Posts by Jai Ganesh

Jai Ganesh · This is Cool

Solution

Gist

In chemistry, a solution is a homogeneous mixture of two or more substances where one substance (the solute) is dissolved evenly into another (the solvent). This mixture is uniform throughout, meaning the composition is the same everywhere in the solution. Examples include saltwater, sugar dissolved in water, or alloys like steel.

Summary

Solution, in chemistry, is a homogenous mixture of two or more substances in relative amounts that can be varied continuously up to what is called the limit of solubility. The term solution is commonly applied to the liquid state of matter, but solutions of gases and solids are possible. Air, for example, is a solution consisting chiefly of oxygen and nitrogen with trace amounts of several other gases, and brass is a solution composed of copper and zinc.

Life processes depend in large part on solutions. Oxygen from the lungs goes into solution in the blood plasma, unites chemically with the hemoglobin in the red blood cells, and is released to the body tissues. The products of digestion also are carried in solution to the different parts of the body. The ability of liquids to dissolve other fluids or solids has many practical applications. Chemists take advantage of differences in solubility to separate and purify materials and to carry out chemical analysis. Most chemical reactions occur in solution and are influenced by the solubilities of the reagents. Materials for chemical manufacturing equipment are selected to resist the solvent action of their contents.

The liquid in a solution is customarily designated the solvent, and the substance added is called the solute. If both components are liquids, the distinction loses significance; the one present in smaller concentration is likely to be called the solute. The concentration of any component in a solution may be expressed in units of weight or volume or in moles. These may be mixed—e.g., moles per litre and moles per kilogram.

Crystals of some salts contain lattices of ions—i.e., atoms or groups of atoms with alternating positive and negative charges. When such a crystal is to be dissolved, the attraction of the oppositely charged ions, which are largely responsible for cohesion in the crystal, must be overcome by electric charges in the solvent. These may be provided by the ions of a fused salt or by electric dipoles in the molecules of the solvent. Such solvents include water, methyl alcohol, liquid ammonia, and hydrogen fluoride. The ions of the solute, surrounded by dipolar molecules of the solvent, are detached from each other and are free to migrate to charged electrodes. Such a solution can conduct electricity, and the solute is called an electrolyte.

The potential energy of attraction between simple, nonpolar molecules (nonelectrolytes) is of very short range; it decreases approximately as the seventh power of the distance between them. For electrolytes the energy of attraction and repulsion of charged ions drops only as the first power of the distance. Accordingly, their solutions have very different properties from those of nonelectrolytes.

It is generally presumed that all gases are completely miscible (mutually soluble in all proportions), but this is true only at normal pressures. At high pressures, pairs of chemically dissimilar gases may very well exhibit only limited miscibility. Many different metals are miscible in the liquid state, occasionally forming recognizable compounds. Some are sufficiently alike to form solid solutions.

Details

In chemistry, a solution is defined by IUPAC as "A liquid or solid phase containing more than one substance, when for convenience one (or more) substance, which is called the solvent, is treated differently from the other substances, which are called solutes. When, as is often but not necessarily the case, the sum of the mole fractions of solutes is small compared with unity, the solution is called a dilute solution. A superscript attached to the ∞ symbol for a property of a solution denotes the property in the limit of infinite dilution." One parameter of a solution is the concentration, which is a measure of the amount of solute in a given amount of solution or solvent. The term "aqueous solution" is used when one of the solvents is water.

Types

Homogeneous means that the components of the mixture form a single phase. Heterogeneous means that the components of the mixture are of different phase. The properties of the mixture (such as concentration, temperature, and density) can be uniformly distributed through the volume but only in absence of diffusion phenomena or after their completion. Usually, the substance present in the greatest amount is considered the solvent. Solvents can be gases, liquids, or solids. One or more components present in the solution other than the solvent are called solutes. The solution has the same physical state as the solvent.

Gaseous mixtures

If the solvent is a gas, only gases (non-condensable) or vapors (condensable) are dissolved under a given set of conditions. An example of a gaseous solution is air (oxygen and other gases dissolved in nitrogen). Since interactions between gaseous molecules play almost no role, non-condensable gases form rather trivial solutions. In the literature, they are not even classified as solutions, but simply addressed as homogeneous mixtures of gases. The Brownian motion and the permanent molecular agitation of gas molecules guarantee the homogeneity of the gaseous systems. Non-condensable gaseous mixtures (e.g., air/CO2, or air/xenon) do not spontaneously demix, nor sediment, as distinctly stratified and separate gas layers as a function of their relative density. Diffusion forces efficiently counteract gravitation forces under normal conditions prevailing on Earth. The case of condensable vapors is different: once the saturation vapor pressure at a given temperature is reached, vapor excess condenses into the liquid state.

Liquid solutions

Liquids dissolve gases, other liquids, and solids. An example of a dissolved gas is oxygen in water, which allows fish to breathe under water. An examples of a dissolved liquid is ethanol in water, as found in alcoholic beverages. An example of a dissolved solid is sugar water, which contains dissolved sucrose.

Solid solutions

If the solvent is a solid, then gases, liquids, and solids can be dissolved.

Gas in solids:

* Hydrogen dissolves rather well in metals, especially in palladium; this is studied as a means of hydrogen storage.

Liquid in solid:

* Mercury in gold, forming an amalgam
* Water in solid salt or sugar, forming moist solids
* Hexane in paraffin wax
* Polymers containing plasticizers such as phthalate (liquid) in PVC (solid)

Solid in solid:

* Steel, basically a solution of carbon atoms in a crystalline matrix of iron atoms
* Alloys like bronze and many others
* Radium sulfate dissolved in barium sulfate: a true solid solution of Ra in BaSO4.

Solubility

The ability of one compound to dissolve in another compound is called solubility. When a liquid can completely dissolve in another liquid the two liquids are miscible. Two substances that can never mix to form a solution are said to be immiscible.

All solutions have a positive entropy of mixing. The interactions between different molecules or ions may be energetically favored or not. If interactions are unfavorable, then the free energy decreases with increasing solute concentration. At some point, the energy loss outweighs the entropy gain, and no more solute particles can be dissolved; the solution is said to be saturated. However, the point at which a solution can become saturated can change significantly with different environmental factors, such as temperature, pressure, and contamination. For some solute-solvent combinations, a supersaturated solution can be prepared by raising the solubility (for example by increasing the temperature) to dissolve more solute and then lowering it (for example by cooling).

Usually, the greater the temperature of the solvent, the more of a given solid solute it can dissolve. However, most gases and some compounds exhibit solubilities that decrease with increased temperature. Such behavior is a result of an exothermic enthalpy of solution. Some surfactants exhibit this behaviour. The solubility of liquids in liquids is generally less temperature-sensitive than that of solids or gases.

Properties

The physical properties of compounds such as melting point and boiling point change when other compounds are added. Together they are called colligative properties. There are several ways to quantify the amount of one compound dissolved in the other compounds collectively called concentration. Examples include molarity, volume fraction, and mole fraction.

The properties of ideal solutions can be calculated by the linear combination of the properties of its components. If both solute and solvent exist in equal quantities (such as in a 50% ethanol, 50% water solution), the concepts of "solute" and "solvent" become less relevant, but the substance that is more often used as a solvent is normally designated as the solvent (in this example, water).

Additional Information

A solution is a homogeneous mixture of two or more substances. A solution may exist in any phase.

A solution consists of a solute and a solvent. The solute is the substance that is dissolved in the solvent. The amount of solute that can be dissolved in a solvent is called its solubility. For example, in a saline solution, salt is the solute dissolved in water as the solvent.

For solutions with components in the same phase, the substances present in a lower concentration are solutes, while the substance present in the highest abundance is the solvent. Using air as an example, oxygen and carbon dioxide gases are solutes, while nitrogen gas is the solvent.

Note that whether or not components start in different phases, a solution only consists of one phase. For example, sugar is a solid, while water is a liquid, However, a solution of sugar water is liquid only.

Characteristics of a Solution

A chemical solution exhibits several properties:

* A solution consists of a homogeneous mixture.
* A solution is composed of one phase (e.g., solid, liquid, gas).
* Particles in a solution are not visible to the naked eye.
* A solution does not scatter a light beam.
* The components of a solution cannot be separated using simple mechanical filtration.

Solution Examples

Any two substances which can be evenly mixed may form a solution. Even though materials of different phases may combine to form a solution, the end result always exists of a single phase.

An example of a solid solution is brass. An example of a liquid solution is aqueous hydrochloric acid (HCl in water). An example of a gaseous solution is air.

Solution Type : Example

gas-gas : air
gas-liquid : carbon dioxide in soda
gas-solid : hydrogen gas in palladium metal
liquid-liquid : gasoline
solid-liquid : sugar in water
liquid-solid : mercury dental amalgam
solid-solid : sterling silver.

