Molecules

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Molecules

Molecule, a group of two or more atoms that form the smallest identifiable unit into which a pure substance can be divided and still retain the composition and chemical properties of that substance.

The division of a sample of a substance into progressively smaller parts produces no change in either its composition or its chemical properties until parts consisting of single molecules are reached. Further subdivision of the substance leads to still smaller parts that usually differ from the original substance in composition and always differ from it in chemical properties. In this latter stage of fragmentation the chemical Bonds that hold the atoms together in the molecule are broken.

Atoms consist of a single nucleus with a positive charge surrounded by a cloud of negatively charged electrons. When atoms approach one another closely, the electron clouds interact with each other and with the nuclei. If this interaction is such that the total energy of the system is lowered, then the atoms bond together to form a molecule. Thus, from a structural point of view, a molecule consists of an aggregation of atoms held together by valence forces. Diatomic molecules contain two atoms that are chemically bonded. If the two atoms are identical, as in, for example, the Oxygen“>oxygen molecule (O2), they compose a homonuclear diatomic molecule, while if the atoms are different, as in the carbon monoxide molecule (CO), they make up a heteronuclear diatomic molecule. Molecules containing more than two atoms are termed polyatomic molecules, e.g., carbon dioxide (CO2) and water (H2O). Polymer molecules may contain many thousands of component atoms.

Not all substances are made up of distinct molecular units. Sodium chloride (common table salt), for example, consists of sodium ions and chlorine ions arranged in a lattice so that each sodium ion is surrounded by six equidistant chlorine ions and each chlorine ion is surrounded by six equidistant sodium ions. The forces acting between any sodium and any adjacent chlorine ion are equal. Hence, no distinct aggregate identifiable as a molecule of sodium chloride exists. Consequently, in sodium chloride and in all solids of similar type, the concept of the chemical molecule has no significance. Therefore, the formula for such a compound is given as the simplest ratio of the atoms, called a formula unit—in the case of sodium chloride, NaCl.

Molecules are held together by shared electron pairs, or covalent bonds. Such bonds are directional, meaning that the atoms adopt specific positions relative to one another so as to maximize the bond strengths. As a result, each molecule has a definite, fairly rigid structure, or spatial distribution of its atoms. Structural chemistry is concerned with valence, which determines how atoms combine in definite ratios and how this is related to the bond directions and bond lengths. The properties of molecules correlate with their structures; for example, the water molecule is bent structurally and therefore has a dipole moment, whereas the carbon dioxide molecule is linear and has no dipole moment. The elucidation of the manner in which atoms are reorganized in the course of chemical reactions is important. In some molecules the structure may not be rigid; for example, in ethane (H3CCH3) there is virtually free rotation about the carbon-carbon single bond.

The nuclear positions in a molecule are determined either from microwave vibration-rotation spectra or by neutron diffraction. The electron cloud surrounding the nuclei in a molecule can be studied by X-ray diffraction experiments. Further information can be obtained by electron spin resonance or nuclear magnetic resonance techniques. Advances in Microscope“>electron microscopy have enabled visual images of individual molecules and atoms to be produced. Theoretically the molecular structure is determined by solving the quantum mechanical equation for the motion of the electrons in the fieldof the nuclei (called the Schrödinger equation). In a molecular structure the bond lengths and bond angles are those for which the molecular energy is the least. The determination of structures by numerical solution of the Schrödinger equation has become a highly developed process entailing use of computers and supercomputers.

Atoms

Atom, smallest unit into which matter can be divided without the release of electrically charged particles. It also is the smallest unit of matter that has the characteristic properties of a chemical element. As such, the atom is the basic building block of chemistry.

Most of the atom is empty space. The rest consists of a positively charged nucleus of protons and neutrons surrounded by a cloud of negatively charged electrons. The nucleus is small and dense compared with the electrons, which are the lightest charged particles in nature. Electrons are attracted to any positive charge by their electric force; in an atom, electric forces bind the electrons to the nucleus.

