ਰਸਾਇਣ ਵਿਗਿਆਨ

ਵਿਕਿਪੀਡਿਆ ਤੋਂ

ਨਮੂਨਾ:Portal

ਰਸਾਇਣਿਕ ਵਿਗਿਆਨ (in Greek: χημεία) is  the science of matter that deals with the composition, structure, and  properties of substances and  with the transformations that they undergo. In the study of matter, chemistry also investigates its interactions with energy and  itself (see physics, biology). Because of the diversity of matter, which is  mostly in the form of atoms, chemists often study how atoms of different chemical elements interact to form molecules and  how molecules interact with each other.

ਵਿਸ਼ਾ-ਸੂਚੀ ੧ ਜਾਣ-ਪਛਾਣ ੨ ਰਸਾਇਣਿਕ ਵਿਗਿਆਨ ਵਿੱਚ ਅਧੀਨ-ਵਿਸ਼ੇ ੩ ਮੁੱਢਲੇ ਸਿਧਾਂਤ ੩.੧ ਨਾਂ-ਕਰਨ ਢੰਗ ੩.੨ ਪਰਮਾਣੂ ੩.੩ ਤੱਤ ੩.੪ ਯੋਗਿਕ ੩.੫ ਅਣੂ ੩.੬ Ions ੩.੭ ਬੰਧਨ ੩.੮ ਮਾਦੇ ਦੀ ਹਾਲਤ ੩.੯ ਰਸਾਇਣਿਕ ਕਿਰਿਆਵਾਂ ੩.੧੦ Quantum chemistry ੩.੧੧ ਨਿਯਮ ੪ ਰਸਾਇਣ ਵਿਗਿਆਨ ਦਾ ਇਤਹਾਸ ੪.੧ Etymology ੫ ਇਹ ਵੀ ਵੇਖੋ ੬ ਬਾਹਰੀ ਸਬੰਧ ੭ ਹੋਰ ਜਾਣਕਾਰੀ

[ਬਦਲੋ] ਜਾਣ-ਪਛਾਣ

Chemistry is  a large field encompassing many subdisciplines that often overlap with significant portions of other sciences. The fundamental component of chemistry is  that it  involves matter in some way (this explains its broad reach). it  may involve the interaction of matter with non-material phenomenon, such as energy for example. more  central to chemistry is  the interaction of matter with matter such as in the classic chemical reaction where chemical bonds are  broken and  made, forming new molecules.

Matter, such as the chair you are  sitting in or  the air you breathe, is  known today to consist of molecules. Each molecule consists of small bits of matter known as atoms that are  connected together through chemical bonds. Each atom consists of smaller bits of matter known as subatomic particles. The structure of the world we commonly experience and  the properties of the matter we commonly interact with are  determined by the nature of this matter on the chemical level. Steel is  hard because of how the atoms are  bound together. Wood will burn because it  can react with oxygen in a chemical reaction. Water is  a liquid at room temperature because of how each molecule of water interacts with its neighbors. In fact, you are  a thinking, sentient being because of an  on-going series of chemical reactions and  other chemical interactions. You can see this text because of how light interacts with molecules called proteins in the back of your eye.

Chemistry is  often called the central science because it  is what connects most of the other sciences together. Chemistry is  in some ways physics on a larger scale and  in some ways is  biology or  geology on a smaller scale. Chemistry is  used to understand and  make better materials for engineering. it  is used to understand the chemical mechanisms of disease as well as to create pharmaceuticals to treat disease. Chemistry is  somehow involved in almost every science, every technology and  every "thing".

With such a large area of study, it  is impossible to know everything about chemistry and  very difficult to summarize the field concisely. Even the most knowledgable, experienced chemist only knows a very narrow area of chemistry better than others. Of course, most chemists have  a broad general knowledge of many areas of chemistry as well. Chemistry is  divided into many areas of study called subdisciplines in which chemists specialize. The chemistry taught at the high school or  early college level is  often called "general chemistry" and  is intended to be an  introduction to a wide variety of fundamental concepts and  to give the student the tools to continue on to more  advanced subjects. Many concepts presented at this level are  often incomplete and  technically inaccurate yet of extraordinary utility. Chemists regularly use these simple, elegant tools and  explanations in their work when they suffice because the best solution possible is  often so overwhelmingly difficult and  the true solution is  usually unobtainable.

Presented below are  summaries and  links to other articles that contain knowledge on a wide variey of subdisciplines, techniques, theories and  tools used in chemistry. Although a good knowledge of chemistry only comes with many years of study, you may find small bits of knowledge here that may be helpful.