Jai Ganesh · This is Cool

2452) Seebeck Effect

Gist

Seebeck effect, production of an electromotive force (emf) and consequently an electric current in a loop of material consisting of at least two dissimilar conductors when two junctions are maintained at different temperatures. The conductors are commonly metals, though they need not even be solids. The German physicist Thomas Johann Seebeck discovered (1821) the effect. The Seebeck effect is used to measure temperature with great sensitivity and accuracy and to generate electric power for special applications.

Summary

The Seebeck effect is the direct conversion of temperature differences into electrical voltage, generated when two different conductors or semiconductors are joined to form a loop. This phenomenon creates a small voltage, called the Seebeck voltage, which can be used for practical applications like generating electricity from heat using thermoelectric generators or measuring temperature with thermocouples.

The Seebeck effect is the phenomenon where a temperature difference between two different conductors or semiconductors creates an electrical voltage. This direct conversion of thermal energy to electrical energy is the principle behind thermoelectric devices like thermocouples, which use a temperature gradient to generate a measurable voltage.

Details:

Key learnings:

Seebeck Effect Definition: The Seebeck effect is defined as the conversion of temperature differences into electric voltage, enabling various practical applications.
Temperature to Electricity: This effect generates electricity when there is a temperature difference across the junctions of two different materials.
Key Applications: Thermocouples and thermoelectric generators are primary applications, used for temperature measurement and converting waste heat into power.
Material Requirements: Effective materials for the Seebeck effect include metals with low Seebeck coefficients and semiconductors with higher coefficients for better performance.
Advantages and Challenges: While the Seebeck effect is reliable and can harness low-grade heat, finding materials with the right properties remains a significant challenge.

The Seebeck effect is a phenomenon that converts temperature differences into electric voltage and vice versa. It is named after Thomas Johann Seebeck, a German physicist who discovered it in 1821. The Seebeck effect is the basis of thermocouples, thermoelectric generators, and spin caloritronics.

Thomas Seebeck:

What is the Seebeck Effect?

The Seebeck effect is defined as the generation of an electric potential (or voltage) across two different conductors or semiconductors that are connected in a loop and have a temperature difference between their junctions. The voltage is proportional to the temperature difference and depends on the materials used.

For example, a thermocouple is a device that uses the Seebeck effect to measure temperature. It consists of two wires made of different metals (such as copper and iron) that are joined at both ends. One end is exposed to a hot source (such as a flame) and the other end is kept cold (such as in ice water). The temperature difference between the ends creates a voltage across the wires, which can be measured by a voltmeter.

The Seebeck effect also enables the generation of electricity from waste heat. In a thermoelectric generator, multiple thermocouples are linked either in series or parallel. These thermocouples have one side connected to a heat source—like an engine or furnace—and the other to a heat sink, such as air or water. This temperature differential generates a voltage capable of powering electrical devices, such as lights or fans.

How Does the Seebeck Effect Work?

Electrons, which are negatively charged and move freely in conductors and semiconductors, drive the Seebeck effect. When these materials are heated, the electrons gain energy and move from the hot area to the cooler one, generating an electric current as they travel.

However, different materials have different numbers and types of electrons available for conduction. Some materials have more electrons than others, and some have electrons with different spin orientations. Spin is a quantum property of electrons that makes them act like tiny magnets. When two materials with different electron characteristics are joined together, they form an interface where electrons can exchange energy and spin.

The Seebeck effect occurs when two such interfaces are subjected to a temperature difference. The electrons at the hot interface gain more energy and spin from the heat source and transfer them to the electrons at the cold interface through the loop. This creates an imbalance of charge and spin between the interfaces, resulting in an electric potential and a magnetic field. The electric potential drives an electric current through the loop, while the magnetic field deflects a compass needle placed near it.

What are the Applications of the Seebeck Effect?

The Seebeck effect has many applications in science, engineering, and technology. Some of them are:

* Thermocouples: These are devices that use the Seebeck effect to measure temperature with high accuracy and sensitivity. They are widely used in industries, laboratories, and households for various purposes, such as controlling ovens, monitoring engines, measuring body temperature, etc.
* Thermoelectric generators: These are devices that use the Seebeck effect to convert waste heat into electricity for special applications, such as powering spacecraft, remote sensors, medical implants, etc.
* Spin caloritronics: This is a branch of physics that studies how heat and spin interact in magnetic materials. The Seebeck effect plays an important role in this field, as it can create spin currents and voltages from temperature gradients. This can lead to novel devices for information processing and storage, such as spin batteries, spin transistors, spin valves, etc.

What are the Advantages and Limitations of the Seebeck Effect?

The Seebeck effect has some advantages and limitations that affect its performance and efficiency. Some of them are:

Advantages: The Seebeck effect is simple, reliable, and versatile. It does not require any moving parts or external power sources. It can operate over a wide range of temperatures and materials. It can generate electricity from low-grade heat sources that would otherwise be wasted.

Limitations: The Seebeck effect is limited by the availability and compatibility of materials. It requires materials with high electrical conductivity and low thermal conductivity to achieve high voltage and low heat loss. It also requires materials with different Seebeck coefficients to create a voltage difference. The Seebeck coefficient is a property that measures how much voltage is generated per unit temperature difference for a given material. The Seebeck coefficient depends on the type and concentration of charge carriers, their energy levels, and their interactions with the lattice. The Seebeck coefficient can vary with temperature, composition, and magnetic field. Finding materials with high and stable Seebeck coefficients is a challenge for thermoelectric applications.

What are the Types of Materials Used for the Seebeck Effect?

The materials used for the Seebeck effect can be classified into three categories: metals, semiconductors, and superconductors.

* Metals: Metals are good conductors of both electricity and heat. They have low Seebeck coefficients and high thermal conductivity, which makes them inefficient for thermoelectric applications. However, metals are easy to fabricate and connect, and they have high mechanical strength and stability. Metals are commonly used for thermocouples, where accuracy and durability are more important than efficiency. Some examples of metal pairs used for thermocouples are copper-constantan, iron-constantan, chromel-alumel, etc.
* Semiconductors: Semiconductors are materials that have an intermediate electrical conductivity that can be controlled by doping or applying an electric field. They have higher Seebeck coefficients and lower thermal conductivity than metals, which makes them more suitable for thermoelectric applications. However, semiconductors are more difficult to fabricate and connect, and they have lower mechanical strength and stability than metals. Semiconductors are commonly used for thermoelectric generators and coolers, where efficiency and performance are more important than accuracy and durability. Some examples of semiconductor pairs used for thermoelectric devices are bismuth telluride-antimony telluride, lead telluride-silicon germanium, etc.
* Superconductors: Superconductors are materials that have zero electrical resistance below a critical temperature. They have very high Seebeck coefficients and very low thermal conductivity, which makes them ideal for thermoelectric applications. However, superconductors are very rare and expensive, and they require very low temperatures to operate, which limits their practical use. Superconductors are mainly used for research purposes, such as studying the spin Seebeck effect, which is a phenomenon that involves the generation of a spin voltage from a temperature gradient in a magnetic material.

Conclusion

The Seebeck effect, which transforms temperature differences into electrical voltage, plays a crucial role in devices like thermocouples and thermoelectric generators. Its efficiency hinges on the materials used—specifically their conductivity and Seebeck coefficients. Despite challenges in material selection, its potential in various fields remains substantial.

Additional Information

The Seebeck effect is a phenomenon in which a temperature difference between two dissimilar electrical conductors or semiconductors produces a voltage difference between the two substances.

When heat is applied to one of the two conductors or semiconductors, heated electrons flow toward the cooler conductor or semiconductor. If the pair is connected through an electrical circuit, direct current (DC) flows through that circuit.

Seebeck effect: Key findings

The Seebeck effect refers to the buildup of electric potential which happens when there is a temperature gradient between different electrical conductors or semiconductors.

Here are some key findings of this phenomenon:

* The voltages produced by the Seebeck effect are small, usually only a few microvolts (millionths of a volt) per kelvin of temperature difference at the junction between the conductors or semiconductors.
* If the temperature difference is large enough, some Seebeck-effect devices can produce a few millivolts (thousandths of a volt).
* Numerous such devices can be connected in series to increase the output voltage or in parallel to increase the maximum deliverable current.
* Large arrays of Seebeck-effect devices can provide useful, small-scale electrical power if a large temperature difference is maintained across the junctions.

Seebeck effect: Explanation

In 1821, German physicist Thomas Seebeck discovered that when two wires made from dissimilar metals are joined at two ends to form a loop, and if the two junctions are maintained at different temperatures, a voltage develops in the circuit. This phenomenon is therefore named after him.

