
    Energy (ATP + heat).

    All monosaccharides and disaccharides have the following characteristics:
    sweet taste, soluble in water and lower molecular mass. In the same way
    that two monosaccharides may combine in pairs to give a disaccharide,
    many monosaccharides may also combine by condensation reactions to
    form a polysaccharide. The polysaccharides like starch are not soluble in

    water, and do not have the sweet taste.

    d. Lipids (Fats and oils)
    Fat sometimes ‘lipids’ refers to both fats and oils. Where by fats and oils
    have the same basic chemical structure but their appearance differs at room
    temperature that is, fats are solids at room temperature while oils are liquids
    at room temperature. Fat is composed of three elements which are carbon,

    oxygen and hydrogen.

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    Sources and classification of lipids
    Fats and oils are obtained from both the plants and animals. And fat is
    present in food either as visible fat or invisible fat.
    Visible fat is the one that is easily seen or detected in food for example; fat

    in meat, butter, margarine, lard, suet and cooking fat and oil.

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    Invisible fat is the part of food that is not easily seen for example fat with
    in lean meat, egg yolk, flesh of oily fish, groundnuts, soya beans, avocado
    and fat found in prepared foods, for example, pastry, cakes, biscuits, French

    fries, pancakes, croquettes.

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    Lipids are of different types as it is summarized in the following table

    Table 1.6: Lipids, structure, main role and features

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    e. Proteins
    These are also referred to as macro-nutrients. The protein are also called
    body- building food.

    Proteins are made of complex molecules which contain elements like oxygen,
    hydrogen, carbon, nitrogen and sometimes Sulphur and phosphorous. The
    protein molecules are made up of small units called

    Amino acids joined together like links in a chain.

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    There are 21 different amino acids and each has its own chemical name.
    Different proteins are made when different numbers and types of amino acids
    combine through a covalent peptide bond. Proteins are therefore known as
    polypeptides.

    Examples of proteins:
    a) Collagen, myosin and elastin found in meat,
    b) Caseinogen, lactalbumin, lacto globulin found in milk,
    c) Avalbumin, mucin and liporitellin found in eggs,
    d) Zein found in maize

    The 21 different amino acids found in protein are:

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    They are used to repair, to build, to maintain our bodies; to make muscles
    and to make breast milk during lactation period. The proteins are classified
    into two categories: animal or complete proteins and plant proteins or

    incomplete proteins.

    Functions of proteins
    Proteins are large organic compounds formed by amino acids and they are
    not truly soluble in water. In addition to carbon, hydrogen and oxygen, proteins

    always contain nitrogen, usually Sulphur and sometimes phosphorus.

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    1.2.2. Balanced diet and food service techniques

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    a. Balance diet
    Eating a balanced diet means eat at least 5 portions of a variety of fruit
    and vegetables every day (see 5 A Day), base meals on higher fibre starchy
    foods like potatoes, bread, rice or pasta, have some dairy or dairy alternatives
    (such as soya drinks) eat some beans, pulses, fish, eggs, meat and other
    protein

    Food variety means eating a wide variety of foods from each of the five food
    groups, in the amounts recommended. Eating many different foods helps
    maintain a healthy and interesting diet which provides a range of different
    nutrients to the body. Eating a variety of foods promotes good health and
    can help reduce the risk of disease. ( https://www.google.balanced diet chart
    for family)

    The nutritional requirement is influenced by age, sex, growth, pregnancy
    and breastfeeding, illness, psychological and emotional stress, activity
    level and other factors like smoking and drinking. Biological factors include
    age, gender, growth, disease states, and genetic makeup. Among the no
    biological factors, socio-economic status is the most important. Poverty is
    one of the major socio-economic causes of variation in nutrient intake, and it
    also impacts nutrient requirements. ( https://www.google.balanced diet chart
    for family)

    Example:
    Aging is linked to a variety of changes in the body, including muscle loss,
    thinner skin and less stomach acid. ... Low stomach acid can affect the
    absorption of nutrients, such as vitamin B12, calcium, iron and magnesium.
    Although the recommended breakdown of carbohydrate, protein, and fat are
    the same for both genders, because men generally need more calories, they
    also require higher total intake of each of the macronutrients. Women need
    fewer calories than men, but in many cases, they have higher vitamin and
    mineral needs.

    Reference Intakes
    Nutritional needs vary depending on sex, size, age and activity levels so use
    this chart as a general guide only. The chart shows the Reference Intakes
    (RI) or daily amounts recommended for an average, moderately active
    adult to achieve a healthy, balanced diet for maintaining rather than losing or
    gaining weight. The RIs for fat, saturates, sugars and salt are all maximum
    amounts, while those for carbs and protein are figures you should aim to
    meet each day. There is no RI for fibre although health experts suggest we

    have 30g a day.

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    A balanced diet is one that contains all nutrients required in health in
    appropriate proportion. A balanced diet must should contain all food groups
    such as: body building food, energy giving food and protective food in an
    appropriate amount. A balanced diet help a person to:
    –– Make you strong
    –– Provide better health
    –– Make you more productive

    –– Ensure strong immune system

    It’s not hard to include foods from the five food groups into appetizers and
    meals. Some suggestions include:
    –– Vegetables and legumes – raw or cooked vegetables can be used as
    a snack food or as a part of lunch and dinner. Salad vegetables can be
    used as a sandwich filling. Vegetable soup can make a healthy lunch.
    Stir-fries, vegetable patties and vegetable curries make nutritious
    evening meals. Try raw vegetables like carrot and celery sticks for a
    snack ‘on the run’.
    –– Fruit – this is easy to carry as a snack and can be included in most
    meals. For example, try a banana with your breakfast cereal, an apple
    for morning tea and add some berries in your yoghurt for an afternoon
    snack. Fresh whole fruit is recommended over fruit juice and dried fruit.
    Fruit juice contains less fibre than fresh fruit and both fruit juice and
    dried fruit, and are more concentrated sources of sugar and energy.
    Dried fruit can also stick to teeth, which can increase the risk of dental
    caries.

    –– Bread, cereals, rice, pasta and noodles – add rice, pasta or noodles
    to serves of protein and vegetables for an all-round meal. There are
    many varieties of these to try. Where possible, try to use wholegrains
    in breads and cereals.