[ਬਦਲੋ] ਰਸਾਇਣਿਕ ਵਿਗਿਆਨ ਵਿੱਚ ਅਧੀਨ-ਵਿਸ਼ੇ

Chemistry typically is  divided into several major sub-disciplines. There are  also several main cross-disciplinary and  more specialized fields of chemistry.

Analytical chemistry 

Analytical chemistry is  the analysis of material samples to gain an  understanding of their chemical composition and  structure.

Biochemistry 

Biochemistry is  the study of the chemicals, chemical reactions and  chemical interactions that take place in living organisms.

Inorganic chemistry 

Inorganic chemistry is  the study of the properties and  reactions of inorganic compounds. The distinction between organic and  inorganic disciplines is  not absolute and  there is  much overlap, most importantly in the sub-discipline of organometallic chemistry.

Organic chemistry 

Organic chemistry is  the study of the structure, properties, composition, mechanisms, and  reactions of organic compounds.

Physical chemistry 

Physical chemistry is  the study of the physical basis of chemical systems and  processes. In particular, the energetic description of diverse chemical transformations are  of interest to physical chemists. Important areas of study include chemical thermodynamics, chemical kinetics, statistical mechanics, and  spectroscopy. Physical chemistry has large overlap with molecular physics.

Theoretical chemistry 

Theoretical chemistry is  the study of chemistry via theoretical reasoning (usually within mathematics or  physics). In particular the application of quantum mechanics to chemistry is  called quantum chemistry. Since the end of the second world war, the development of computers has allowed a systematic development of computational chemistry, which is  the art of developing and  applying computer programs for solving chemical problems. Theoretical chemistry has large overlap with molecular physics.

ਹੋਰ ਖੇਤਰ 

Astrochemistry, Atmospheric chemistry, Chemical Engineering, Electrochemistry, Environmental chemistry, Geochemistry, History of chemistry, Materials science, Medicinal chemistry, Molecular Biology, Molecular genetics, Nuclear chemistry, Organometallic chemistry, Petrochemistry, Pharmacology, Photochemistry, Phytochemistry, Polymer chemistry, Supramolecular chemistry, Surface chemistry, and  Thermochemistry.

[ਬਦਲੋ] ਮੁੱਢਲੇ ਸਿਧਾਂਤ

[ਬਦਲੋ] ਨਾਂ-ਕਰਨ ਢੰਗ

Nomenclature refers to the system for naming chemical compounds. There are  well-defined systems in place for naming chemical species. Organic compounds are  named according to the organic nomenclature system. Inorganic compounds are  named according to the inorganic nomenclature system.

ਵੇਖੋ: IUPAC nomenclature

[ਬਦਲੋ] ਪਰਮਾਣੂ

ਮੁੱਖ ਲੇਖ: ਪਰਮਾਣੂ.

An atom is  a collection of matter consisting of a positively charged core (the nucleus) which contains protons and  neutrons, and  which maintains a number of electrons to balance the positive charge in the nucleus.

[ਬਦਲੋ] ਤੱਤ

ਮੁੱਖ ਲੇਖ: ਰਸਾਇਣਿਕ ਤੱਤ

An element is  a class of atoms which have  the same number of protons in the nucleus. This number is  known as the atomic number of the element. For example, all atoms with 6 protons in their nuclei are  atoms of the chemical element carbon, and  all atoms with 92 protons in their nuclei are  atoms of the element uranium.

The most convenient presentation of the elements is  in the periodic table, which groups elements with similar chemical properties together. Lists of the elements by name, by symbol, and  by atomic number are  also available.

Because the number of protons in the nucleus dictates the number of electrons surrounding the nucleus and  their properties, and  because the electrons are  the outermost component of atoms (the component which presents a surface to the rest of the universe), the identity of an  element dictates the interactions, or  chemical transformations, in which it  can participate. There may, however, be subtle changes in chemical properties brought about by the number of neutrons in the nucleus of otherwise "same" elements.

See also: isotope

[ਬਦਲੋ] ਯੋਗਿਕ

ਮੁੱਖ ਲੇਖ: ਰਸਾਇਣਿਕ ਯੋਗਿਕ

A compound is  a substance with a fixed ratio of elements which determines the composition, and  a particular organisation which determines chemical properties. For example, water is  a compound containing hydrogen and  oxygen in the ratio of two to one. Compounds are  formed and  interconverted by chemical reactions.