When heat is applied to one of the two conductors or semiconductors, that metal heats up. Consequently, the valence electrons present in this metal flow toward the cooler metal. This happens because electrons move to where energy (in this case, heat) is lower. If the metals are connected through an electrical circuit, direct current flows through the circuit.

However, this voltage is just a few microvolts per kelvin temperature difference. Thermal energy is continuously transferred from the warmer metal to the cooler metal until eventually, temperature equilibrium is obtained.

The Seebeck effect and its resultant thermoelectric effect is a reversible process. If the hot and cold junctions are interchanged, valence electrons will flow in the other direction, and also change the direction of the DC current.

Seebeck effect and thermocouples

The pair of metal wires forming the electrical circuit is known as a thermocouple. On a larger scale and due to the Seebeck effect, thermocouples are used to approximately measure temperature differences. They are also used to actuate electronic switches that can turn large systems on and off, a capability that is employed in thermoelectric cooling technology.

Seebeck used copper and bismuth in his experiment. Other common thermocouple metal combinations that are used today include the following:

* constantan and copper
* constantan and iron
* constantan and chromel
* constantan and alumel

Applications of Seebeck effect

There are many applications of the Seebeck effect. In addition to its use in thermocouples to measure temperature differences, the phenomenon is also used in the following ways:

* in thermopiles (that is, in a setting where a number of thermocouples are connected in series);
* in thermoelectric generators that function as heat engines;
* in power plants to convert waste heat into (extra) power;
* in automobiles as automotive thermoelectric generators, to increase fuel efficiency;
* in high-frequency electrical power sensors;
* to verify material degradation and radiation level, and to perform strength testing of radioactive materials (which vary with temperature over a given time period); and
* to actuate security alarms or switches.

Spin Seebeck effect

In 2008, physicists discovered the Spin Seebeck effect (SSE). This effect refers to the generation of a spin voltage caused by a temperature gradient in a ferromagnet. This gradient enables the thermal injection of spin currents from the ferromagnet into a nonmagnetic metal. This injection happens over a macroscopic scale of several millimeters.

SSE is seen when heat is applied to a magnetized metal. As a result, electrons rearrange themselves according to their spin. Unlike ordinary electron movement, this rearrangement does not create heat as a waste product.

The effect could lead to the development of smaller, faster and more energy-efficient microchips or switches, as well as spintronics devices.

Seebeck effect vs. Peltier effect

In 1834, Jean Peltier, a French watchmaker, discovered another second thermoelectric effect that was later named the Peltier effect. Peltier observed that when a current flows through a circuit containing a junction of two dissimilar metals -- similar to the setup in the Seebeck effect -- heat is either absorbed or liberated at the junction. This absorption or liberation depends on the pair of metals used and the direction of the current.

The Seebeck effect and Peltier effect both involve circuits made from dissimilar metals, as well as heat and electricity. Both are also reversible processes. But despite these similarities, there are some differences between these effects as well.

The Seebeck effect occurs when the two ends of a thermocouple are at different temperatures, which results in electricity flowing from the hot metal to the cold metal.

In the Peltier effect, a temperature difference is created between the junctions when electrical current flows across the terminals. In a copper-constantan thermocouple in which the current at the junction is flowing from copper (+) to constantan (-), heat will be absorbed. But if the direction of the current is reversed -- i.e., from constantan (-) to copper (+) -- it will result in heat liberation.

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Jai Ganesh · Science HQ

Metalloid

Gist

A metalloid is a chemical element that has properties intermediate between those of metals and nonmetals, and is also known as a semimetal. These elements are often semiconductors and have a metallic luster but are brittle. Common metalloids include boron, silicon, germanium, antimony, and tellurium.

A metalloid is an element that possesses a preponderance of properties in between, or that are a mixture of, those of metals and nonmetals, and which is therefore hard to classify as either a metal or a nonmetal.

Metalloids are solids that have both metallic and nonmetallic characteristics, such as a shiny, brittle appearance and intermediate electrical conductivity. They are semiconductors, meaning their conductivity falls between that of a metal and a nonmetal. Chemically, they often behave as nonmetals, have intermediate electronegativity and ionization energy, and can form alloys with metals.

Summary

The word metalloid comes from the Latin metallum ("metal") and the Greek oeidḗs ("resembling in form or appearance"). However, there is no standard definition of a metalloid and no complete agreement on which elements are metalloids. Despite the lack of specificity, the term remains in use in the literature.

The six commonly recognised metalloids are boron, silicon, germanium, As, antimony and tellurium. Five elements are less frequently so classified: carbon, aluminium, selenium, polonium and astatine. On a standard periodic table, all eleven elements are in a diagonal region of the p-block extending from boron at the upper left to astatine at lower right. Some periodic tables include a dividing line between metals and nonmetals, and the metalloids may be found close to this line.

Typical metalloids have a metallic appearance, may be brittle and are only fair conductors of electricity. They can form alloys with metals, and many of their other physical properties and chemical properties are intermediate between those of metallic and nonmetallic elements. They and their compounds are used in alloys, biological agents, catalysts, flame retardants, glasses, optical storage and optoelectronics, pyrotechnics, semiconductors, and electronics.

The term metalloid originally referred to nonmetals. Its more recent meaning, as a category of elements with intermediate or hybrid properties, became widespread in 1940–1960. Metalloids are sometimes called semimetals, a practice that has been discouraged, as the term semimetal has a more common usage as a specific kind of electronic band structure of a substance. In this context, only As and Sb are semimetals, and commonly recognised as metalloids.

Details

A metalloid is a chemical element with properties that fall between those of metals and nonmetals. The term typically refers to a group of between six and eight elements—boron, silicon, Ge, As, Sb, tellurium, and possibly, polonium and astatine—found near the center of the P-block or main block of the periodic table. These elements are classified as metalloids because they share certain physical characteristics with metals, such as luster or moderate conductivity, while they exhibit chemical behavior similar to nonmetals—often forming covalent bonds and acidic oxides.

Properties:

Physical properties

* Appearance: They exhibit a metallic luster, giving them a shiny appearance. However, like nonmetals, they are brittle and can shatter under stress.
* Electrical conductivity: They generally act as semiconductors, meaning that they can conduct electricity under certain conditions—this property makes them essential in electronic and photovoltaic devices.
* Thermal conductivity: Their ability to conduct heat falls between that of metals and nonmetals; they are better thermal conductors than nonmetals but not as efficient as metals.
* Density and melting and boiling points: Metalloids usually have densities and melting and boiling points that are intermediate between those of metals and nonmetals, contributing to their classification as a distinct group.
* Allotropy: Metalloids exist in allotropes (multiple structural forms), such as silicon, which appears as amorphous silicon, a brown powder, and crystalline silicon, which has a metallic luster and gray color.

Chemical properties

* Oxidation states: Each metalloid can exhibit more than one oxidation state, which allows these elements to form a wide range of chemical compounds.
* Electronegativity: Metalloids have electronegativity values that fall between those of metals and nonmetals. Metals are generally less electronegative and tend to form ionic compounds, whereas nonmetals are more electronegative and tend to form covalent bonds. Because metalloids sit in the intermediate range, they can form either ionic or covalent bonds, depending on the element with which they react.
* Acid-base behavior: Metals generally react with acids and nonmetals with bases. Metalloids are often amphoteric, meaning that they can react with both acids and bases.

Uses

Metalloids are used in several industries. In electronics silicon and germanium are used as semiconductors in devices such as computer chips, solar cells, and transistors. In glass and ceramics, boron and silicon improve strength and resistance to thermal shock. Borosilicate glass, which includes boron, is used in laboratory equipment and cookware.

Metalloids contribute to alloy production. Silicon is added to aluminum for better casting properties, while boron strengthens steel. Sb and As are used in lead alloys for batteries, bullets, and solders. Antimony compounds also serve as flame retardants.

Additional Information

Some elements are “none of the above.” They don’t fit neatly into the categories of metal or non-metal because of their characteristics. A metalloid is an element that has properties that are intermediate between those of metals and nonmetals. Metalloids can also be called semimetals. On the periodic table, the elements colored yellow, which generally border the stair-step line, are considered to be metalloids. Notice that aluminum borders the line, but it is considered to be a metal since all of its properties are like those of metals.

Examples of Metalloids

Silicon is a typical metalloid. It has luster like a metal, but is brittle like a nonmetal. Silicon is used extensively in computer chips and other electronics because its electrical conductivity is in between that of a metal and a nonmetal.

Boron is a versatile element that can be incorporated into a number of compounds. Borosilicate glass is extremely resistance to thermal shock. Extreme changes in the temperature of objects containing borosilicates will not create any damage to the material, unlike other glass compositions, which would crack or shatter. Because of their strength, boron filaments are used as light, high-strength materials for airplanes, golf clubs, and fishing rods. Sodium tetraborate is widely used in fiberglass as insulation and also is employed in many detergents and cleaners.

