• Flower structure; Development of male and female gametophytes;
• Pollination-types, agencies and examples;
• Outbreeding devices;
• Pollen-Pistil interaction;
• Double fertilisation;
• Post fertilisation events-Development of endosperm and embryo, Development of seed and formation of fruit;
• Special modes-apomixis, parthenocarpy,
• polyembryony;
• Significance of seed and fruit formation.

2 Human Reproduction:

• Male and female reproductive systems;
• Microscopic anatomy of testis and ovary; Gametogenesis-spermatogenesis & oogenesis;
• Menstrual cycle;
• Fertilisation, embryo development upto blastocyst formation, implantation;
• Pregnancy and placenta formation (Elementary idea);
• Parturition (Elementary idea); Lactation (Elementary idea).

3 Reproductive health:

• Need for reproductive health and prevention of sexually transmitted diseases (STD);
• Birth control-Need and Methods, Contraception and Medical Termination of Pregnancy (MTP); Amniocentesis;
• Infertility and assisted reproductive technologies – IVF, ZIFT, GIFT (Elementary idea for general awareness).

• Mendelian Inheritance;
• Deviations from Mendelism-Incomplete dominance, Co-dominance, Multiple alleles and Inheritance of blood groups, Pleiotropy; Elementary idea of polygenic inheritance; Chromosome theory of inheritance; Chromosomes and genes;
• Sex determination-In
• humans, birds, honey bee;
• Linkage and crossing over; Sex-linked inheritance-Haemophilia, Colour blindness; Mendelian disorders in humans-Thalassemia;
• Chromosomal disorders in humans; Down’s syndrome, Turner’s and Klinefelter’s syndromes.

2. Molecular basis of Inheritance:

• Search for genetic material and DNA as genetic material;
• Structure of DNA and RNA; DNA packaging;
• DNA replication; Central dogma; Transcription, genetic code, translation;
• Gene expression and regulation-Lac Operon;
• Genome and human genome project;
• DNA fingerprinting.

3. Evolution: Origin of life;

• Biological evolution and evidence for biological evolution from Paleontology, comparative anatomy, embryology and molecular evidence);
• Darwin’s contribution, Modern Synthetic theory of Evolution; Mechanism of evolution variation (Mutation and Recombination) and Natural Selection with examples and types of natural selection;
• Gene flow and genetic drift;
• Hardy-Weinberg’s principle;
• Adaptive Radiation; Human evolution.

• Pathogens;
• Parasites causing human diseases (Malaria, Filariasis, Ascariasis. Typhoid, Pneumonia, common cold, amoebiasis, ringworm);
• Basic concepts of immunology-vaccines; Cancer, HIV and AIDS; Adolescence, drug and alcohol abuse.

2. Microbes in human welfare:

• In household food processing, industrial production, sewage treatment, energy generation and as biocontrol agents and biofertilisers.

• Genetic engineering (Recombinant DNA technology).

2. Application of Biotechnology in health and agriculture:

• Human insulin and vaccine production, gene therapy;
• Genetically modified organisms-Bt crops;
• Transgenic Animals; Biosafety issues-Biopiracy and patents.

• Habitat and niche; Population and ecological adaptations;
• Population interactions-mutualism, competition, predation, parasitism;
• Population attributes-growth, birth rate and death rate, age distribution.

2. Ecosystem:

• Patterns, components; productivity and decomposition;
• Energy flow; Pyramids of number, biomass, energy; Nutrient cycling (carbon and phosphorous);
• Ecological succession; Ecological Services-Carbon fixation, pollination, oxygen release.

3. Biodiversity and its conservation:

• Concept of Biodiversity;
• Patterns of Biodiversity; Importance of Biodiversity;
• Loss of Biodiversity; Biodiversity conservation;
• Hotspots, endangered organisms, extinction, Red Data Book, biosphere reserves, National parks and sanctuaries.