    –– Lean meat, fish, poultry, eggs, nuts, legumes and tofu – these can
    all provide protein. It’s easy to include a mixture of protein into snacks
    and meals. Try adding lean meat to your sandwich or have a handful
    of nuts as a snack. You can also add legumes to soups or stews for an
    evening meal.

    –– Milk, yoghurt and cheese – try adding yogurt to breakfast cereal
    with milk, or using cottage cheese as a sandwich filling. Shavings of
    parmesan or cheddar can be used to top steamed vegetables or a
    salad. Use mostly reduced fat products.

    Feeding on unbalanced diet for a longtime may lead to malnutritional
    diseases. Malnutrition means feeding on a meal lacking some food nutrients
    (deficient diseases), or on a meal with all food nutrients but in unappropriated
    amount (over eating).

    Some deficient diseases include: kwashiorkor (caused by the meal lacking
    proteins), marasmus (caused by the meal lacking overall nutrients), and
    goitre (caused by the meal lacking iodine). The diseases caused by over
    eating include: obesity, a condition in which excessive fats are deposited
    in the body. More malnutritional diseases are described in the tables above

    describing functions of minerals and vitamins.

    b. Basic food service technics
    They are many different approaches of serving food. An operation should use
    a service style that is the best to satisfy its family members. The traditional
    table service provides service for family members who are seated at table.
    The English service comparable to Rwandan style is a type of service known
    as “family style service”. In this service the big dish is placed in front of the

    host along with serving plate and family members serve themselves.

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    • Principles for meal service

    The family style meal service allows participants to eat together and to
    make food choices based on individual appetites and food preferences. It
    promotes mealtime as a learning experience to help participants develop
    positive attitudes toward nutritious foods, share in group eating situations,
    and develop good eating habits. Family style meal service can be conducted
    in a variety of ways. For example, participants may help in preparing for the
    meal by clearing the table and setting places, sharing conversation during
    the meal, and cleaning up after the meal.

    Family style meal service operates as follows:
    –– All required meal components are placed on the table at the same time.
    –– Participants may serve themselves from serving dishes that are on the table
    –– Adults supervising the meal help those participants who are not able to serve themselves.
    –– Participants can make choices selecting foods and in the size of the serving.
    –– A supervising adult actively encourage family members to serve
    themselves and offers the food item again later in the meal if member
    (s) initially refuse the food or take a very small portion. Adult should
    model good eating habits while supervising participants at the dining
    table.

    • Standards of serving food temperatures
    The importance of temperature
    The crucial important part of food safety in the home is to keep hot food hot
    and to keep cold food cold. For safety it is vitally important to keep food out
    of that danger zone.
    The food being served should be kept at specified range and appropriate
    temperature (T):
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    Note:
    –– The temperature danger zone for bacteria reproduction and growth: 5OC < T < 63OC, food is not suitable for eating.
    –– Bacteria do not multiply and start to die at 63OC above and do not grow and multiply at 5OC below.
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    End unit assessment
    1. Analyze the importance of food nutrients.
    2. Explain the importance of a balanced diet.
    3. Explain how the condition factors (age, gender; activity; pregnant and breastfeeding mothers) affect the dietary needs of humans.
    4. Justify the different functions of food nutrients in the body.
    5. Classify vitamins and minerals as nutrients.
    6. Organize the diet components in food groups.
    7. Organize a list of foods that are good sources of specific food nutrients.
    8. Prepare a balanced diet
    9. Discuss services techniques of healthy diet.

    10. Recognize the role of integrated science in everyday life experiences










    Files: 2
  • UNIT 2: STRUCTURE ELECTRONIC OF CONFIGURATION AN ATOM AND

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    The ancient Greek philosophers Leucippus and Democritus believed that
    atoms existed, but they had no idea as to their nature. Centuries later, in
    1803, the English chemist John Dalton, guided by the experimental fact that
    chemical elements can’t be decomposed chemically, was led to formulate
    his atomic theory.

    Dalton’s atomic theory was based on the assumption that atoms are
    tiny indivisible entities, with each chemical element consisting of its own
    characteristic atoms.

    1) Dalton’s Atomic Theory
    a. Each element is made up of tiny particles called atoms.
    b. The atoms of a given element are identical; the atoms of different elements are different in some fundamental way(s).
    c. Chemical compounds are formed when atoms of different elements combine with each other. A given compound always has the same relative numbers and types of atoms.
    d. Chemical reactions involve reorganization of the atoms—changes in the way they are bound together. The atoms themselves are not changed in a chemical reaction.
    e. Dalton’s atomic theory successfully explained the following laws –
    conservation of mass, constant composition and multiple proportions.
    However, it failed to explain certain other observations like the
    generation of electricity on rubbing glass or ebonite with silk or fur.
    These observations propelled the discovery of sub-atomic particles
    in the 20th century. Let’s learn about the discovery of the first sub-atomic particle – Electron.

    The atom is now known to consist of three primary particles: protons,
    neutrons, and electrons, which make up the atoms of all matter.
    A series of experimental facts established the validity of the model.

    Radioactivity played an important part. Marie Curie suggested, in 1899,
    that when atoms disintegrate, they contradict Dalton’s idea that atoms are
    indivisible. There must then be something smaller than the atom (subatomic
    particles) of which atoms were composed.

    Long before that, Michael Faraday’s electrolysis experiments and laws
    suggested that, just as an atom is the fundamental particle of an element, a
    fundamental particle for electricity must exist. The “particle” of electricity was given the name electron.
    a. Discovery of the electron
    Experiments conducted by the British physicist Joseph John Thomson, in
    1897 proved the existence of the electron and obtained the charge-to- mass
    ratio for it.

    Conclusions from the Study of the Electron:
    –– All elements must contain identically charged electrons. Concluded that electron was part of an atom.
    –– Atoms are neutral, so there must be positive particles in the atom to balance the negative charge of the electrons
    –– Electrons have so little mass that atoms must contain other particles that account for most of the mass

    Thomson believed that the electrons were like plums embedded in a
    positively charged “pudding,” and thus his atomic model was called the
    “plum pudding” model.

