JEE Advanced Chemistry Syllabus 2021 JEE (Advanced) organized by IIT Delhi offers admission into undergraduate courses leading to a Bachelor’s, Integrated Masters or Bachelor-Master Dual Degree in Engineering, Sciences, or Architecture.
All aspirants of JEE Advanced you should know the syllabus of the JEE Advanced exam. Aspirants must cover all the topics of Mathematics, Physics, Chemistry, and Architecture Aptitude Test from class 11th and 12th, standard. Along with NCERT books, aspirants can study from JEE reference books JEE study materials. Aspirants should also solve questions from past year papers of JEE Advanced to know what type of questions you can expect in the examination and how you can solve it to a minimum time.
We come up with JEE Advanced 2021 guide that will help you to prepare well in the exam all important information we collected together it saves your time.
JEE Advanced Chemistry Syllabus 2021
Concept of atoms and molecules; Dalton’s atomic theory; Mole concept; Chemical formulae; Balanced chemical equations; Calculations (based on mole concept) involving common oxidation-reduction, neutralization, and displacement reactions; Concentration in terms of mole fraction, molarity, molality, and normality.
Gaseous and liquid states
Absolute scale of temperature, ideal gas equation; Deviation from ideality, van der Waals equation; Kinetic theory of gases, average, root mean square, and most probable velocities and their relation with temperature; Law of partial pressures; Vapour pressure; Diffusion of gases.
Atomic structure and chemical bonding
Bohr model, the spectrum of the hydrogen atom, quantum numbers; Wave-particle duality, de Broglie hypothesis; Uncertainty principle; Qualitative quantum mechanical picture of the hydrogen atom, shapes of s, p, and d orbitals; Electronic configurations of elements (up to atomic number 36); Aufbau principle; Pauli’s exclusion principle and Hund’s rule; Orbital overlap and covalent bond; Hybridisation involving s, p, and d orbitals only; Orbital energy diagrams for homonuclear diatomic species; Hydrogen bond; Polarity in molecules, dipole moment (qualitative aspects only); VSEPR model and shapes of molecules (linear, angular, triangular, square planar, pyramidal, square pyramidal, trigonal bipyramidal, tetrahedral, and octahedral).
The first law of thermodynamics; Internal energy, work, and heat, pressure-volume work; Enthalpy, Hess’s law; Heat of reaction, fusion, and vapourization; Second law of thermodynamics; Entropy; Free energy; Criterion of spontaneity.
Law of mass action; Equilibrium constant, Le Chatelier’s principle (effect of
concentration, temperature, and pressure); Significance of ΔG and ΔG0 in chemical equilibrium; Solubility product, common ion effect, pH and buffer solutions; Acids and bases (Bronsted and Lewis concepts); Hydrolysis of salts.
Electrochemical cells and cell reactions; Standard electrode potentials; Nernst equation and its relation to ΔG; Electrochemical series, emf of galvanic cells; Faraday’s laws of electrolysis; Electrolytic conductance, specific, equivalent and molar conductivity, Kohlrausch’s law; Concentration cells.
Rates of chemical reactions; Order of reactions; Rate constant; First order reactions; Temperature dependence of rate constant (Arrhenius equation).
Classification of solids, crystalline state, seven crystal systems (cell parameters a, b, c, α, β, γ), the close-packed structure of solids (cubic), packing in fcc, bcc, and hcp lattices; Nearest neighbors, ionic radii, simple ionic compounds, point defects.
Raoult’s law; Molecular weight determination from lowering of vapour pressure, the elevation of boiling point and depression of freezing point.
Elementary concepts of adsorption (excluding adsorption isotherms); Colloids: types, methods of preparation and general properties; Elementary ideas of emulsions, surfactants, and micelles (only definitions and examples).
Radioactivity: isotopes and isobars; Properties of α, β and γ rays; Kinetics of radioactive decay (decay series excluded), carbon dating; Stability of nuclei with respect to proton-neutron ratio; Brief discussion on fission and fusion reactions.
Isolation/preparation and properties of the following non-metals Boron, silicon, nitrogen, phosphorus, oxygen, sulphur and halogens; Properties of allotropes of carbon (only diamond and graphite), phosphorus and sulphur.
Preparation and properties of the following compounds
Oxides, peroxides, hydroxides, carbonates, bicarbonates, chlorides and sulphates of sodium, potassium, magnesium and calcium; Boron: diborane, boric acid and borax; Aluminium: alumina, aluminium chloride and alums; Carbon: oxides and oxyacid (carbonic acid); Silicon: silicones, silicates and silicon carbide; Nitrogen: oxides, oxyacids and ammonia; Phosphorus: oxides, oxyacids (phosphorus acid, phosphoric acid) and phosphine; Oxygen: ozone and hydrogen peroxide; Sulphur: hydrogen sulphide, oxides, sulphurous acid, sulphuric acid and sodium thiosulphate; Halogens: hydrohalic acids, oxides and oxyacids of chlorine, bleaching powder; Xenon fluorides.
Transition elements (3d series)
Definition, general characteristics, oxidation states, and their stabilities, color (excluding the details of electronic transitions) and calculation of spin only magnetic moment; Coordination compounds: nomenclature of mononuclear coordination compounds, cis-trans and ionization isomerism, hybridization and geometries of mononuclear coordination compounds (linear, tetrahedral, square planar and octahedral).
Preparation and properties of the following compounds
Oxides and chlorides of tin and lead; Oxides, chlorides and sulphates of Fe2+, Cu2+ and Zn2+; Potassium permanganate, potassium dichromate, silver oxide, silver nitrate, silver thiosulphate.