[ਬਦਲੋ] ਅਣੂ

ਮੁੱਖ ਲੇਖ: ਅਣੂ

ਇੱਕ ਅਣੂ ਇੱਕ ਸ਼ੁੱਧ ਯੋਗਿਕ ਦਾ ਨਾ-ਟੁੱਟਣਯੋਗ ਰੂਪ ਹੈ, ਜੋ ਕਿ ਵਿੱਲਖਣ ਕਿਸਮ ਦੇ ਗੁਣ ਰੱਖਦਾ ਹੈ। ਅਣੂ ਵਿੱਚ ਦੋ ਜਾਂ ਵੱਧ ਪਰਮਾਣੂ ਬੰਧਨ ਰਾਹੀਂ ਆਪਸ ਵਿੱਚ ਜੁੜੇ ਹੁੰਦੇ ਹਨ।

[ਬਦਲੋ] Ions

Main article: Ion.

An ion is  a charged species, or  an atom or  a molecule that has lost or  gained an  electron. Positively charged cations (e.g. sodium cation Na⁺) and  negatively charged anions (e.g. chloride Cl^-) build neutral salts (e.g. sodium chloride NaCl). Examples of polyatomic ions that do not split up during acid-base reactions are  hydroxide (OH^-), or  phosphate (PO₄^3-).

[ਬਦਲੋ] ਬੰਧਨ

ਮੁੱਖ ਲੇਖ: ਰਸਾਇਣਿਕ ਬੰਧਨ

A chemical bond is  the force which holds together atoms in molecules or  crystals. In many simple compounds, valence bond theory and  the concept of oxidation number can be used to predict molecular structure and  composition. Similarly, theories from classical physics can be used to predict many ionic structures. With more  complicated compounds, such as metal complexes, valence bond theory fails and  alternative approaches which are  based on quantum chemistry, such as molecular orbital theory, are  necessary.

[ਬਦਲੋ] ਮਾਦੇ ਦੀ ਹਾਲਤ

ਮੁੱਖ ਲੇਖ: Phase (ਮਾਦਾ).

A phase is  a set of states of a chemical system that have  similar bulk structural properties, over a range of conditions, such as pressure or  temperature. Physical properties, such as density and  refractive index tend to fall within values characteristic of the phase. The phase of matter is  defined by the phase transition, which is  when energy put into or  taken out of the system goes into rearranging the structure of the system, instead of changing the bulk conditions.

Sometimes the distinction between phases can be continuous instead of having a discrete boundary, in this case the matter is  considered to be in a supercritical state. When three states meet based on the conditions, it  is known as a triple point and  since this is  invariant, it  is a convenient way to define a set of conditions.

The most familiar examples of phases are  solids, liquids, and  gases. less  familiar phases include plasmas, Bose-Einstein condensates and  fermionic condensates and  the paramagnetic and  ferromagnetic phases of magnetic materials. Even the familiar ice has many different phases, depending on the pressure and  temperature of the system. While most familiar phases deal with three-dimensional systems, it  is also possible to define analogs in two-dimensional systems, which is  getting a lot of attention because of its relevance to biology.

[ਬਦਲੋ] ਰਸਾਇਣਿਕ ਕਿਰਿਆਵਾਂ

ਮੁੱਖ ਲੇਖ: ਰਸਾਇਣਿਕ ਕਿਰਿਆ

Chemical reactions are  transformations in the fine structure of molecules. Such reactions can result in molecules attaching to each other to form larger molecules, molecules breaking apart to form two or  more smaller molecules, or  rearrangement of atoms within or  across molecules. Chemical reactions usually involve the making or  breaking of chemical bonds.

[ਬਦਲੋ] Quantum chemistry

ਮੁੱਖ ਲੇਖ: Quantum chemistry.

Quantum chemistry describes the behavior of matter at the molecular scale. it  is, in principle, possible to describe all chemical systems using this theory. In practice, only the simplest chemical systems may realistically be investigated in purely quantum mechanical terms, and  approximations must be made for most practical purposes (e.g., Hartree-Fock, post Hartree-Fock or  Density functional theory, see computational chemistry for more  details). Hence a detailed understanding of quantum mechanics is  not necessary for most chemistry, as the important implications of the theory (principally the orbital approximation) can be understood and  applied in simpler terms.

