Chemisrty » molecules

Elements and Compounds chemical reactivity trend

admin — Wed, 06 Oct 2010 12:02:08 +0000

The halogens are the most reactive elements as a family. Fluorine is the most reactive of all the halogens. The reactivity of the halogens decreases down the group. The high reactivity of halogens is due to the following reasons:

(i) Low dissociation energies

All the halogens have very low dissociation energies. As a result, they can readily dissociate into atoms and react with other substances. As shown below, the dissociation energies of halogens are quite low in comparison to common molecules such as H2, O2 and N2.

(ii) High electron affinity

Halogens have very high electron affinity values and therefore, have very strong tendency to gain an electron. Thus halogens are very reactive elements due to their low dissociation energies and high electron affinity values. As clear from the values of bond dissociation energies, fluorine has the lowest bond dissociation energy. This is due to weak F-F bond because of the repulsion between the non-bonding electrons in the small molecule. Therefore, it is most reactive among the halogens.

Some of the important chemical reactions of halogens are discussed ahead.

Tags: atoms, bond dissociation energies, bond dissociation energy, bonding electrons, chemical reactions, chemical reactivity, electron affinity, elements and compounds, h2 o2, molecule, molecules, reactive elements, reactivity of halogens, repulsion, tendency

Pure and Impure Substances

admin — Fri, 01 Oct 2010 16:00:54 +0000

All matter can be broadly divided into two major groups “Pure” and “Impure”. The term ‘purity’ has quite a different meaning in chemistry than in our day-to-day life. Normally when we refer to pure water, pure milk, etc., what is implied is that the water, milk etc., are free from harmful substances such as bacteria, fungi, viruses, etc. ‘Purity’ in chemistry is entirely of a different nature. When we say a substance is pure, it means that the substance is made of only one type of constituent particles.

Example: In chemical terms, pure water means that it is made of only one type of molecules i.e., H2O.

As mentioned above matter can be divided into pure and impure substances. The pure substances can be further divided into “Elements” and “Compounds”. The impure substances, commonly called “Mixtures” can also be divided further into ‘Homogeneous’ and ‘Heterogeneous’ mixtures.

Tags: bacteria, chemistry, constituent particles, different meaning, elements and compounds, fungi, harmful substances, homogeneous and heterogeneous mixtures, molecules

Repackaging Vitamins: Niacin

admin — Sun, 05 Sep 2010 11:46:39 +0000

Vitamins are small molecules (where small is relative to proteins!) that a living organism cannot synthesize, but are nevertheless required. The word vitamin was coined by a Polish biochemist, Kazimierz Funk by sandwiching together “vital” and “amine”. Not all vitamins turned out to be amines (molecules with an NH2 group in them), however the name stuck.

One such non-amine “vital amine” has the structure shown below. It’s a carboxylic acid (the COOH group). Originally designated as vitamin PP, it is now better known as the third of the B vitamin complex or B3. PP stood for pellagra preventing factor. Pellagra is a nutritional deficiency, once common in Italy, that results in rough skin – pella is Italian for skin.

The original common chemical name for B3 was nicotinic acid. (The synthetic form can be made by oxidizing nicotine with nitric acid.) In the late 1930s, niacin (NIcotinic ACid vitamIN) was adopted as the preferred name, to avoid confusion with nicotine. (I’m unclear why this was undesirable; smoking was pervasive.)

Repackaging scientific terms to make them less frightening for the general public is not just a historical phenomenon. Much more recently the application of NMR (nuclear magnet resonance) to medical imaging saw its “nuclear” dropped (thus forestalling any potential association with nuclear radiation) to become MRI (magnetic resonance imaging). It should be made clear, that like nicotinic acid, which contains no nicotine, NMR does not require nuclear radiation.

Tags: 1930s, amines, b vitamin, biochemist, carboxylic acid, cooh group, living organism, medical imaging, molecules, mri magnetic resonance imaging, nh2 group, nicotine, nmr, nuclear radiation, pella, pellagra, preferred name, rough skin

How do Enzymes Catalyze Reactions

admin — Sat, 28 Aug 2010 03:50:20 +0000

Enzymes

Enzymes are proteins that catalyze, or affect the rate, of chemical reactions without themselves being altered in the process. Specific enzymes catalyze each cellular reaction.
The main role of enzymes during the respiration reaction is to assist in transferring electrons from one molecule to another. These transfers are called “redox” reactions, where the loss of electrons from one molecule (oxidation) must coincide with the addition of electrons to another substance (reduction).

Glycolysis

This first step of the respiration reaction takes place in the cytoplasm, or fluid, of the cell. Glycolysis consists of nine separate chemical reactions, each catalyzed by a specific enzyme.
The key players in glycolysis are the enzyme dehydrodgenase and a coenzyme (non-protein helper) called NAD+. Dehydrodgenase oxidizes glucose by stripping two electrons from it and transferring them to NAD+. In the process glucose is “split” into two molecules of pyruvate, which continue the reaction.

The Citric Acid Cycle

The second step of the respiration reaction takes place inside a cell organelle called the mitochondria, which due to their role in ATP production are called “power factories” for the cell.
Just before the citric acid cycle starts, pyruvate is “groomed” for the reaction by being converted into a high-energy substance called acetyl coenzyme A, or acetyl-CoA.
Specific enzymes located in the mitochondria then power the many reactions that make up the citric acid cycle (also known as the Krebs cycle) by rearranging chemical bonds and participating in more redox reactions.
At the completion of this step, electron carrying molecules leave the citric acid cycle and begin the third step.

Oxidative Phosphorylation

The final step of the respiration reaction, also called the electron transport chain, is where the energy payoff occurs for the cell. During this step oxygen drives a chain of electron movement across the membrane of the mitochondria. This transfer of electrons powers the ability of the enzyme ATP synthase to produce 38 molecules of ATP.

Tags: atp production, catalyze, chemical bonds, chemical reactions, citric acid cycle, cytoplasm, electron movement, electron transport chain, electrons, glucose, high energy, krebs cycle, mitochondria, molecule, molecules, oxidation, oxidative phosphorylation, pyruvate, respiration, role of enzymes

Atoms and Atomic Theory

admin — Wed, 25 Aug 2010 22:47:31 +0000

Chemistry is the study of matter and the interactions between different types of matter and energy. The fundamental building block of matter is the atom. An atom consists of three main parts: protons, neutrons, and electrons. Protons have a positive electrical charge. Neutrons have no electrical charge. Electrons have a negative electrical charge. Protons and neutrons are found together in what is called the nucleus of the atom. Electrons circle around nucleus.

Chemical reactions involve interactions between the electrons of one atom and the electrons of another atom. Atoms which have different amounts of electrons and protons have a positive or negative electrical charge and are called ions. When atoms bond together, they can make larger building blocks of matter called molecules.

Tags: atom, atomic theory, atoms, chemical reactions, chemistry, electrons and protons, electrons protons, matter and energy, molecules, negative electrical charge, nucleus, protons and neutrons, protons neutrons and electrons, types of matter