CHEMCA- Chemistry Made Easy

Organic Chemistry - Isomerism

Amines

Carboxylic Acids- Preparation, Physical Properties and Chemical Properties

Aldehydes and Ketones

Alcohol , Phenol and Ether

Haloalkanes and Haloarenes

Reaction Chart of Haloalkanes Reaction chart of Haloarenes E1 vs E2 Differences between SN1 and SN2 Haloalkanes and Haloarenes class notes

Basics of Organic Chemistry

GOC - IUPAC Nomenclature of Organic Compounds

Aromatic Hydrocarbons class notes

Hydrocarbons - Alkynes Notes

Hydrocarbons- Alkenes Notes

Hydrocarbons- Alkanes Notes

Periodic classification of elements

Ionic Equilibrium

Chemical Equilibrium

Thermodynamics

Atomic Structure

Mole Concept

- February 01, 2024

Quiz:1 Periodic Classification of Elements

- February 01, 2024

The Synergy of Industrial Automation and Chemical Engineering: A Perfect Blend for Progress

- January 31, 2024

In the ever-evolving landscape of industrial processes, the synergy between industrial automation and chemical engineering has become a driving force, propelling efficiency, safety, and innovation to new heights. These two disciplines, seemingly distinct, complement each other in a harmonious dance, revolutionizing how we approach manufacturing and production. Automation in Chemical Engineering: The role of chemical engineers has traditionally been deeply rooted in designing, optimizing, and overseeing chemical processes. With the advent of automation, the execution of these processes has undergone a transformative shift. Automation technologies, ranging from programmable logic controllers (PLCs) to advanced machine learning algorithms, have become integral in streamlining and enhancing various facets of chemical engineering. One significant area where automation has made an impact is in process control. Automated systems can monitor and adjust variables in real-time, ensuring precise

Problem Practice on conductivity and batteries (electrochemistry)

Problem Practice on Galvanic cells (Electrochemistry )

Problem Practice on Colligative Properties

Problem practice on Henry's Law, Raoult's law and ideal solution

Concentration Terms (Problem Practice)

Alcohol, phenol and ether (Problem Practice 1)

Bredt's Rule

- December 03, 2023

Organic Distinction Test

- December 03, 2023

1.Bayer's Test 2.Bromine water Test 3. Bradys Test /2,4-DNP Test 4. Tollens Test 5. Hinsberg test 6. Libermann's Nitroso Test 7. Lucas Test 8. Ferric chloride test 9. Fehling's test 10. Carbylamine Test 11. Victor meyer test 12.Iodoform Test

Types of Carbocation

Carbocations are reactive intermediates in organic chemistry characterized by a positively charged carbon atom with three bonds and an empty p orbital. Their instability makes them highly reactive, often serving as reaction intermediates in various organic transformations. Carbocations can be classified based on their substitution pattern as primary, secondary, or tertiary, with stability increasing in the order tertiary > secondary > primary due to hyperconjugation and inductive effects. Their reactivity influences reaction mechanisms, including electrophilic additions and substitutions

Branches of Chemistry

The four main branches of chemistry are: (1) Organic chemistry; (2) Inorganic chemistry; (3) Physical chemistry; (4) Analytical chemistry. (1) Organic chemistry : It is concerned with the study of compounds of carbon except carbonates, bicarbonates, cyanides, isocyanides, carbides and oxides of carbon. It is actually the study of hydrocarbons and their derivatives. (2) Inorganic chemistry : It deals with the study of all known elements and their compounds except organic compounds. It is concerned with the materials obtained from minerals, air, sea and soil. (3) Physical chemistry : It is concerned with the physical properties and constitution of matter, the laws of chemical combination and theories governing reactions. The effect of temperature, pressure, light, concentration, etc., on reactions come under the scope of physical chemistry. (4) Analytical chemistry : It deals with various methods of analysis of chemical substances both qualitative and qu

Rules of rounding off

Rounding off the uncertain digit : (a) If the left most digit to be rounded off is more than 5 , the preceding number is increased by one. Example : 2.16 is rounded to 2.2 (b) If the left most digit to be rounded off is less than 5 , the preceding number is retained. Example : 2.14 is rounded off to 2.1 (c) If the left most digit to be rounded off is equal to 5 , the preceding number is not changed if it is even and increased by one if it is odd. Example : 3.25 is rounded off to 3.2 2.35 is round off to 2.4

Significant figures

(A) Every scientific observation involves some degree of uncertainty depending upon the limitation of instrument. To represent scientific data, role of significant figures has its own importance. (B) Significant figures are equal to the number of digits in numbers with last digit uncertain and rest all are certain digits i.e. all the digits of datum including the uncertain one , are called significant figures. (C) Rules for determination of significant figure: (i) All non zero digits are significant. Example : 3.14 has three significant figures (ii) The zeros to the right of the decimal point are significant. Example : 3.0 has two significant figures. (iii) The zeros to the left of the first non zero digit in a number are not significant. Example : 0.02 has one significant figure. (iv) The zeros between two non zero digits are also significant. Example : 6.01 has three significant figures. (v) Exponential form : N × 10 n . Where N show the significant figure. Exam

Gold Number (Surface Chemistry )