Antimony is a brittle, bluish-white metallic material that is a poor conductor of electricity. Used with lead, antimony increases the hardness and strength of the mixture. This material plays an important role in the fabrication of electronic and semiconductor devices. About half of the antimony used industrially is employed in the production of batteries, bullets, and alloys.

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Jai Ganesh · Exercises

Hi,

2659.

Jai Ganesh · Science HQ

Nonmetal

Gist

A nonmetal is a chemical element that lacks the properties of a metal, such as being a poor conductor of heat and electricity and being brittle when solid. Nonmetals can be gases (like oxygen and helium), a liquid (like bromine), or solids (like carbon and sulfur). They tend to have high electronegativity, meaning they attract electrons in chemical reactions.

The 22 nonmetals are hydrogen, helium, carbon, nitrogen, oxygen, fluorine, neon, phosphorus, sulfur, chlorine, argon, selenium, bromine, krypton, iodine, xenon, astatine, radon, tennessine, oganesson, silicon, and boron. Note that silicon and boron are sometimes categorized differently, and the exact classification of the newest elements can vary, but these 22 are commonly listed as nonmetals.

Summary

A nonmetal, in physics, is a substance having a finite activation energy (band gap) for electron conduction. This means that nonmetals display low (insulators) to moderate (semiconductors) bulk electrical conductivities, which increase with increasing temperature, and are subject to dielectric breakdown at high voltages and temperatures. Like metals, nonmetals may occur in the solid, liquid, or gaseous state. However, unlike metals, nonmetals display a wide range of both mechanical and optical properties, ranging from brittle to plastic and from transparent to opaque.

From a chemical point of view, nonmetals may be divided into two classes: 1) covalent materials, which contain atoms having small sizes, high electronegativities, low valence vacancy to electron ratios, and a pronounced tendency to form negative ions in chemical reactions and negative oxidation states in their compounds; 2) ionic materials, which contain both small and large atoms. Ions may be formed by adding electrons to (small, electronegative atoms) or by extracting electrons from (large, electropositive) atoms. In ionic materials, nonmetals exist either as monatomic anions (e. g., F-in NaF) or as constituents of polyatomic anions (e.g., N and O in the NO3-`s in NaNO3). When in the form of simple elemental substances, about 25 or 22% of the known elements form nonmetals at normal temperatures and pressures, including all of the elements in the S-block of the periodic table and approximately 58% of those in the P-block.

Details

In the context of the periodic table, a nonmetal is a chemical element that mostly lacks distinctive metallic properties. They range from colorless gases like hydrogen to shiny crystals like iodine. Physically, they are usually lighter (less dense) than elements that form metals and are often poor conductors of heat and electricity. Chemically, nonmetals have relatively high electronegativity or usually attract electrons in a chemical bond with another element, and their oxides tend to be acidic.

Seventeen elements are widely recognized as nonmetals. Additionally, some or all of six borderline elements (metalloids) are sometimes counted as nonmetals.

The two lightest nonmetals, hydrogen and helium, together account for about 98% of the mass of the observable universe. Five nonmetallic elements—hydrogen, carbon, nitrogen, oxygen, and silicon—form the bulk of Earth's atmosphere, biosphere, crust and oceans, although metallic elements are believed to be slightly more than half of the overall composition of the Earth.

Chemical compounds and alloys involving multiple elements including nonmetals are widespread. Industrial uses of nonmetals as the dominant component include in electronics, combustion, lubrication and machining.

Most nonmetallic elements were identified in the 18th and 19th centuries. While a distinction between metals and other minerals had existed since antiquity, a classification of chemical elements as metallic or nonmetallic emerged only in the late 18th century. Since then about twenty properties have been suggested as criteria for distinguishing nonmetals from metals. In contemporary research usage it is common to use a distinction between metal and not-a-metal based upon the electronic structure of the solids; the elements carbon, As and Sb are then semimetals, a subclass of metals. The rest of the nonmetallic elements are insulators, some of which such as silicon and germanium can readily accommodate dopants that change the electrical conductivity leading to semiconducting behavior.

Additional Information

The non-metals are elements on the right of the periodic table. Non-metals can be gases, liquids or solids. Non-metals are dull in colour, not shiny like metals. You can't hammer or shape a non-metal; it will just shatter if you hit it. Sulphur is an example of a non-metal. It's yellow and shatters if you hit it with a hammer. Non-metals don't conduct electricity well: they are insulators. There is one exception: graphite is a non-metal which can conduct electricity.

Oxygen, carbon, sulfur and chlorine are examples of non-metal elements.

Non-metals have properties in common with each other. For example, they are often:

* Poor conductors of heat and electricity
* Dull in their appearance
* Weak and brittle

Some other common properties of non-metals are:

* Generally low melting and boiling points, meaning they are gases and liquids at room temperature
* Not sonorous
* Diamond is a form of carbon. Carbon is a non-metal. In the form of diamond it has a high melting point and is shiny.

Some non-metals do not have all of these common properties.

For example, carbon has two main forms - graphite found in pencils, and diamond. Both graphite and diamond have very high melting points and are shiny.

Graphite conducts electricity, which is not typical of non-metals. However graphite is also brittle which is a typical property of non-metals.

Jai Ganesh · Exercises

Hi,

Partially correct. Well done!

2658.

Jai Ganesh · Dark Discussions at Cafe Infinity

Collaborate Quotes

1. Software innovation, like almost every other kind of innovation, requires the ability to collaborate and share ideas with other people, and to sit down and talk with customers and get their feedback and understand their needs. - Bill Gates

2. When you know people are really at peace with who they are and what they do, they collaborate and want to help you to improve. - Javier Bardem

3. I'm one that likes to collaborate. - Christina Aguilera

4. I like to collaborate on my music. The creative process is fun, and you get a lot of ideas from having discussions about it. Ultimately, the final decision is mine. - Janet Jackson.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#10679. What does the term in Geography Colony mean?

#10680. What does the term in Geography Colluvium mean?

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#5875. What does the noun origami mean?

#5876. What does the verb (used without object) originate mean?

Jai Ganesh · Jai Ganesh's Puzzles

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#2532. What does the medical term Brachycephaly mean?

Jai Ganesh · Jokes

Q: What do you call dancing candy?
A: Sour cabbage patch kids.
* * *
Q: Why did the grocery store sell green and purple cabbage?
A: Cause two heads are better than one.
* * *
Q: What do you call a man who gives a cabbage a job?
A: A Head hunter.
* * *
Knock, knock!
Who’s there?
Cabbage.
Cabbage who?
What, you expect a cabbage to have a last name or what?
* * *

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#9812.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#6306.

Jai Ganesh · Exercises

Hi,

2657.

Jai Ganesh · This is Cool

Nuclear Power

Gist

Nuclear power is the use of nuclear reactions to produce electricity. Nuclear power can be obtained from nuclear fission, nuclear decay and nuclear fusion reactions. Presently, the vast majority of electricity from nuclear power is produced by nuclear fission of uranium and plutonium in nuclear power plants.

Nuclear power is generated through a process called nuclear fission, where the heat produced is used to create steam that spins turbines to generate electricity. First, neutrons split uranium atoms in a reactor's core, releasing more neutrons and heat. This heat boils water into steam, which then turns a turbine connected to an electric generator.

Summary

Nuclear power is electricity generated by power plants that derive their heat from fission in a nuclear reactor. Except for the reactor, which plays the role of a boiler in a fossil-fuel power plant, a nuclear power plant is similar to a large coal-fired power plant, with pumps, valves, steam generators, turbines, electric generators, condensers, and associated equipment.

World nuclear power

Nuclear power provides almost 15 percent of the world’s electricity. The first nuclear power plants, which were small demonstration facilities, were built in the 1960s. These prototypes provided “proof-of-concept” and laid the groundwork for the development of the higher-power reactors that followed.

The nuclear power industry went through a period of remarkable growth until about 1990, when the portion of electricity generated by nuclear power reached a high of 17 percent. That percentage remained stable through the 1990s and began to decline slowly around the turn of the 21st century, primarily because of the fact that total electricity generation grew faster than electricity from nuclear power while other sources of energy (particularly coal and natural gas) were able to grow more quickly to meet the rising demand. This trend appears likely to continue well into the 21st century. The Energy Information Administration (EIA), a statistical arm of the U.S. Department of Energy, has projected that world electricity generation between 2005 and 2035 will roughly double (from more than 15,000 terawatt-hours to 35,000 terawatt-hours) and that generation from all energy sources except petroleum will continue to grow.