    Efforts were then turned to measuring the charge on the electron, and these
    were eventually successful and in 1916 – Robert Millikan determines the
    mass of the electron: 1/1840 the mass of a hydrogen atom. The electron has
    a mass of 9.11 x 10-28 g and has one unit of negative charge

    b. Discovery of the nucleus, 1911
    In 1911, Ernest Rutherford (1871-1937) and his co-workers discovered the
    nucleus and their main conclusions were the following.
    –– The nucleus is small
    –– The nucleus is dense
    –– The nucleus is positively charged and electrons are distributed around the nucleus and occupy the most of the volume.
    The positively charged particles in the nucleus were called protons. The
    Rutherford Atomic Model was called a “nuclear model”
    Neils Bohr worked under Rutherford but found problems with his theory.
    He ultimately determined that electrons are in circular orbits with increasing

    energy levels.

    c. Discovery of the neutrons, 1932

    In spite of the success of Rutherford and his co-workers in explaining atomic
    structure, one major problem remains unsolved.

    If the hydrogen contains one proton and the helium atom contains two
    protons, the relative atomic mass of helium should be twice that of hydrogen.
    However, the relative atomic mass of helium is four and not two.

    James Chadwick, English physicist (1891-1974), showed that the origin of
    the extra mass of helium was due to uncharged particles present in the
    nucleus that they call neutrons.

    Bohr’s theory said that the protons are in the middle and the electrons travel
    in specific energy levels and orbits around the nucleus
    The modern model is basically the same except the nucleus contains protons
    and neutrons

    2) Properties of sub-atomic particles
    The following table summarizes the relative masses, the relative charges

    and the position within the atom of these sub-atomic particles.

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    a. Atomic number
    The atomic number (Z) or proton number is the number of protons in the
    nucleus of an atom. It corresponds to the order of the element in the periodic
    table.

    The number of the protons in the nucleus of an atom determines the element
    to which the atom belongs. If an atom has an atomic number of 7, the atom
    must be a nitrogen atom. All nitrogen atoms have 7 protons in the nucleus.
    Atoms carry no overall charge. The number of protons must therefore be the
    same as the number of electrons.

    b. Mass number
    The mass number (A) or nucleon number is the sum of the number of
    protons and the number of neutrons in the nucleus of an atom.
    The number of neutrons can be obtained by subtracting the atomic number
    from the mass number.

    Chemists use the following shorthand to represent an atom. The mass
    number is shown as a superscript (top number) and the atomic number is
    shown as a subscript (bottom number) beside the symbol of the element.

    Example:

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    Each fluorine atom contains: 9 protons, 9 electrons and 10 neutrons
    The term nuclide is used to describe any atomic species of which the
    proton number and the nucleon number are specified. The species and are
    nuclides.

    c. Isotopes
    Isotopes are atoms of the same element with the same atomic number but
    different mass numbers. They have different numbers of neutrons. They are
    nuclides of the same element.

    Example:
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    Isotopes of an element have the same chemical properties because they

    have the same number of electrons.

    When elements react, it is the electrons that are involved in the reactions.
    This means that the isotopes of an element cannot be differentiated by
    chemical reactions.

    Because isotopes of an element have different numbers of neutrons,
    they have different masses, and isotopes have slightly different physical
    properties.

    Isotopes and their abundance are estimated using an apparatus called mass

    spectrometer (See figure 2.1)

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    The relative isotopic masses of all others atoms are obtained by comparison
    with the mass of a carbon-12 atom.

    On that scale, the relative atomic mass of a proton and that of a neutron are
    both very close to one unit (1.0074 and 1.0089 units respectively). Since
    the relative mass of an electron is negligible (0.0005units), it follows that all
    isotopic masses will be close to whole numbers.

    However relative atomic masses of elements are not close to whole numbers
    because natural occurring elements are often mixtures of isotopes.
    The relative atomic mass (RAM) of an element, Ar , is the average of the
    relative isotopic masses of the different isotopes weighted in the proportions

    in which they occur.

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    The Electron Configuration is the way electrons are arranged around the
    nucleus. Electrons occupy shells starting with the one closer to the nucleus,
    i.e by increasing energy level. Energy levels are numbered 1, 2, 3, 4, 5, 6, 7
    starting with K. Each of these numbers is called energy quantum number or
    principal quantum numbers.

    a. Quantum numbers
    Energy levels or shells are subdivided into sub-shells known as s, p, d, f.
    Each sub-level is split into orbitals. Orbitals of a given sub-shell have the same
    name. Each electron is associated with a set of four quantum numbers s
    The principal quantum number, n, can have positive integral values 1, 2,
    3, 4,.... It governs the energy of the electron and also its probable distance
    from the nucleus. The most stable electronic state of an atom is called its
    ground state. Any higher energy state is called excited state.

    The angular momentum quantum number or (azimuthal quantum
    number), l, can have an integral values from zero to (n-1) for each value
    of n. It determines the shape of the volume of space that an electron can

    occupy. It also indicates the number of sub-levels for each level.

    The values of l is generally designated by the letters:

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    If an electron has a principal quantum number n=2 and an angular momentum
    quantum number l=0 it is said to be a 2s electron.

    –– The magnetic quantum number, ml, has values ranging from –l to +l.
    Within a sub- shell, the value of ml depends on the value of the angular
    momentum quantum number, l. For a certain value of l, there are (2l +
    1) integral values of ml as follows: -l, (-l +1), . . . 0, . . . (+l-1), +l.
    It determines the spatial orientation of an orbital.