Because of the nature of quantum mechanics, no single image has been entirely satisfactory at visualizing the atom’s various characteristics, which thus forces physicists to use complementary pictures of the atom to explain different properties. In some respects, the electrons in an atom behave like particles orbiting the nucleus. In others, the electrons behave like waves frozen in position around the nucleus. Such wave patterns, called orbitals, describe the distribution of individual electrons. The behaviour of an atom is strongly influenced by these orbital properties, and its chemical properties are determined by orbital groupings known as shells.

Most matter consists of an agglomeration of molecules, which can be separated relatively easily. Molecules, in turn, are composed of atoms joined by chemical bonds that are more difficult to break. Each individual atom consists of smaller particles—namely, electrons and nuclei. These particles are electrically charged, and the electric forces on the charge are responsible for holding the atom together. Attempts to separate these smaller constituent particles require ever-increasing amounts of energy and result in the creation of new subatomic particles, many of which are charged.

All atoms are roughly the same size, whether they have 3 or 90 electrons. Approximately 50 million atoms of solid matter lined up in a row would measure 1 cm (0.4 inch). A convenient unit of length for measuring atomic sizes is the angstrom (Å), defined as 10−10 metre. The radius of an atom measures 1–2 Å. Compared with the overall size of the atom, the nucleus is even more minute. It is in the same proportion to the atom as a marble is to a football field. In volume the nucleus takes up only 10−14metres of the space in the atom—i.e., 1 part in 100,000. A convenient unit of length for measuring nuclear sizes is the femtometre (fm), which equals 10−15 metre. The diameter of a nucleus depends on the number of particles it contains and ranges from about 4 fm for a Light“>light nucleus such as carbon to 15 fm for a heavy nucleus such as lead. In spite of the small size of the nucleus, virtually all the mass of the atom is concentrated there. The protons are massive, positively charged particles, whereas the neutrons have no charge and are slightly more massive than the protons. The fact that nuclei can have anywhere from 1 to nearly 300 protons and neutrons accounts for their wide variation in mass. The lightest nucleus, that of hydrogen, is 1,836 times more massive than an electron, while heavy nuclei are nearly 500,000 times more massive.

 


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A molecule is a group of two or more atoms held together by chemical bonds. Molecules are the basic units of many of the substances that make up our world, including water, air, and food. They are also the building blocks of living things.

The structure of a molecule is determined by the way its atoms are arranged. The shape of a molecule can affect its properties, such as its polarity and its ability to bond with other molecules.

Polarity is a measure of how unevenly the electrons in a molecule are shared between the atoms. Molecules that are polar have a positive end and a negative end. This can cause them to be attracted to other molecules, such as water molecules.

The shape of a molecule is determined by the way its atoms are bonded together. The most common shapes of molecules are linear, trigonal planar, tetrahedral, and octahedral.

Molecular orbital theory is a way of describing the bonding in molecules. It uses the idea that electrons can be found in orbitals, which are regions of space around the nucleus where the electrons are most likely to be found.

Bonding in molecules can be covalent, ionic, or metallic. Covalent bonds are formed when atoms share electrons. Ionic bonds are formed when atoms transfer electrons to each other. Metallic bonds are formed when atoms share electrons in a sea of electrons.

Molecular spectroscopy is the study of the interaction of matter with electromagnetic radiation. It can be used to determine the structure of molecules and to study their properties.

Molecular dynamics is a computer simulation technique that is used to study the motion of molecules. It can be used to study the properties of materials and to design new materials.

Molecular modeling is a technique that is used to create a three-dimensional representation of a molecule. It can be used to study the structure of molecules and to predict their properties.

Molecular simulation is a technique that is used to study the behavior of molecules. It can be used to study the properties of materials and to design new materials.

Molecular biology is the study of the structure and function of molecules that make up living things. It includes the study of DNA, RNA, proteins, and other molecules.

Molecular genetics is the study of the genes that control the structure and function of living things. It includes the study of DNA, RNA, and proteins.

Molecular medicine is the study of the use of molecules to treat and prevent disease. It includes the study of drugs, Vaccines, and other therapies.

Molecular pharmacology is the study of the interaction of drugs with molecules in the body. It includes the study of how drugs work and how they can be used to treat disease.