In 2012 more than 400 nuclear reactors were in operation in 30 countries around the world, and more than 60 were under construction. The United States has the largest nuclear power industry, with more than 100 reactors; it is followed by France, which has more than 50. Of the top 15 electricity-producing countries in the world, all but two, Italy and Australia, utilize nuclear power to generate some of their electricity. The overwhelming majority of nuclear reactor generating capacity is concentrated in North America, Europe, and Asia. The early period of the nuclear power industry was dominated by North America (the United States and Canada), but in the 1980s that lead was overtaken by Europe. The EIA projects that Asia will have the largest nuclear capacity by 2035, mainly because of an ambitious building program in China.

A typical nuclear power plant has a generating capacity of approximately one gigawatt (GW; one billion watts) of electricity. At this capacity, a power plant that operates about 90 percent of the time (the U.S. industry average) will generate about eight terawatt-hours of electricity per year. The predominant types of power reactors are pressurized water reactors (PWRs) and boiling water reactors (BWRs), both of which are categorized as light water reactors (LWRs) because they use ordinary (light) water as a moderator and coolant. LWRs make up more than 80 percent of the world’s nuclear reactors, and more than three-quarters of the LWRs are PWRs.

Details

Nuclear power is the use of nuclear reactions to produce electricity. Nuclear power can be obtained from nuclear fission, nuclear decay and nuclear fusion reactions. Presently, the vast majority of electricity from nuclear power is produced by nuclear fission of uranium and plutonium in nuclear power plants. Nuclear decay processes are used in niche applications such as radioisotope thermoelectric generators in some space probes such as Voyager 2. Reactors producing controlled fusion power have been operated since 1958 but have yet to generate net power and are not expected to be commercially available in the near future.

The first nuclear power plant was built in the 1950s. The global installed nuclear capacity grew to 100 GW in the late 1970s, and then expanded during the 1980s, reaching 300 GW by 1990. The 1979 Three Mile Island accident in the United States and the 1986 Chernobyl disaster in the Soviet Union resulted in increased regulation and public opposition to nuclear power plants. Nuclear power plants supplied 2,602 terawatt hours (TWh) of electricity in 2023, equivalent to about 9% of global electricity generation, and were the second largest low-carbon power source after hydroelectricity. As of November 2025, there are 416 civilian fission reactors in the world, with overall capacity of 376 GW, 63 under construction and 87 planned, with a combined capacity of 66 GW and 84 GW, respectively. The United States has the largest fleet of nuclear reactors, generating almost 800 TWh per year with an average capacity factor of 92%. The average global capacity factor is 89%. Most new reactors under construction are generation III reactors in Asia.

Nuclear power is a safe, sustainable energy source that reduces carbon emissions. This is because nuclear power generation causes one of the lowest levels of fatalities per unit of energy generated compared to other energy sources. "Economists estimate that each nuclear plant built could save more than 800,000 life years." Coal, petroleum, natural gas and hydroelectricity have each caused more fatalities per unit of energy due to air pollution and accidents. Nuclear power plants also emit no greenhouse gases and result in less life-cycle carbon emissions than common sources of renewable energy. The radiological hazards associated with nuclear power are the primary motivations of the anti-nuclear movement, which contends that nuclear power poses threats to people and the environment, citing the potential for accidents like the Fukushima nuclear disaster in Japan in 2011, and is too expensive to deploy when compared to alternative sustainable energy sources.

Additional Information

As the world’s second-largest source of low-emissions electricity after hydropower, nuclear power today produces just under 10% of global electricity supply. Now, fresh momentum around the world has the potential to open a new era for nuclear energy.

Power generation from the global fleet of nearly 420 active nuclear reactors is set to reach a record high in 2025 as Japan restarts production, maintenance works are completed in France, and new reactors begin commercial operations in various markets, including China, Europe, India and Korea. Meanwhile, more than 60 nuclear reactors are currently under construction – representing over 70 gigawatts (GW) of capacity – and governments’ interest in nuclear power is at its highest level since the oil crisis in the 1970s, reflecting efforts to bolster energy security, accelerate clean energy transitions and meet rising demand for electricity. Over 40 countries now have plans to expand its use.

Nuclear power is an important low-emission source of electricity, providing about 10% of global electricity generation. For those countries where it is accepted, it can complement renewables in reducing power sector emissions while also contributing to electricity security as a dispatchable power source. It is also an option for producing low-emission heat and hydrogen.

More efforts are needed to get nuclear power on track with the Net Zero Emissions by 2050 Scenario. Lifetime extensions of existing nuclear power plants are one of the most cost-effective sources of low-emission electricity, and there have been several positive policy developments to take full advantage of these opportunities including in the United States, France and Japan. Additional effort is needed to accelerate new constructions – 8 GW of new nuclear capacity was brought online in 2022, but the Net Zero Scenario calls for over four-times as much annual deployment by 2030. Support for innovation in nuclear power, including small modular reactors, will also help expand the range of low-emission options and widen the path to net zero power.

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Jai Ganesh · Science HQ

Metal

Gist

A metal is a material that is typically hard, strong, shiny, and an excellent conductor of heat and electricity. It can be shaped by hammering (malleability) or drawn into wires (ductility). The term can refer to a chemical element (like iron, copper, or gold), a mixture of elements (like steel), or the music genre, heavy metal.

A metal is a material that is typically hard, shiny, and an excellent conductor of heat and electricity. Common characteristics include being malleable (can be hammered into sheets), ductile (can be drawn into wires), and having a high melting point. Metals are elements found on the periodic table that readily lose electrons to form positive ions. Examples include iron, copper, aluminum, and gold.

Summary

A metal is any of a class of substances characterized by high electrical and thermal conductivity as well as by malleability, ductility, and high reflectivity of light.

Approximately three-quarters of all known chemical elements are metals. The most abundant varieties in the Earth’s crust are aluminum, iron, calcium, sodium, potassium, and magnesium. The vast majority of metals are found in ores (mineral-bearing substances), but a few such as copper, gold, platinum, and silver frequently occur in the free state because they do not readily react with other elements.

Metals are usually crystalline solids. In most cases, they have a relatively simple crystal structure distinguished by a close packing of atoms and a high degree of symmetry. Typically, the atoms of metals contain less than half the full complement of electrons in their outermost shell. Because of this characteristic, metals tend not to form compounds with each other. They do, however, combine more readily with nonmetals (e.g., oxygen and sulfur), which generally have more than half the maximum number of valence electrons. Metals differ widely in their chemical reactivity. The most reactive include lithium, potassium, and radium, whereas those of low reactivity are gold, silver, palladium, and platinum.

The high electrical and thermal conductivities of the simple metals (i.e., the non-transition metals of the periodic table) are best explained by reference to the free-electron theory. According to this concept, the individual atoms in such metals have lost their valence electrons to the entire solid, and these free electrons that give rise to conductivity move as a group throughout the solid. In the case of the more complex metals (i.e., the transition elements), conductivities are better explained by the band theory, which takes into account not only the presence of free electrons but also their interaction with so-called d electrons.

The mechanical properties of metals, such as hardness, ability to resist repeated stressing (fatigue strength), ductility, and malleability, are often attributed to defects or imperfections in their crystal structure. The absence of a layer of atoms in its densely packed structure, for example, enables a metal to deform plastically, and prevents it from being brittle.

Details

A metal is a material that, when polished or fractured, shows a lustrous appearance, and conducts electricity and heat relatively well. These properties are all associated with having electrons available at the Fermi level, as opposed to nonmetallic materials which do not. Metals are typically ductile (can be drawn into a wire) and malleable (can be shaped via hammering or pressing).

A metal may be a chemical element such as iron; an alloy such as stainless steel; or a molecular compound such as polymeric sulfur nitride. The general science of metals is called metallurgy, a subtopic of materials science; aspects of the electronic and thermal properties are also within the scope of condensed matter physics and solid-state chemistry, it is a multidisciplinary topic. In colloquial use materials such as steel alloys are referred to as metals, while others such as polymers, wood or ceramics are nonmetallic materials.

A metal conducts electricity at a temperature of absolute zero, which is a consequence of delocalized states at the Fermi energy. Many elements and compounds become metallic under high pressures, for example, iodine gradually becomes a metal at a pressure of between 40 and 170 thousand times atmospheric pressure.

When discussing the periodic table and some chemical properties, the term metal is often used to denote those elements which in pure form and at standard conditions are metals in the sense of electrical conduction mentioned above. The related term metallic may also be used for types of dopant atoms or alloying elements.

The strength and resilience of some metals has led to their frequent use in, for example, high-rise building and bridge construction, as well as most vehicles, many home appliances, tools, pipes, and railroad tracks. Precious metals were historically used as coinage, but in the modern era, coinage metals have extended to at least 23 of the chemical elements. There is also extensive use of multi-element metals such as titanium nitride or degenerate semiconductors in the semiconductor industry.