    –– The (Electron) Spin Quantum Number, ms, may have values of - 1⁄2
    or + 1⁄2 only. The value of ms does not depend on the value of any other
    quantum number. It represents the spin of an electron that occupies a
    given orbital. Electrons will spin opposite each other in the same orbital

    Table 2.1: Relationship among values of n, l, ml through n=4

    zas

    s

    –– Atoms of the various elements differ from each other in their values of Z and electrons.
    –– Electrons in atoms are arranged in orbitals and shells.
    –– Orbitals are characterized by the quantum numbers n, l and ml.
    –– Orbitals having the same value of n are said to be in the same shell. Orbitals having the same values of n and l are said to be in the same subshell.
    –– Electrons are distributed in orbitals following the rules below.

    b. 1 Pauli Exclusion Principle
    No two electrons in the same atom can have the same set of the four quantum
    numbers. If two electrons have the same values of n, l, ml, they must have
    different values of ms. Then, since only two values of ms are allowed, an
    orbital can hold only two electrons, and they must have opposite spins.

    b. 2 Hunds’ rule
    Electrons occupy all the orbitals of a given sublevel singly before pairing
    begins.
    Spins of electrons in different incomplete orbitals are parallel in the ground
    state. The most stable arrangement of electrons in the subshells is the one

    with the greatest number of parallel spins.

    b. 3 Aufbau principle or build up principle or construction principle
    The Aufbau principle or build up principle or construction principle state that
    “Electrons fill lower energy orbitals (closer to the nucleus) before they fill

    higher energy ones”.

    s

    z

    a

    x

    xs

    zs

    s

    zs

    End unit assessment

    1. Given the following data concerning isotopes of nickel:

    xs

    xd

    xs


  • UNIT 3: CELL STRUCTURE

    s

    zs

    s

    The three basic, structural parts of a compound microscope are:
    –– head/body houses the optical parts in the upper part of the microscope,
    –– base of the microscope supports the microscope and houses the illuminator;
    –– arm connects to the base and supports the microscope head

    The different parts of light microscope are described below:
    –– Base: supports and stabilizes the microscope on the table or any other working place
    –– Light source: It is made by lamp or mirror which provides light for viewing the slide.
    –– Stage: is a platform used to hold the specimen in position during observation.
    –– Stage clips: are pliers used to fix and hold tightly the slide on stage.
    –– Arm: supports the body tube of microscope
    –– Body tube: maintains the proper distance between the objective and ocular lenses
    –– Arm: used for holding when carrying the microscope and it holds the body tube which bears the lenses.
    –– Coarse focus adjustment moves stage up and down a large amount for coarse focus
    –– Fine focus adjustment moves stage up and down a tiny amount for fine focus
    –– Objective lenses: focuses and magnifies light coming through the slide
    zs
    Under electron microscope, it is possible to identify a range of organelles in
    plant and animal cells. Ultrastructure is the detailed of cell as revealed by

    the electron microscope.

    x

    xs

    zx

    –– Gives the membranes of some eukaryotic cells the mechanical stability.
    –– It fits between fatty acid tails and helps make the barrier more complete,
    so substances like water molecules and ions cannot pass easily and directly through the membrane.
    Channel proteins
    –– Allow the movement of some substances across the membrane.
    –– Large molecules like glucose enter and leave the cell using these protein channels.
    Carrier proteins
    –– Actively move some substances across the cell membrane. For
    example, magnesium and other mineral ions are actively pumped into
    the root’s hair cells from the surrounding soil.
    –– Nitrate ions are actively transported into xylem vessels of plants. Receptor sites
    –– Allow hormones to bind with the cell so that a cell response can be carried out.
    –– Glycoproteins and glycolipids may be involved in cells signalling and they allow the immune system to recognize foreign objects to the cells.
    –– Some hormone receptors are glycoprotein, and some are glycolipid.

    3.2.2. Cytoplasmic constituents and their functions
    plant and animal cells contain a variety of cell organelles including nucleus,
    mitochondria, Golgi apparatus, endoplasmic reticulum, ribosomes, centrioles,

    vacuoles, chloroplasts, lysosomes and cytoskeleton.

    z

    The ER consists of a series of flattened membrane-bound sacs called
    cisternae. The rough ER is surrounded with ribosomes. The rough ER
    transports proteins made on attached ribosomes. The smooth ER is made
    of tubular cavities lacks ribosomes, and it involves in synthesis of lipids that
    the cell needs.

    NB: Glandular cells are seen to have several RER for synthesis of hormones
    and enzymes. Examples include liver cells, plasma cells, and pancreatic

    cells.

    s

    s

    These are spherical sacs surrounded by a single membrane. They contain
    powerful digestive enzymes. Their role is to break down materials such
    as white blood cells, and destroy invalid microorganisms. In acrosome,
    lysosomes help the sperm to penetrate the egg by breaking down the

    material surrounding the egg.

    sw

    zx

    \

    A vacuole is a saclike structure that is used to store materials such as water,
    salts, proteins, and carbohydrates. In many plant cells there is a single, and
    large central vacuole filled with liquid. The pressure of central vacuole in
    this cells makes it possible for plants to support heavy structures such as
    leaves and flowers. Some animals and some unicellular organisms contain
    contractile vacuoles which contract rhythmically to pump excess water out

    of the cell.

    as

    x

    The cell nucleus contains nearly all the cell’s DNA with the coded
    instructions for making proteins and other important molecules. The nucleus
    is surrounded by a double nuclear envelope, which allow materials to move
    into and out of the nucleus through nuclear pores. The granules found in the
    nucleus are called chromatin which consist of DNA bound to protein. When
    a cell divides, the chromatin condenses into chromosomes containing the
    genetic information. The nucleus contains a dense spherical structure called

    nucleolus in which assembly of ribosomes occurs.

    s

    Chloroplasts are the site of photosynthesis in plant cells. These are found
    in plant cells and in cells of some protoctists. They also have two membranes
    separated by a fluid-filled space. The inner membrane is continuous, with
    thylakoids. A stalk of thylakoids is called a granum (plural: grana). A
    chloroplast contains many sets of disc like sacs called thylakoids, which
    are arranged in stacks known as grana. Each granum looks like a stack of
    coins where each coin being a thylakoid. The thylakoid contains chlorophyll
    molecules which capture the light energy that is needed for in the process of
    light-dependent reactions of photosynthesis. A typical chloroplast contains
    approximatively 60 grana, each consisting of about 50 thylakoids. The space
    outside the thylakoid membranes are made by watery matrix called stroma.
    The stroma contains enzymes responsible for light-independent reactions of

    photosynthesis.

    zs

    Mitochondrion have two membranes separated by a fluid-filled intermembrane
    space. The inner membrane is highly folded to form cristae that plays a big
    role in aerobic respiration. The central part of the mitochondrion is called
    matrix. The mitochondria are the site where Adenosine triphosphate

    (ATP= cellular energy) is produced during aerobic respiration.

    s

    3.3.1. Similarities between animal cell and plant cell
    –– Both animal and plant cells have a cell membrane, a cytoplasm and a nucleus.
    –– Both animal and plant cells have a true nucleus bounded by an envelope.
    –– Both animal and plant cells have mitochondria, Golgi apparatus, Reticulum endoplasmic, lysosome, big ribosomes (80S), peroxisome, microtubules.
    –– The protoplasm is enveloped by a bounding cell membrane called plasmalemma.
    –– The protoplasm is composed of a dense round structure called nucleus which is surrounded by a less dense jelly-like  cytoplasm.
    –– Vacuoles contain secretions, food- particles, or decomposing organic substances.
    –– Chemically, both plant and animal cells are made up of water (80-90%), proteins (7-13%), lipids (1-2%), carbohydrates (1-1.5%) and inorganic salts.
    –– The cytoplasmic organelles are suspended in a semi-fluid jelly matrix called cytosol.