[ਬਦਲੋ] ਨਿਯਮ

ਰਸਾਇਣ ਵਿਗਿਆਨ ਦਾ ਸਭ ਤੋਂ ਮੁੱਢਲਾ ਨਿਯਮ ਹੈ ਮਾਦਾ ਸਥਿਰਤਾ ਦਾ ਨਿਯਮ, which states that there is  no detectable change in the quantity of matter during an  ordinary chemical reaction. Modern physics shows that it  is actually energy that is  conserved, and  that energy and  mass are  related; a concept which becomes important in nuclear chemistry. Conservation of energy leads to the important concepts of equilibrium, thermodynamics, and  kinetics.

Further laws of chemistry elaborate on the law of conservation of mass. Joseph Proust's law of definite composition says that pure chemicals are  composed of elements in a definite formulation; we now know that the structural arrangement of these elements is  also important.

ਡਾਲਟਨ ਦਾ ਬਹੁ-ਅਨੁਪਾਤੀ ਨਿਯਮ ਕਹਿੰਦਾ ਹੈ ਕਿ says that these chemicals will present themselves in proportions that are  small whole numbers (i.e. 1:2 O:H in water); although for biomacromolecules and  mineral chemistry the ratios tend to require large numbers.

ਰਸਾਇਣ ਵਿਗਿਆਨ ਦੇ ਮੌਜੂਦਾ ਨਿਯਮ ਊਰਜਾ ਅਤੇ ਸੰਚਾਰ ਵਿੱਚ ਸਬੰਧ ਸਥਾਪਤ ਕਰਦੇ ਹਨ।

• In equilibrium, molecules exist in mixture defined by the transformations possible on the timescale of the equilibrium, and  are in a ratio defined by the intrinsic energy of the molecules—the lower the intrinsic energy, the more  abundant the molecule.
• Transforming one structure to another requires the input of energy to cross an  energy barrier; this can come from the intrinsic energy of the molecules themselves, or  from an  external source which will generally accelerate transformations. The higher the energy barrier, the slower the transformation occurs.
• There is  a hypothetical intermediate, or  transition structure, that corresponds to the structure at the top of the energy barrier. The Hammond-Leffler Postulate states that this structure looks most similar to the product or  starting material which has intrinsic energy closest to that of the energy barrier. Stabilizing this hypothetical intermediate through chemical interaction is  one way to achieve catalysis.
• All chemical processes are  reversible (law of microscopic reversibility) although some processes have  such an  energy bias, they are  essentially irreversible.

[ਬਦਲੋ] ਰਸਾਇਣ ਵਿਗਿਆਨ ਦਾ ਇਤਹਾਸ

• ਅਲਚੀਮੀ(Alchemy)
• ਰਸਾਇਣਿਕ ਤੱਤਾਂ ਦੀ ਖੋਜ
• ਰਸਾਇਣ ਵਿਗਿਆਨ ਦਾ ਇਤਹਾਸ
• ਰਸਾਇਣ ਵਿਗਿਆਨ ਦੇ ਨੋਬਲ ਇਨਾਮ
• ਰਸਾਇਣਿਕ ਤੱਤਾਂ ਦੀ ਖੋਜ ਦੀ ਸਮਾਂ-ਸੀਮਾ

[ਬਦਲੋ] Etymology

ਪੁਰਾਣਾ ਫਰੈਂਚ: alkemie; ਅਰਬ al-kimia: ਤਬਦੀਲੀ ਦੀ ਕਲਾ। ਇਹ ਵੀ ਵੇਖੋ: alchemy

[ਬਦਲੋ] ਇਹ ਵੀ ਵੇਖੋ

• American Chemical Society
• Chemical engineering
• Chemist and  List of chemists
• International Union of Pure and  Applied Chemistry
• List of chemistry topics
• List of compounds
• List of important publications in chemistry
• Periodic table

[ਬਦਲੋ] ਬਾਹਰੀ ਸਬੰਧ

ਨਮੂਨਾ:Wikibooks ਨਮੂਨਾ:Wikibookspar

• Chemical Glossary
• Chemistry Information Database includes basic information and  some toxicity
• IUPAC Nomenclature Home Page, see especially the "Gold Book" containing definitions of standard chemical terms
• Experiments videos and  photos of the techniques and  results
• Material safety data sheets for a variety of chemicals
• Material Safety Data Sheets

[ਬਦਲੋ] ਹੋਰ ਜਾਣਕਾਰੀ

• Chang, Raymond. Chemistry 6th ed. Boston: James M. Smith, 1998. ISBN 0071152210.

ਨਮੂਨਾ:BranchesofChemistry ਨਮੂਨਾ:Natural sciences-footer