The history of refined metals is thought to begin with the use of copper about 11,000 years ago. Gold, silver, iron (as meteoric iron), lead, and brass were likewise in use before the first known appearance of bronze in the fifth millennium BCE. Subsequent developments include the production of early forms of steel; the discovery of sodium—the first light metal—in 1809; the rise of modern alloy steels; and, since the end of World War II, the development of more sophisticated alloys.

Additional Information

The term “metal” applies to a large portion of the periodic table of elements. Metals are typically characterized by high electrical and thermal conductivity, luster, and, in many cases, notable malleability, ductility, and tensile strength. Most are solid at room temperature and readily form metallic bonds. They are a core pillar of most product market segments thanks to their advantageous properties and broad versatility.

What Is Metal?

Metal elements are characterized by several distinct physical and chemical properties. They are typically found toward the left side of the periodic table and are distinguished by their ability to form positive ions (cations) via the loss of electrons. These cations form metallic bonds with free electrons, allowing them to move freely among the metal atoms. This bonding structure contributes to their unique properties, such as ductility, conductivity, and strength.

What Are the Different Properties of Metal?

The common properties of metals are listed and discussed below:

1. Density

Density is a fundamental physical property, quantifying mass per unit volume. Metals, on average, exhibit higher densities than non-metals, influenced by factors like atomic structure, atomic number/mass, and crystalline/atomic packing arrangement. Variations in composition, temperature, and pressure impact metal density; pure metals often boast higher densities than alloys.

2. Electronegativity

Electronegativity is a measure of an atom's electron-attracting capability when forming molecular bonds. In metals, it underpins their chemical behaviors and interactions. Metals typically exhibit low electronegativity compared to non-metals, signifying weaker electron attractions during bond formation. Consequently, metals readily donate electrons to nearby atoms, yielding positively charged ions (cations) that can then form ionic compounds or metallic bonds.

When forming bonds, metal ions are enveloped by a sea of delocalized electrons, enabling efficient electricity and heat conduction. Metals react with non-metals, forming ionic compounds with high melting points. Some such reactions generate impermeable oxide coatings like aluminum oxide or chromium oxide, while others, like iron oxide (rust), allow further degradation. Almost all metals oxidize readily when conditions allow.

3. Luster

Luster defines how light interacts with a material's surface and how well it reflects to the observer. Metals' electron configuration and metallic bonding enable strong electromagnetic (EM) reflection. Incident light interacts with delocalized electrons in the lattice. They’re easily absorbed and re-emitted, imparting a characteristic brilliance to the macroscopic surface.

Luster varies with surface finish, purity, and crystal structure, with polished surfaces exhibiting greater reflectivity. Beyond aesthetics, luster holds practical significance because it reflects infrared and radio frequencies in addition to visible light.

4. Malleability

Malleability denotes a material's ability to endure compressive stress and deform without fracturing. This trait defines metals’ utility and adaptability. Metallic bonding and regular crystalline structure enable metal atoms to glide over one another under pressure, remaining in lattice contact by delocalized electrons circulating among metal ions.

Malleability varies based on microscopic crystal structure, temperature, and purity. Metals with the closest-packed microstructure, like gold and silver, are the most malleable. Malleability facilitates forging, stamping, and rolling, among other processes.

5. Opacity

Metals’ electronic structure makes them opaque in the visible spectrum. When light interacts with a metal surface, it encounters free electrons, which absorb and scatter photons. This scattering prevents light from passing through in a straight line, resulting in opacity. Metals absorb many wavelengths of light, including the visible spectrum, so they’re highly opaque.

Overall, electronic structure, electron mobility, and light scattering within the lattice combine to make metals opaque at all visible frequencies and more or less reflective across most spectra. This property influences laser-based machining methods, thermal control/dissipation applications, and aesthetic roles.

6. Ductility

A metal’s intrinsic ductility determines how it can be formed into useful shapes. Metallic bonding fosters high ductility, as atomic layers slide over each other under stress. Ductility varies across metals, and it is affected by purity, crystalline structure, and other factors. More densely packed crystal structures, like those in gold and silver, show higher ductility.

This is a key property for metals drawn into wires, rods, or thin sheets for electrical wiring, cables, and metal foils. Ductility also enables intricate component shaping via forging, extrusion, and rolling.

7. Hardness

Hardness gauges a material's resistance to deformation, scratching, or penetration. In metals, it has functional significance, dictating the products’ durability. Standardized tests like Rockwell, Vickers, or Brinell measure hardness.

Atomic structure and bonding have the biggest influence on metal hardness — densely packed crystal structures like face-centered cubic (FCC) or body-centered cubic (BCC) translate into harder metals. Alloying elements, grain size, and heat treatment also impact hardness. Hardness guides material selection — hard metals find use in tools and wear-resistant coatings, while softer ones are critical in resilient structural components for buildings and vehicles.

8. Conductivity

Conductivity describes a material's ability to conduct electricity or heat. Both are crucial features in many metal applications.

The free electrons in a metal’s crystal structure enable excellent electrical current flow. This property is found in wiring, circuits, and electronics. For the same reason, metals generally exhibit high thermal conductivity, facilitating heat transfer via lattice vibrations and free electron movement. Applications span from heat exchangers to cooking utensils. Conductivity hinges on factors like crystal structure and purity; dense structures like copper and silver exhibit superior conductivity. These inherent conductive qualities are important factors in material selection for electronics and thermal management items.

9. High Tensile Strength

Tensile strength describes a material's ability to resist tensile forces without permanent deformation. It's key for structural and load-bearing applications, and metals are usually far stronger in tension than are polymers or ceramics.

Metallic bonding underpins this strength — the atoms shift elastically under tension. Tensile strength varies with factors like composition, crystal structure, grain size, and processing. Metals with greater crystallinity, smaller grains, and higher purity exhibit superior tensile strength.

10. High Reflectivity

Reflectivity defines a material's ability to reflect light or other electromagnetic radiation. It is essentially the same as luster but applies to a larger frequency range, from X-ray/UV to long-wave radio. Nevertheless, the mechanisms of reflectivity are the same as those describing luster.

11. Sonorousness

Sonorousness characterizes a material's ability to produce resonant sound upon impact, a hallmark of most metals. This property stems from the fact that sound waves propagate easily through metallic crystalline structures. Sound reflection further extends the sound effects. Striking a metal object, like a bell or plate, induces highly elastic vibrations that travel through the lattice, resulting in clear, ringing tones. The macro effect is shape oscillations that induce sound waves in the surrounding air.

Practical applications abound, particularly in musical instruments where metals produce rich, resonant sounds. Additionally, sonorous metals are used in acoustic engineering, enhancing sound reflection and architectural acoustics in buildings and performance spaces.

12. High Melting and Boiling Points

Most metals exhibit very high melting and boiling points (MP and BP). The most notable exceptions are lead, tin, gallium, and mercury. Metallic bonding is responsible for these characteristics, with variations in atomic size and packing density affecting specific values.

Tungsten and molybdenum have high MPs and may be added as alloying agents to raise the MP of various materials for high-temperature machinery. Tantalum also has a high BP, benefiting vacuum systems.

13. Corrosion Resistance

Corrosion resistance describes the material’s durability amid exposure to corrosive elements like moisture, chlorides, acids, and alkalis. It safeguards structural integrity and aesthetics for all types of products.

Metals can corrode via oxidation or other chemical reactions, leading to surface defects and weakened structures. Factors like composition, treatments, and environment influence resistance.

Stainless steel, nickel, chromium, zinc, aluminum, and titanium excel because they form impermeable and self-healing oxide layers on their surfaces. Many cheaper but high-performing metals, like steel, require coatings or alloying. Steel can be coated in zinc or alloyed with chromium to resist oxidation. Gold and silver are both highly resistant to corrosion under typical conditions, with gold being virtually immune to most corrosive agents.

14. Magnetic Properties

Metals’ magnetic properties arise from their electron configuration and atomic arrangement. They are categorized into three types: ferromagnetic, paramagnetic, and diamagnetic metals. Ferromagnetic metals exhibit strong magnetic responses to external magnetic fields and will retain their magnetic alignment after being exposed to a magnetic field. Paramagnetic metals, on the other hand, are weakly attracted to magnetic fields but lose magnetization once the field is removed. Diamagnetic metals are repelled by magnetic fields and possess no net magnetization.

These three properties enable applications in magnetic storage, electromagnets, magnetic shielding, magnetic braking, and MRI machines.

15. Solid State at Room Temperature

Metals typically remain solid at room temperature due to the robust metallic bonds between atoms. The arrangement and strength of metallic bonds, influenced by factors like valence electrons and atomic size, dictate the melting point.

What Is the Use of Metal?