    3.3.2. Difference between animal and plant cells

    z

    s

    End unit assessment
    A. Multiple choice questions
    1. Which organelle converts the chemical energy in food into a form
    that cells can use?
    a) Chromosome
    b) Chloroplast
    c) Nucleus
    d) Mitochondrion
    2. The cell membranes are constructed mainly of:
    a) Carbohydrate gates
    b) Protein pumps
    c) Lipid bilayer
    d) Free-moving proteins
    3. In many cells, the structure that controls the cell’s activities is the:
    a) Nucleus
    b) Nucleolus
    c) Cell membrane
    d) Organelle
    4. Despite differences in size and shape, all cells have cytoplasm and a
    5.a) Cell wall
    b) Cell membrane
    c) Mitochondria
    d) Nucleus
    If a cell of an organism contains a nucleus, the organism is a (an)
    a) Plant
    b) Eukaryote
    c) Animal

    d) Prokaryote

    6.Match each part of the cell (left column) to corresponding statement

    (right column):

    z


    7. How does a cell membrane differ from a cell wall?
    8. Name the structures that animal and plant cells have in common,
    those found in only plant cells, and those found only in animal cells.
    9. List:
    a) Three organelles each lacking a boundary membrane
    b) Three organelles each bounded by a single membrane
    c) Three organelles each bounded by two membranes (an envelope
    10. The diagram below shows the structure of a liver cell as seen using

    an electron microscope.

    zsz

    a) Name the parts labelled A, B, C and D.
    b) The magnification of the diagram above is 12 000. Calculate the
    actual length of the mitochondrion labelled M, giving your answer in μm. Show your working.
    c) Explain the advantage to have a division of labor between different cells in the body.


  • UNIT 4: INTRODUCTION TO BIODIVERSITY

    QA

    ZS

    Species is a group of closely related organisms which are capable of
    interbreeding to produce fertile offspring. Occasionally two organisms which
    are genetically closely related but not of the same species can interbreed
    to produce infertile offspring. For example, a cross between a donkey and
    a horse, produces a mule, which is infertile. Hence, a donkey and a horse
    do not belong in the same species. Another example includes lions and
    tigers belonging in different species. However, when a male tiger mates
    with a female lion they can have fertile offspring called tiglon, although the
    offspring of female tigers and male lions called ligers are not fertile. Note
    that normally tigers are forest dwellers and lions are plains dwellers and they
    are ecologically isolated. Breeding has only been observed in captivity.

    An ecological population is a group of individuals of the same species
    which live in a particular area at any given time.

    An ecological community consists of populations of different species
    which live in the same place at the same time, and interact with each other.
    A habitat is a specific area or place in which an individual organism lives.
    When a habitat is very small it is regarded as a microhabitat.

    Within the habitat, an ecological niche is the status or the role of an
    organism in its habitat or the mode of life of an organism within its habitats.
    For example, insects are pollinating agents and preys of insectivores.
    In an environment, communities are influenced either by abiotic components,
    also called abiotic factors. These are the non-living physical aspects of the
    environment such as the sunlight, soil, temperature, wind, water, and air.
    Communities are also influenced by biotic components, or biotic factors.
    These are the living organisms in the environment.

    The biosphere is the whole of the earth’s surface, the sea and the air that is
    inhabited by living organisms. The biosphere is made up of all ecosystems.
    An ecosystem is a collection of all the organisms that live together in a

    particular place, together with their nonliving, or physical environment.

    ZS

    Biodiversity is defined as the full range of variety and variability within and
    among living organisms and the ecological complexes in which they occur.
    In other words, biodiversity is the variety of life. It refers to the totality of the
    species including the genetic variation represented in the species populations,
    across the full range of terrestrial organisms, including vertebrates and

    invertebrates, protista, bacteria and plants.

    A

    Biodiversity is can be categorized into three groups:
    –– Genetic diversity (c): The combination of different genes found within
    a population of a single species, and the patterns of variation found
    within different populations of the same species. These variations are
    caused by the gene mutations or chromosomal mutations which create
    differences in individuals of the same species.

    –– Species diversity (b): This is concerned with variation in number of
    species and their relative abundance in an area in which they inhabit.
    All species are different from each other. These could be structural
    differences, such as the difference between a mango tree and a cow.
    They could also be functional differences, such as the differences
    between bacteria that cause decay and those that help us to digest
    food. The variation in the relative abundance of species within a habitat
    may be caused by different factors, mainly environmental factors which
    can affect their rate of reproduction.

    –– Ecosystem diversity (a) : This is concerned with variations in
    ecosystems or habitats that occur within a region. Environmental
    factors like climate change may cause diversity of habitats or systems
    within a region.

    –– Functional diversity
    Biodiversity / biological diversity means the variability among living
    organism from all sources and ecological complex of which they
    are part. In general a species rich ecosystem is presumed to have
    high functional diversity, because there are many species with many

    different behaviour.

    S

    Looking anywhere around we can help us appreciate the beauty biodiversity
    gives our environment. Beyond beauty, why is biodiversity important?
    Biodiversity and its maintenance are very important for sustaining life on
    earth. The points below guide carrying out of importance of biodiversity:
    1. Importance to the nature
    Biodiversity maintains food chain in the nature, all living things in environment
    are interdependent. Animals could not exist without green plants. These
    plants could not exist without animals to pollinate them. These plant are
    dependent on decomposers. Whereas some living things can be niches for
    others living things. Thus, living things have many complex relationships
    among organisms.