Ores and minerals
Commonly occurring ores and minerals of iron, copper, tin, lead, magnesium, aluminium, zinc and silver.
Chemical principles and reactions only (industrial details excluded); Carbon reduction method (iron and tin); Self-reduction method (copper and lead); Electrolytic reduction method (magnesium and aluminium); Cyanide process (silver and gold).
Principles of qualitative analysis
Groups I to V (only Ag+, Hg2+, Cu2+, Pb2+, Bi3+, Fe3+, Cr3+, Al3+, Ca2+, Ba2+, Zn2+, Mn2+ and Mg2+); Nitrate, halides (excluding fluoride), sulphate and sulphide.
The hybridization of carbon; σ and π-bonds; Shapes of simple organic molecules; Structural and geometrical isomerism; Optical isomerism of compounds containing up to two asymmetric centres, (R,S and E,Z nomenclature excluded); IUPAC nomenclature of simple organic compounds (only hydrocarbons, mono-functional and bi-functional
compounds); Conformations of ethane and butane (Newman projections); Resonance and hyperconjugation; keto-enol tautomerism; Determination of empirical and molecular formulae of simple compounds (only combustion method); Hydrogen bonds: definition and their effects on physical properties of alcohols and carboxylic acids; Inductive and resonance effects on acidity and basicity of organic acids and bases; Polarity and inductive effects in alkyl halides; Reactive intermediates produced during homolytic and heterolytic bond cleavage; Formation, structure and stability of carbocations, carbanions and free radicals.
Preparation, properties, and reactions of alkanes
Homologous series, physical properties of alkanes (melting points, boiling points, and density); Combustion and halogenation of alkanes; Preparation of alkanes by Wurtz reaction and decarboxylation reactions.
Preparation, properties, and reactions of alkenes and alkynes
Physical properties of alkenes and alkynes (boiling points, density, and dipole moments); Acidity of alkynes; Acid-catalyzed hydration of alkenes and alkynes (excluding the stereochemistry of addition and elimination); Reactions of alkenes with KMnO4 and ozone; Reduction of alkenes and alkynes; Preparation of alkenes and alkynes by elimination reactions; Electrophilic addition reactions of alkenes with X2, HX, HOX and H2O (X=halogen); Addition reactions of alkynes; Metal acetylides.
Reactions of benzene
Structure and aromaticity; Electrophilic substitution reactions: halogenation, nitration, sulphonation, Friedel-Crafts alkylation, and acylation; Effect of o-, m- and p-directing groups in monosubstituted benzenes.
Acidity, electrophilic substitution reactions (halogenation, nitration, and sulphonation); Reimer-Tieman reaction, Kolbe reaction.
Characteristic reactions of the following (including those mentioned above)
Alkyl halides: rearrangement reactions of alkyl carbocation, Grignard reactions, nucleophilic substitution reactions; Alcohols: esterification, dehydration, and oxidation, reaction with sodium, phosphorus halides, ZnCl2/concentrated HCl, conversion of alcohols into aldehydes and ketones; Ethers: Preparation by Williamson’s Synthesis; Aldehydes and Ketones: oxidation, reduction, oxime and hydrazone formation; aldol condensation, Perkin reaction; Cannizzaro reaction; haloform reaction and nucleophilic
addition reactions (Grignard addition); Carboxylic acids: formation of esters, acid chlorides, and amides, ester hydrolysis; Amines: basicity of substituted anilines and aliphatic amines, preparation from nitro compounds, reaction with nitrous acid, azo coupling reaction of diazonium salts of aromatic amines, Sandmeyer and related reactions of diazonium salts; carbylamine reaction; Haloarenes: nucleophilic aromatic substitution
in haloarenes and substituted haloarenes (excluding Benzyne mechanism and Cine substitution).
Classification; mono- and disaccharides (glucose and sucrose); Oxidation, reduction, glycoside formation, and hydrolysis of sucrose.
Amino acids and peptides
General structure (only primary structure for peptides) and physical properties.
Properties and uses of some important polymers
Natural rubber, cellulose, nylon, Teflon, and PVC.
Practical organic chemistry
Detection of elements (N, S, halogens); Detection and identification of the following functional groups: hydroxyl (alcoholic and phenolic), carbonyl (aldehyde and ketone), carboxyl, amino, and nitro; Chemical methods of separation of mono-functional organic compounds from binary mixtures.
JEE Advanced Preparation Tips
JEE Advanced is one of the top engineering entrance exams and gives you a great opportunity to get admissions into India’s top IITs
Every one of you will try harder to get crack JEE Advanced and get admission to one of the best institutes in India. Cracking JEE Advanced is not an easy task sometimes it requires months or even years of hard work and preparation. Most of the aspirants usually start their preparations at least a year ahead while some tend to start a month or two before the scheduled examination date. While everybody has their own strategy and study plans for the exam preparation.
Here we come up with few tips
- SyllabusFirstly You should know the complete syllabus, understand the topics, and try to divide it according to your schedule.
- Selection of Study MaterialYes, selection of study material is most important for better preparation because it gives you the clarity to understand the topics in a better way. selection of books and help you a lot.
- Time TableThis plays a very important role in your preparation, Its completely in your hand to schedule it and plan your study. Plan your study pattern and stick to it is very important Self evaluate regularly
All JEE Advanced Tools including previous year question papers with key for all departments are also made available on the iStudy app, currently on Google Play. you can also visit the official site for more updates.