Metals have a plethora of applications owing to their physical, mechanical, and chemical properties. They are ideal for structural applications like construction and transportation, enduring heavy loads and harsh loading conditions. Their electrical and thermal conductivity makes metals vital in electrical wiring, electronics, and heating/cooling systems. Metals' malleability and ductility allow easy shaping and fabrication. Some offer excellent corrosion resistance, ideal for outdoor, marine, and chemically aggressive environments. High recyclability means metals can be reused, reducing the environmental impact of primary extraction and waste disposal. Some metals are visually appealing enough for jewelry and architectural finishes. Metals' high melting and boiling points ensure they retain mechanical strength, demanding high-temperature applications.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#10677. What does the term in Geography Col mean?

#10678. What does the term in Geography Colatitude mean?

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#5873. What does the adjective confederate mean?

#5874. What does the verb (used without object) confer mean?

Jai Ganesh · Dark Discussions at Cafe Infinity

2399) Charles H. Townes

Gist:

Work

Stimulated emission means that a light packet, a photon, coming in contact with an atom can cause an electron to descend to a lower energy level so that an additional photon with the same amount of energy is emitted. If electrons are elevated to higher energy levels with the help of heat or light, an avalanche-like effect occurs when they fall to lower levels. In the 1950s Charles Townes, Nicolay Basov, and Aleksandr Prokhorov contributed to putting this phenomenon into practical use in masers and lasers, which produce concentrated and coherent beams of microwaves and light, respectively.

Summary

Charles Hard Townes (born July 28, 1915, Greenville, South Carolina, U.S.—died January 27, 2015, Oakland, California) was an American physicist, joint winner (with the Soviet physicists Aleksandr M. Prokhorov and Nikolay G. Basov) of the Nobel Prize for Physics in 1964 for his role in the invention of the maser and the laser.

Townes studied at Furman University (B.A., B.S., 1935), Duke University (M.A., 1937), and the California Institute of Technology (Ph.D., 1939). In 1939 he joined the technical staff of Bell Telephone Laboratories, Inc., where he worked until 1948, when he joined the faculty of Columbia University. Three years later he conceived the idea of using ammonia molecules to amplify microwave radiation. Townes and two students completed the first such device in December 1953 and gave it the name maser, an acronym for “microwave amplification by stimulated emission of radiation.” In 1958 Townes and A.L. Schawlow showed that it was possible to construct a similar device using light—i.e., a laser.

From 1959 to 1961 Townes served as vice president and director of research of the Institute for Defense Analyses, Washington, D.C. He then was appointed provost and professor of physics at the Massachusetts Institute of Technology, Cambridge. In 1967 he became a professor at the University of California, Berkeley, where he initiated a program of radio and infrared astronomy leading to the discovery of complex molecules (ammonia and water) in the interstellar medium. He became professor emeritus in 1986.

Details

Charles Hard Townes (July 28, 1915 – January 27, 2015) was an American physicist. Townes worked on the theory and application of the maser, for which he obtained the fundamental patent, and other work in quantum electronics associated with both maser and laser devices. He shared the 1964 Nobel Prize in Physics with Nikolay Basov and Alexander Prokhorov. Townes was an adviser to the United States Government, meeting every US president from Harry S. Truman (1945) to Bill Clinton (1999).

He directed the US government's Science and Technology Advisory Committee for the Apollo lunar landing program. After becoming a professor of the University of California, Berkeley in 1967, he began an astrophysical program that produced several important discoveries, for example, the black hole at the center of the Milky Way galaxy.

Townes was religious and believed that science and religion are converging to provide a greater understanding of the nature and purpose of the universe.

Early life and education

Townes had German, Scottish, English, Welsh, Huguenot French, and Scotch Irish ancestry, Townes was born in Greenville, South Carolina, the son of Henry Keith Townes (1876–1958), an attorney, and Ellen Sumter Townes (née Hard; 1881–1980). His brother, Henry Keith Townes Jr., (January 20, 1913 – May 2, 1990), was a renowned entomologist who was a world authority on Ichneumon wasps. Charles earned his B.S. in Physics and B.A. in Modern Languages at Furman University, where he graduated in 1935. Townes completed work for the Master of Arts degree in physics at Duke University in 1937, and then began graduate school at the California Institute of Technology, from which he received a Ph.D. degree in 1939. During World War II, he worked on radar bombing systems at Bell Labs.

Career and research

In 1950, Townes was appointed professor at Columbia University. He served as executive director of the Columbia Radiation Laboratory from 1950 to 1952. He was Chairman of the Physics Department from 1952 to 1955.

In 1951, Townes conceived a new way to create intense, precise beams of coherent radiation, for which he invented the acronym maser (for Microwave Amplification by Stimulated Emission of Radiation). When the same principle was applied to higher frequencies, the term laser was used (the word "light" substituting for the word "microwave").

During 1953, Townes, James P. Gordon, and Herbert J. Zeiger built the first ammonia maser at Columbia University. This device used stimulated emission in a stream of energized ammonia molecules to produce amplification of microwaves at a frequency of about 24.0 gigahertz.

From 1959 to 1961, he was on leave of absence from Columbia University to serve as vice president and director of research of the Institute for Defense Analyses in Washington, D.C., a nonprofit organization, which advised the U.S. government and was operated by eleven universities. Between 1961 and 1967, Townes served as both provost and professor of physics at the Massachusetts Institute of Technology. Then, during 1967, he was appointed as a professor of physics at the University of California at Berkeley, where he remained for almost 50 years; his status was as professor emeritus by the time of his death during 2015. Between 1966 and 1970, he was chairman of the NASA Science Advisory Committee for the Apollo lunar landing program.

For his creation of the maser, Townes along with Nikolay Basov and Alexander Prokhorov received the 1964 Nobel Prize in Physics. Townes also developed the use of masers and lasers for astronomy, was part of a team that first discovered complex molecules in space, and determined the mass of the supermassive black hole at the center of the Milky Way galaxy.

During 2002–2003, Townes served as a Karl Schwarzschild Lecturer in Germany and the Birla Lecturer and Schroedinger Lecturer in India.

Townes is one of the 20 American recipients of the Nobel Prize in Physics to sign a letter addressed to President George W. Bush in May 2008, urging him to "reverse the damage done to basic science research in the Fiscal Year 2008 Omnibus Appropriations Bill" by requesting additional emergency funding for the Department of Energy's Office of Science, the National Science Foundation, and the National Institute of Standards and Technology.

Jai Ganesh · This is Cool

2451) Ozone

Gist

Ozone (O3) is a gas with a distinct odor that exists in two layers of the atmosphere: the protective stratospheric ozone layer and the harmful ground-level ozone. While stratospheric ozone is beneficial because it shields the Earth from the sun's harmful ultraviolet (UV) radiation, ground-level ozone is a major air pollutant and a key component of smog that can cause serious health problems. Ground-level ozone forms when pollutants from sources like car exhaust and industrial emissions react with sunlight.

Ozone (O3) is a gas with a chemical formula of O3, meaning it has three oxygen atoms instead of the two in the oxygen we breathe (O2). It can be "good" or "bad" depending on its location in the atmosphere: "good" stratospheric ozone forms a protective layer that shields Earth from the sun's harmful ultraviolet (UV) radiation, while "bad" ground-level ozone is a pollutant that can damage lungs and crops.

Summary

Ozone, also called trioxygen, is an inorganic molecule with the chemical formula O3. It is a pale-blue gas with a distinctively pungent odour. It is an allotrope of oxygen that is much less stable than the diatomic allotrope O2, breaking down in the lower atmosphere to O2 (dioxygen). Ozone is formed from dioxygen by the action of ultraviolet (UV) light and electrical discharges within the Earth's atmosphere. It is present in very low concentrations throughout the atmosphere, with its highest concentration high in the ozone layer of the stratosphere, which absorbs most of the Sun's ultraviolet (UV) radiation.

Ozone's odour is reminiscent of chlorine, and detectable by many people at concentrations of as little as 0.1 ppm in air. Ozone's O3 structure was determined in 1865. The molecule was later proven to have a bent structure and to be weakly diamagnetic. At standard temperature and pressure, ozone is a pale blue gas that condenses at cryogenic temperatures to a dark blue liquid and finally a violet-black solid. Ozone's instability with regard to more common dioxygen is such that both concentrated gas and liquid ozone may decompose explosively at elevated temperatures, physical shock, or fast warming to the boiling point. It is therefore used commercially only in low concentrations.

Ozone is a powerful oxidising agent (far more so than dioxygen) and has many industrial and consumer applications related to oxidation. This same high oxidising potential, however, causes ozone to damage mucous and respiratory tissues in animals, and also tissues in plants, above concentrations of about 0.1 ppm. While this makes ozone a potent respiratory hazard and pollutant near ground level, a higher concentration in the ozone layer (from two to eight ppm) is beneficial, preventing damaging UV light from reaching the Earth's surface.