    They are adapted to live together in communities. If a species is lost from an
    ecosystem the lost may have consequences for others living things in the
    area. An organism suffers when a plant or animal it feed upon is removed

    permanently from a food web.

    z

    Looking anywhere around we can help us appreciate the beauty biodiversity
    gives our environment. Beyond beauty, why is biodiversity important?
    Biodiversity and its maintenance are very important for sustaining life on
    earth. The points below guide carrying out of importance of biodiversity:

    1. Importance to the nature
    Biodiversity maintains food chain in the nature, all living things in environment
    are interdependent. Animals could not exist without green plants. These
    plants could not exist without animals to pollinate them. These plant are
    dependent on decomposers. Whereas some living things can be niches for
    others living things. Thus, living things have many complex relationships
    among organisms.

    They are adapted to live together in communities. If a species is lost from an
    ecosystem the lost may have consequences for others living things in the
    area. An organism suffers when a plant or animal it feed upon is removed
    permanently from a food web.

    Genetic biodiversity, arboreal plants, such as trees, tend to have more
    genetic diversity, on the whole, than vascular plants, such as grasses. This
    holds true both within populations and within the different species.

    Large populations are more likely to maintain genetic material and thus
    generally have higher genetic diversity. Hence, genetic diversity plays an
    important role in the survival and adaptability of a species.

    Maintaining balance of the ecosystem, a population may soon exceed the
    area’s carrying capacity if its predator is removed; if the symbiotic relationship
    among organisms are broken due to the loss of species, the remaining
    species will also be affected.

    Biodiversity protects water resources, natural vegetation cover in water
    catchments help to maintain hydrological cycles, regulating and stabilising
    water runoff, and acting as a buffer against extreme events such as flood
    and drought.

    Biodiversity increases ecosystem productivity where each species, no matter
    how small, all have an important role to play, a large number of plant species
    means a greater variety of crops. Greater species diversity ensures natural
    sustainability for all life forms.

    Promote soils formation and protection, the well-being of all plants and land-
    based animals depends on the complex processes that take place in soil.
    Soil develop from parent material by various weathering processes. Organic
    matter accumulation, decomposition, and humification are as critically
    important to soil formation as weathering.

    Provision of biological resources, biodiversity provides main ecosystem
    service such as nutrient cycling, carbon sequestration, pest regulation and
    pollination, sustain agriculture productivity. Promoting the healthy functioning
    of ecosystems ensures the resilience of agriculture as it intensifies to meet
    growing demands for food production.

    2. Importance to people
    By diverse species of plants and algae living in variety of ecosystem through
    photosynthesis process, regularly supply oxygen for breathing process to
    human being. Yet only a few species of plants and animals supply the major
    portion of food eaten by the human population.

    Drugs companies manufacture synthetic drugs are first isolated from living
    things. Example, mold penicillium provides an antibiotic penicillium, cinchona
    tree release antimalarial drug etc Preserving biodiversity ensures there will

    be a supply of living things, some of which may provide future drugs.

    x

    Biodiversity and food security, the provisioning of clean water and diverse
    food supply makes it vital for all living things, biodiversity helps regulate the
    nutrients cycle and water and mitigates impacts of climate change

    3. Biodiversity stability
    Biodiversity can bring stability to ecosystems. These are stable if their
    biodiversity is maintained. Instead of being clumped together, the plants are
    scattered in many parts of the rain forest, making it more difficult for the

    disease organism to spread.

    z

    4.4.1. Threats of biodiversity
    the main causes of biodiversity loss can be attributed to the influence of
    human activities on ecosystems. Threats to biodiversity may include:
    a. Habitat loss and the degradation of the environment
    The habitat loss and the degradation of the environment occur in different
    ways.

    The most occurring, are tree cutting, agriculture and fires. These human
    activities lead to the alteration and loss of suitable habitats for biodiversity.
    As a consequence, there is a loss of plant species as well as the decrease
    in the animal species associated to this plant diversity.

    b. ntroduction of invasive species and genetically modified
    organisms

    Species originating from a particular area are harmful to native species
    also called endemic species when they are introduced into new natural
    environments. They can lead to different forms of imbalance in the ecological
    equilibrium, so that endemic species may fail to compete with introduced
    species, and they may affect the abundance and distribution in natural
    habitat.

    c. Pollution
    Human activities such as excessive use of fertilizers, and increased pollutants
    from industries and domestic sewage affect biodiversity. They contribute to
    the alteration of the flow of energy, chemicals and physical constituents of the
    environment and hence species may die as a result of toxic accumulation.

    d. Overexploitation of natural resources
    Increased hunting, fishing, and farming in particular areas lead to the decrease
    and loss of biodiversity due to excessive and continuous harvesting without
    leaving enough time for the organisms to reproduce and stabilize in their
    natural habitat.

    e. Climate change
    This is a change in the pattern of weather, related changes in oceans, land
    surfaces and ice sheets due to global warming resulting from man’s activities.
    Increasing global temperatures have resulted into melting of icebergs raising
    sea levels and so flooding coastal areas eventually affecting the niche, and

    these may take the lives on many living things.

    4.4.2. Consequences of loss of biodiversity
    They are various consequences of loss of biodiversity that include:
    –– Desertification, is thought by scientists to be a consequence of climate
    change, has been considered to be related to deforestation. Disrupting
    water cycles and soil structure results into less rainfall in an area.
    –– Floods as a result of rising sea levels.
    –– Habitat destruction for extensive farming, timber harvesting and infrastructure and settlement.
    –– Decrease in food production as result of change in pattern of weather that affects productivity
    –– Large scale deforestation has a negative effect on nutrient recycling and can accelerates soil erosion.

    –– Diseases that come as effects of floods and malnutrition due to famine

    d

    d

    1.Explain what is meant by a habitat and make a list of all the habitats you can see in your school compound.
    2. Pollution is one of the causes of aquatic biodiversity loss.
    a) What do you understand by water pollution?
    b) Outline human activities that contribute to water pollution
    c) Discuss how polluted water affects aquatic living organisms?

    d) Relate desertification with biodiversity loss.