Molecular engineering is the design and construction of molecules with specific properties. It includes the design of drugs, materials, and other products.

Molecular Nanotechnology is the manipulation of individual atoms and molecules to create new materials and devices. It is a promising field with the potential to revolutionize many industries.

Molecular electronics is the study of the use of molecules to create electronic devices. It includes the study of molecular transistors, switches, and other devices.

Molecular computing is the study of the use of molecules to perform computations. It includes the study of molecular logic gates, memories, and other devices.

Molecular Robotics is the study of the design and construction of robots from molecules. It is a promising field with the potential to revolutionize many industries.

1. What is a chemical bond?

A chemical bond is an attraction between atoms that enables the formation of chemical substances that contain two or more atoms. The bond is caused by the electromagnetic force attraction between opposite charges, the electronegativity of atoms, and the orbital overlap between atoms.

2. What are the different types of chemical bonds?

There are three main types of chemical bonds: ionic bonds, covalent bonds, and metallic bonds.

  • Ionic bonds are formed when one atom donates an electron to another atom. The atom that donates the electron becomes a positively charged ion, while the atom that receives the electron becomes a negatively charged ion. The oppositely charged ions are attracted to each other, forming an ionic bond.
  • Covalent bonds are formed when two atoms share electrons. The electrons are shared equally between the two atoms, and the atoms form a covalent bond.
  • Metallic bonds are formed when atoms share electrons in a sea of electrons. The electrons are not bound to any particular atom, but are free to move throughout the Metal.

3. What are the properties of chemical bonds?

The properties of chemical bonds depend on the type of bond. Ionic bonds are typically strong and brittle, while covalent bonds are typically strong and flexible. Metallic bonds are typically ductile and malleable.

4. What are the applications of chemical bonds?

Chemical bonds are essential for the formation of all matter. They are also used in a variety of applications, such as in the production of plastics, pharmaceuticals, and other materials.

5. What are the challenges of chemical bonds?

One challenge of chemical bonds is that they can be difficult to break. This can make it difficult to recycle or reuse materials that contain chemical bonds. Another challenge is that chemical bonds can be harmful to the Environment. For example, the release of greenhouse gases into the Atmosphere can contribute to Climate change.

6. What are the future directions of research on chemical bonds?

One area of future research on chemical bonds is the development of new materials that are stronger and more durable. Another area of research is the development of new methods for breaking chemical bonds. This could be used to recycle or reuse materials that are currently difficult to recycle.

Sure. Here are some MCQs without mentioning the topic Molecules:

  1. Which of the following is not a type of chemical bond?
    (A) Ionic bond
    (B) Covalent bond
    (C) Metallic bond
    (D) Molecular bond

  2. Which of the following is not a property of a molecule?
    (A) Shape
    (B) Size
    (C) Charge
    (D) Mass

  3. Which of the following is not a type of molecule?
    (A) Atom
    (B) Ion
    (C) Molecule
    (D) Compound

  4. Which of the following is not a property of a compound?
    (A) Formula
    (B) Structure
    (C) Melting point
    (D) Boiling point

  5. Which of the following is not a type of Chemical Reaction?
    (A) Synthesis
    (B) Decomposition
    (C) Combustion
    (D) Atomization

  6. Which of the following is not a property of a chemical reaction?
    (A) Rate
    (B) Energy
    (C) Product
    (D) Reactant

  7. Which of the following is not a type of chemical change?
    (A) Physical change
    (B) Chemical change
    (C) Nuclear change
    (D) Biological change

  8. Which of the following is not a property of a chemical change?
    (A) Reversible
    (B) Irreversible
    (C) Exothermic
    (D) Endothermic

  9. Which of the following is not a type of chemical equilibrium?
    (A) Dynamic equilibrium
    (B) Static equilibrium
    (C) Heterogeneous equilibrium
    (D) Homogeneous equilibrium

  10. Which of the following is not a property of a chemical equilibrium?
    (A) Constant
    (B) Variable
    (C) Reversible
    (D) Irreversible