Details

Ozone, (O3), triatomic allotrope of oxygen (a form of oxygen in which the molecule contains three atoms instead of two as in the common form) that accounts for the distinctive odor of the air after a thunderstorm or around electrical equipment. The odor of ozone around electrical machines was reported as early as 1785; ozone’s chemical constitution was established in 1872. Ozone is an irritating pale blue gas that is explosive and toxic, even at low concentrations. It occurs naturally in small amounts in Earth’s stratosphere, where it absorbs solar ultraviolet radiation, which otherwise could cause severe damage to living organisms on Earth’s surface. Under certain conditions, photochemical reactions between nitrogen oxides and hydrocarbons in the lower atmosphere can produce ozone in concentrations high enough to cause irritation of the eyes and mucous membranes. Such ground-level ozone is considered a major air pollutant.

Ozone usually is manufactured by passing an electric discharge through a current of oxygen or dry air. The resulting mixtures of ozone and original gases are suitable for most industrial purposes, although purer ozone may be obtained from them by various methods; for example, upon liquefaction, an oxygen-ozone mixture separates into two layers, of which the denser one contains about 75 percent ozone. The extreme instability and reactivity of concentrated ozone makes its preparation both difficult and hazardous.

Ozone is 1.5 times as dense as oxygen; at −112 °C (−170 °F) it condenses to a dark blue liquid, which freezes at −251.4 °C (−420 °F). The gas decomposes rapidly at temperatures above 100 °C (212 °F) or, in the presence of certain catalysts, at room temperatures. Although it resembles oxygen in many respects, ozone is much more reactive; hence, it is an extremely powerful oxidizing agent, particularly useful in converting olefins into aldehydes, ketones, or carboxylic acids. Because it can decolorize many substances, it is used commercially as a bleaching agent for organic compounds; as a strong germicide it is used to sterilize drinking water as well as to remove objectionable odors and flavors.

Additional Information

Ozone (O3) is a highly reactive gas composed of three oxygen atoms. It is both a natural and a man-made product that occurs in the Earth's upper atmosphere (the stratosphere) and lower atmosphere (the troposphere). Depending on where it is in the atmosphere, ozone affects life on Earth in either good or bad ways.

Stratospheric ozone is formed naturally through the interaction of solar ultraviolet (UV) radiation with molecular oxygen (O2). The "ozone layer," approximately 6 through 30 miles above the Earth's surface, reduces the amount of harmful UV radiation reaching the Earth's surface.

Tropospheric or ground-level ozone – what we breathe – is formed primarily from photochemical reactions between two major classes of air pollutants, volatile organic compounds (VOC) and nitrogen oxides (NOx). These reactions have traditionally been viewed as depending upon the presence of heat and sunlight, resulting in higher ambient ozone concentrations in summer months. Within the last decade, however, high ozone concentrations have also been observed under specific circumstances in cold months, where a few high elevation areas in the Western U.S. with high levels of local VOC and NOx emissions have formed ozone when snow is on the ground and temperatures are near or below freezing. Ozone contributes to what we typically experience as "smog" or haze, which still occurs most frequently in the summertime, but can occur throughout the year in some southern and mountain regions.

Although some stratospheric ozone is transported into the troposphere, and some VOC and NOx occur naturally, the majority of ground-level ozone is the result of reactions of man-made VOC and NOx. Significant sources of VOC are chemical plants, gasoline pumps, oil-based paints, autobody shops, and print shops. Nitrogen oxides result primarily from high temperature combustion. Significant sources are power plants, industrial furnaces and boilers, and motor vehicles.

Ozone has two properties of interest to human health. First, it absorbs UV light, reducing human exposure to harmful UV radiation that causes skin cancer and cataracts. Second, when inhaled, it reacts chemically with many biological molecules in the respiratory tract, leading to a number of adverse health effects. This course addresses this second property.

Ozone (O3) is a gas molecule composed of three oxygen atoms which occur both in the Earth's upper atmosphere and at ground level. There is both a "good" and "bad" Ozone.

Bad Ozone - Ground-level Ozone is an air pollutant that is harmful to breathe and damages crops, trees, and other vegetation. It is the main ingredient of urban smog. The Centers for Disease Control and Prevention (CDC) states that breathing ground-level ozone can be harmful to your health.

Good Ozone - Ozone is produced naturally in the stratosphere. But this "good" ozone layer is gradually being destroyed by man-made chemicals referred to as ozone-depleting substances (ODS). Essentially, Ozone is only good for our stratosphere, which is a layer of the earth's protective barrier.

Jai Ganesh · Dark Discussions at Cafe Infinity

Cold Quotes - VI

1. We're no longer in the Cold War. Eavesdropping on friends is unacceptable. - Vladimir Putin

2. Construction of the first gas pipeline system was started during the 1960s, at the height of the Cold War, and for all those years, from the 1960s until this day, Russia has been fulfilling its contract obligations in a very consistent and reliable way, regardless of the political situation. - Vladimir Putin

3. Well, my friend, this earth will one day be that cold corpse; it will become uninhabitable and uninhabited like the moon, which has long since lost all its vital heat. - Jules Verne

4. I don't plan to take a formal, cold approach with my children, but I expect a lot. I don't want my children to view me as their best friend. I want to be their mom. - Ivanka Trump

5. The cold, commercial word 'market' disguises its human character - a market is a collection of our aspirations, exertions, choices and desires. - Rupert Murdoch

6. If a patient is cold, if a patient is feverish, if a patient is faint, if he is sick after taking food, if he has a bed-sore, it is generally the fault not of the disease, but of the nursing. - Florence Nightingale

7. We've always had this experience that things take long, but I'm 100% convinced that our principles will in the end prevail. No one knew how the Cold War would end at the time, but it did end. This is within our living experience... I'm surprised at how fainthearted we sometimes are and how quickly we lose courage. - Angela Merkel

8. I think I'm teaching my teammates that they can still be successful while having fun and enjoying the moment rather than being a stone cold brick. - Simone Biles.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#2531. What does the medical term Microkeratome mean (instrument)?

Jai Ganesh · Jokes

Q: What water yields award winning cabbage heads?
A: Perspiration!
* * *
Q: What is another name for brussels sprouts?
A: Cabbage patch kids.
* * *
Q: What does a cabbage outlaw have?
A: A price on his head.
* * *
Q: What do you call a cabbage that's in love?
A: Head over heels.
* * *
Q: What do you tell a cabbage that's down in the dumps?
A: Hold your head up high.
* * *

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#9811.

Jai Ganesh · Jai Ganesh's Puzzles

Hi,

#6305.

Math Is Fun Forum

#1 This is Cool » Solution » Yesterday 23:08:00

#2 Re: This is Cool » Miscellany » Yesterday 22:27:18

#3 Science HQ » Metalloid » Yesterday 16:33:04

#4 Re: Exercises » Compute the solution: » 2025-11-26 22:57:15

#5 Science HQ » Nonmetal » 2025-11-22 19:00:15

#6 Re: Exercises » Compute the solution: » 2025-11-22 16:56:35

#7 Dark Discussions at Cafe Infinity » Collaborate Quotes » 2025-11-20 22:55:15

#8 Re: Jai Ganesh's Puzzles » General Quiz » 2025-11-20 22:29:42

#9 Re: Jai Ganesh's Puzzles » English language puzzles » 2025-11-20 16:40:40

#10 Re: Jai Ganesh's Puzzles » Doc, Doc! » 2025-11-20 16:30:11

#11 Jokes » Cabbage Jokes - II » 2025-11-20 14:42:39

#12 Re: Jai Ganesh's Puzzles » 10 second questions » 2025-11-20 14:08:18

#13 Re: Jai Ganesh's Puzzles » Oral puzzles » 2025-11-20 13:53:46

#14 Re: Exercises » Compute the solution: » 2025-11-20 13:38:25

#15 This is Cool » Nuclear Power » 2025-11-19 18:53:29

#16 Science HQ » Metal » 2025-11-19 18:17:15

#17 Re: Jai Ganesh's Puzzles » General Quiz » 2025-11-19 17:28:06

#18 Re: Jai Ganesh's Puzzles » English language puzzles » 2025-11-19 17:17:11

#19 Re: Dark Discussions at Cafe Infinity » crème de la crème » 2025-11-19 17:05:57

#20 Re: This is Cool » Miscellany » 2025-11-19 16:39:14

#21 Dark Discussions at Cafe Infinity » Cold Quotes - VI » 2025-11-19 16:05:48

#22 Re: Jai Ganesh's Puzzles » Doc, Doc! » 2025-11-19 15:44:35

#23 Jokes » Cabbage Quotes - I » 2025-11-19 15:03:43

#24 Re: Jai Ganesh's Puzzles » 10 second questions » 2025-11-19 14:26:22

#25 Re: Jai Ganesh's Puzzles » Oral puzzles » 2025-11-19 14:06:49

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