  • UNIT 5: INTRODUCTION TO CLASSIFICATION

    x

    xs

    zs

    Taxonomy is the study of classification of living organisms in taxonomic
    levels called taxa (singular: taxon). In biological classification, these taxa
    form a hierarchy. Each kind of organism is assigned to its own species, and
    similar species are grouped into a genus (plural: genera). Similar genera are
    grouped into a family, families into an order, orders into a class, classes into a
    phylum (plural: phyla) and phyla into a kingdom. The hierarchy classification
    starts from the largest group, the domain.

    The eight levels of classification are known as taxa (taxon in singular),
    these include: Domain, Kingdom, phylum, class, order, family, genus
    and species. As one moves down the taxonomic hierarchy, it follows that
    the number of individuals decreases but the number of common features

    increases.

    s

    sd

    Three domains are used by biologists to divide organisms into three large
    groups based on their cell structure. The domain is the highest taxon in the
    hierarchy. The prokaryotes are divided between the domains Eubacteria/
    Bacteria and Archaebacterial/ Archea, while all the eukaryotes are placed
    into the domain Eukarya.

    5.2.1. Domain eubacteria/ bacteria
    domain bacteria include prokaryotic organisms as their cells do not have
    defined, membrane-limited nuclei.
    They are all microscopic that vary in size between 0.2 to 10 micrometers.

    The characteristic features of bacteria are:
    –– Cells with no true nucleus
    –– DNA exists in circular chromosome and does not have histone proteins associated with it.
    –– No membrane-bound organelles (mitochondria, endoplasmic reticulum, Golgi body, chloroplasts)
    –– Contain mesosomes as infolding of membrane and acts as sites for respiration as they lack mitochondria.
    –– Ribosomes (70 S) are smaller than in eukaryotic cells
    –– Cell wall is always present and contains peptidoglycans in place of cellulose
    –– Cells divide by binary fission

    – Usually exist as single cells or colonies.

    s

    The bacteria are important when they help to fertilize fields, to recycle
    nutrients on earth, and to produce food and medicines. The bacteria that
    live in soil recycle the nitrogen and carbon contained in the complex organic
    molecules that remain in plants and animals after they have died. While
    most bacteria is found in many disease, bacteria is very useful to our lives
    because is found in the digestive system to help break down food.

    a. Domain Archaea (Archaebacteria)
    This contains bacteria that live in extreme environments where few other
    organisms can survive, like in volcanic hot springs and black organic mud
    totally devoid of Oxygen.
    Types and economic importance
    They are classified according to the environments they live in:
    –– Methanogenic bacteria that live in habitats deprived of oxygen and give
    off methane as a product of metabolism for example those that live in
    the guts of ruminant animals such as cows.
    –– Halophilic bacteria live only in water with high concentration of salt.
    –– Thermoacidophilic bacteria tolerate extreme acid and temperature that
    exceed boiling point of water and a pH below 2.They are autotrophic
    producer for a unique animal community’s food chain.

    b. Domain Eukarya
    All the organisms classified into this domain have cells with true nuclei
    and membrane-bound organelles. It include the four remaining kingdoms:
    protists, fungi, plantae and Animalia. Their characteristic features are:
    –– Cells with a nucleus and membrane-bounded organelles
    –– linear DNA associated with histones arranged within a chromosome inthe nucleus
    –– Ribosomes (80S) in the cytosol are larger than in prokaryotes, while chloroplasts and mitochondria have small ribosomes (70S ribosomes), like those in prokaryotes.
    –– Chloroplast and mitochondrial DNA is circular as in prokaryote suggesting an evolutionary relationship between prokaryotes and eukaryotes
     –– A great diversity of forms: unicellular, colonial and multicellular organisms
    –– Cell division is by mitosis.

    –– Many different ways of reproduction including asexually and sexually.

    zx

    5.3.1. Protoctista
    This kingdom is made up of a very diverse range of eukaryotic organisms,
    which includes those that are often called protozoans and algae. Living
    things such as paramecium, amoeba, euglena, algae and plasmodia belong

    to the kingdom Protoctista.

    d

    The characteristic features of protoctists are listed according to the different
    phyla due to their diverse range:
    –– Rhizopus that have pseudopodia for locomotion. Example, amoeba.
    –– Flagellates which are protoctista which move by using flagella. Example, Trypanosoma.
    –– Sporozoans which are mainly parasitic organisms that reproduces by multiple fission. Example plasmodium.
    –– Ciliates are protoctista which move with cilia. Example paramecium.
    –– Euglenoid flagellates which are organisms with flagella but with a biochemistry quite distinct from that of flagellates. Example Euglena.
    –– Green algae are photosynthetic protoctista with chlorophyll pigments. Example chlorella.
    –– Red algae are photosynthetic protoctista with red pigment as well as chlorophyll. Example, chondrus
    –– Brown algae which are photosynthetic protoctista with brown pigments as well as chlorophyll. Example Fucus and sea weed.

    NB: Some protists are used in food industry. eg saccharomyces cerevisiae
    ( yeast). The plants protists produce almost one half of the oxygen on the
    planet through photosynthesis. They participate in decomposition and

    recycling of nutrients that humans need to live.

    5.3.2. Fungi
    Fungi are all heterotrophic, obtaining energy and carbon from dead and
    decaying matter or by feeding as parasites on living organisms. There is a

    vast range in size from the microscopic yeasts to macroscopic fungi.

    z

    –– Heterotrophic nutrition.
    –– They use organic compounds made by other organisms as their sourceof energy and source of molecules for metabolism
    –– Reproduce asexually by means of spores and sexually by conjugation.
    –– Simple body form, which may be unicellular or made up of long threads called hyphae (with or without cross walls).
    –– Large fungi such as mushrooms produce large compacted masses of hyphae known as fruiting bodies to release spores.
    –– Cells have cell walls made of chitin or other substances.

    NB: As economic importance some mushrooms are used as food,
    saprophytic fungi such as mucor spp/Rhizopus spp are used in the curing
    of tea and tobacco; the fungi decompose organic matter helping to clean the
    environment and recycle materials.