• Physics: scope and excitement; nature of physical laws; Physics, technology and society
• Need for measurement – units of measurement; systems of units; SI units, fundamental and derived units. Length, mass and time measurements; accuracy and precision of measuring instruments; errors in measurement; significant figures. Dimensions of physical quantities, dimensional analysis and its applications

• Frame of reference, motion in a straight line; position-time graph, speed and velocity. Uniform and non-uniform motion, average speed and instantaneous velocity. Uniformly accelerated motion, velocity-time and position-time graphs for uniformly accelerated motion (graphical treatment)
• Elementary concepts of differentiation and integration for describing motion. Scalar and vector quantities: Position and displacement vectors, general vectors, general vectors and notation, equality of vectors, multiplication of vectors by a real number; addition and subtraction of vectors. Relative velocity
• Unit vectors. Resolution of a vector in a plane-rectangular components
• Scalar and vector products of vectors. Motion in a plane. Cases of uniform velocity and uniform acceleration – projectile motion. Uniform circular motion.

• Intuitive concept of force. Inertia, Newton’s first law of motion; momentum and Newton’s second law of motion; impulse; Newton’s third law of motion. Law of conservation of linear momentum and its applications
• Equilibrium of concurrent forces. Static and kinetic friction, laws of friction, rolling friction, lubrication
• Dynamics of uniform circular motion. Centripetal force, examples of circular motion (vehicle on level circular road, vehicle on banked road)

• Work done by a constant force and variable force; kinetic energy, work-energy theorem, power.
• Notion of potential energy, potential energy of a spring, conservative forces; conservation of mechanical energy (kinetic and potential energies); non-conservative forces; motion in a vertical circle, elastic and inelastic collisions in one and two dimensions.

• Centre of mass of a two-particle system, momentum conservation and centre of mass motion. Centre of mass of a rigid; Centre of mass of uniform rod
• Momentum of a force – torque, angular momentum, conservation of angular momentum with some examples
• Equilibrium of rigid bodies, rigid body rotation and equation of rotational motion, comparison of linear and rotational motions; moment of inertia, radius of gyration. Values of M.I. for simple geometrical objects (no derivation). Statement of parallel and perpendicular axes theorems and their applications

• Kepler’s law of planetary motion. The universal law of gravitation. Acceleration due to gravity and its variation with altitude and depth
• Gravitational potential energy; gravitational potential. Escape velocity, orbital velocity of a satellite. Geostationary satellites

• Elastic behavior, stress-strain relationship. Hooke’s law, Young’s modulus, bulk modulus, shear, modulus of rigidity, poisson’s ratio; elastic energy
• Viscosity, Stoke’s law, terminal velocity, Reynold’s number, streamline and turbulent flow. Critical velocity, Bernoulli’s theorem and its applications.
• Surface energy and surface tension, angle of contact, excess of pressure, application of surface tension ideas to drops, bubbles and capillary rise
• Heat, temperature,thermal expansion; thermal expansion of solids, liquids and gasses. Anomalous expansion. Specific heat of capacity:Cp, Cv-calorimetry; change of state-latent heat
• Heat transfer – conduction and thermal conductivity, convection and radiation. Qualitative ideas of Black body radiation. Wein’s displacement law, and green house effect.
• Newton’s law of cooling and Stefan’s law

• Thermal equilibrium and definition of temperature (zeroth law of thermodynamics). Heat, work and internal energy. First law of thermodynamics. Isothermal and adiabatic processes.
• Second law of thermodynamics: Reversible and irreversible processes. Heat engines and refrigerators

• Equation of state of a perfect gas, work done on compressing a gas
• Kinetic theory of gases: Assumptions, concept of pressure. Kinetic energy and temperature; degrees of freedom, law of equipartition of energy (Statement only) and application to specific heat capacities of gases; concept of mean free path

• Periodic motion-period, frequency, displacement as a function of time. Periodic functions. Simple harmonic motion(SHM) and its equation; phase; oscillations of a spring-restoring force and force constant; energy in SHM – Kinetic and potential energies; simple pendulum – derivation of expression for its time period; free and forced and damped oscillations (qualitative ideas only), resonance
• Wave motion. Longitudinal and transverse waves, speed of wave motion. Displacement relation for a progressive wave. Principle of superposition of waves, reflection of waves, standing waves in strings and organ pipes, fundamental mode and harmonics. Beats. Doppler effect.