    5.3.3. Plantae
    Plants are all multicellular photosynthetic organisms. They have complex
    bodies that are often highly branched both above and below the ground.

    Characteristic features of plants are:
    –– Multicellular eukaryotes with cells that are differentiated to form tissues and organs.
    –– Few specialized cells.
    –– Cells have large and often permanent vacuoles for support with cell walls made of cellulose.
    –– Autotrophic living organisms (most plants contain chlorophyll and store carbohydrates as starch or sucrose).
    –– Usually plants are green
    –– Roots ,stems and leaves
    –– Sexual and asexual reproduction

    NB: People depend upon plants to satisfy such basic human need as food,
    clothing, shelter and health care.

    5.3.4. Animalia
    Animals are multicellular organisms that are all heterotrophic with different

    methods of obtaining their food.

    s

    Organisms in Animalia kingdom share the following features:
    –– Multicellular (different types of specialized cells).
    –– Eukaryotic
    –– Heterotrophic (cells do not have chloroplasts and cannot photosynthesize,
    although some, such as coral polyps have photosynthetic protoctists

    living within their tissues).

    –– Cell vacuoles are small and temporary (for example lysosomes and
    food vacuoles).
    –– Cells do not have cell walls.
    –– Sense organs (communication is by the nervous system)
    –– Motile, at least for part of their life

    NB: Many animals are helpful to humans; many varieties of livestock are
    kept because they add protein to our diets in the form of meat, milk products,
    and egg. Fiber bearing animals such as sheep provide material for making clothing
    5.3.5. Monera
    Organisms in this kingdom are unicellular, that do not have a nucleus. They
    are prokaryotic. They are the smallest and simplest organisms. Some of
    them stick together to form chains or clusters while others are single cells.
    The figure below shows a typical structure of a bacterial cell which contains
    all the main features of prokaryotes.

    Although some of them are harmful in causing human diseases, others are
    beneficial species that are essential to good health, as they are involved in

    food industry, medicine and in pharmacy.

    a

    d

    NB: About economic importance of monera kingdom, many of Nostoc
    species fix atmospheric nitrogen and thus increase soil fertility. They are
    also important in the manufacturing and services industries ( eg production
    of many dietary supplements and pharmaceuticals)
    de
    –– Presence or absence of the envelope: Plant viruses’ bacteriophage
    are no enveloped while animal viruses like HIV and influenza virus are
    enveloped.

    5.4.2. Characteristics of viruses
    Viruses are microorganisms whose structure is only visible with electron
    microscopes. A typical virus consists of DNA or RNA within a protective
    protein coat called capsid which provides protection. Viruses become active
    in metabolism only once inside the host cell. When they infect cells, they
    use biochemical machinery and proteins of the host cell to copy their nucleic
    acids and to make proteins coats often leading to destruction of the host
    cells. The energy for these processes is provided by the ATP from the host
    cell. Because viruses do not consist of cells, they also lack cell membranes,
    cytoplasm, ribosomes, and other cell organelles. Without these structures,
    they are unable to make proteins or even reproduce on their own. Instead,
    they must depend on a host cell to synthesize their proteins and to make
    copies of themselves. Viruses infect and live inside the cells of living
    organisms. They are also regarded as parasites since they depend entirely
    on living cells for their survival. Although viruses are not classified as living
    things, they share two important traits with living things: They have genetic

    material, and they can evolve.

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  • UNIT 6: MOTION ON A STRAIGHT LINE

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    In our daily lives, we come across various objects moving from one point to
    the other. The objects are said to be in motion. People, animals and machines
    are from time to time involved in motion in different directions. Motion in a
    straight line is called linear motion.

    In this unit, we are going to study linear motion. We shall pay attention to the
    time taken, distance covered, speed, velocity and acceleration of the motion
    and their relationships.
    There are two types of linear motion namely: uniform motion and non-uniform
    motion.

    Uniform motion
    In this motion, the speed of the moving remains the same or constant.
    Non-uniform or uniform accelerated motion
    In this motion the speed of an object changes at a constant rate, a good

    example is the free fall.

    6.1.1. Distance and displacement
    Distance

    Distance is the total length of the path followed by an object, regardless of
    the direction of motion. It is a scalar quantity and measured in units of length.
    The SI unit of distance is the metre (m). Long distances may be measured in
    kilometers (km) while short distances may be measured in centimeters (cm)
    or millimeters (mm).

    It should be noted that in determining the distance between two points, the
    direction at any point along the path is not considered. The direction along

    the path may keep on changing or remain constant.

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    Displacement
    Displacement is the object’s overall change in position from the starting to
    the end point. It is the shortest distance along a straight line between two
    points in the direction of motion. The SI unit of displacement is the metre (m).
    To fully describe displacement, you need to specify how far you have
    travelled from where you started and in what direction you have travelled.
    For example, point A is 100 kilometres Northwest of point B. In diagrams,
    an arrowhead indicates the direction of motion (. Displacement is a vector

    quantity.

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    6.1.2. Average velocity and instantaneous velocity
    velocity or speed may be defined as the rate at which something happens,
    moves or functions within a time interval, that is, how fast is a progress,
    movement or an operation. In general, the average speed of an object is
    defined as the covered distance divided by the time it takes to travel this
    distance.
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    Suppose that an object is moving on X-axis so that at an instant t 0 , the
    object is at point (coordinate) x0, and at another later instant t the object is
    at point x.




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    One of the most common examples of uniformly accelerated rectilinear
    motion is that of an object allowed to fall freely near the Earth’s surface.
    For free fall, Galileo postulated that: “at a given location of the Earth and in
    the absence of air or other resistance all objects fall with the same constant
    acceleration”. In the free-fall motion air resistance is negligible and the action
    can be considered due to gravity alone.

    We call this acceleration the acceleration due to gravity on the Earth, and
    we give it the symbol g . Its magnitude is approximately g = − 9.8 m / s 2 . g
    varies slightly according to latitude and elevation. The effects of air resistance
    are often small, and we will neglect them for the most part. We will also
    suppose that an object moves along Y-axis.

    6.3.1. Object thrown downward
    a. General condition

    Suppose an object released to fall from a height y 0 . The vectors of g and
    v0 are parallel. The following figure shows how the ball accelerates within

    equivalent time intervals.

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