Math Is Fun Forum

2531) Manganese Dioxide

Gist

Manganese dioxide (MnO2) is a black or brown inorganic compound occurring naturally as the mineral pyrolusite, which is the main ore of manganese. It is primarily used as a cathodic depolarizer in dry-cell batteries, a catalyst for oxygen production, and as a pigment in ceramics and glass. It is a strong oxidizing agent.

Manganese dioxide (MnO2) is a versatile inorganic compound primarily used as a depolarizer in dry cell (alkaline) batteries, a powerful oxidant in chemical synthesis, and a catalyst for producing oxygen. It is widely used in ceramics, glass decolorization, water purification, and as a raw material for producing manganese steel.

Summary:

Manganese dioxide (Mn02) is a highly versatile compound that is used for water treatment, water softening, iron removal, and other industrial manufacturing processes. Manganese dioxide is an indispensable organic compound for diverse applications across different sectors.

What is Manganese Dioxide?

Manganese Dioxide Chemical Formula: Mn02 : Manganese dioxide is an inorganic compound with the chemical formula Mn02. It is a black or brown-coloured material that naturally occurs as mineral pyrolusite. It is extensively used in different industries for its unique physical and chemical properties. Manganese dioxide is primarily used in groundwater applications. It effectively removes hydrogen sulfide, manganese radium, and iron from water.

What are the Uses of Managese Dioxide?

It finds application in different industries for its excellent chemical and physical properties. The following are the main uses of manganese dioxide.

Application of Manganese Dioxide

* Oxidizing Agent: One of the main uses of manganese dioxide is oxidizing agent. It oxidizes different chemicals and compounds that are essential in the production of batteries. Manganese dioxide is used as a depolarizer in dry-cell batteries to convert gas into water and generate energy.
* Catalyst: It is one of the most powerful catalysts for water treatment. It acts as a filtration agent for water. The catalyst reaction by manganese dioxide during the chemical oxidation reduction process helps to remove math, iron, and radium.
* Production of Ceramic Materials: They are used as a colouring agent to add brown and black pigments to ceramic glazes. They are also used in manufacturing clay to enhance strength and durability.
* Decolouring Agent:Manganese dioxide is used as the decolouring agent in glass production and an oxidizing agent in a chemical agent.
* Steel Production:It is used in the production of steel and other alloys. Mn02 is added to iron during the manufacturing process to remove impurities and improve the quality of the end product.
* Medical Research: Manganese dioxide nanomaterials are explored for drug delivery in cancer therapy.   

Details:

What is Manganese dioxide?

* Manganese dioxide is a black-brown solid that occurs naturally with the formula MnO2.
* Manganese dioxide (MnO2), known as pyrolusite when found in nature, is the most plentiful of all the manganese compounds.
* The principal ore of manganese dioxide is pyrolusite which was known to the ancients as a pigment.

Impure manganese can be made by reducing manganese dioxide with carbon. It is the only important compound of quadripositive manganese.

When MnO2 is fused with KOH

When blackish coloured compound MnO2 is fused with KOH in presence of air, it produces a dark green coloured compound potassium manganate.

Uses of Manganese dioxide – MnO2

* Used in Ceramic Industries for making glass, practically all the raw materials used in glass contain some iron, usually in the form of ferric oxide.
* Ores of manganese are not ‘active’ for direct use in dry cell manufacture and many of them need to be activated by physical or chemical treatment.
* Used in glassmaking to remove the green tint caused by iron impurities.
* Used as an important component in batteries. In the Leclanche cell, the positive electrode carbon, is surrounded by manganese dioxide and carbon.

Frequently Asked Questions – FAQs

Q1: What are the uses of manganese dioxide?
A1: MnO2 is primarily used as a part of dry cell batteries: alkaline batteries and the so-called Leclanché cell, or zinc–carbon batteries. For this application, large quantity are consumed annually. Many industrial uses include the use of MnO2 in ceramics and glass-making as an inorganic pigment.

Q2: Is MnO2 a catalyst?
A2: Manganese dioxide, a compound with the formula MnO2, is used as a catalyst for rapid oxidation of dissolved iron and manganese, present in the form of ferrous and manganese powder, in contact filters. These salts are oxidised by dissolved oxygen to an insoluble ferric and manganic acid.

Q3: How is manganese dioxide formed?
A3: By oxidation of the elemental manganese: elemental manganese reacts with oxygen in the environment to form MnO2. Because of this reaction, elemental manganese does not exist in nature – it is usually found as manganese dioxide in nature.

Q4: Is manganese dioxide harmful to humans?
A4: Harmful if inhaled or swallowed. It may cause eye, skin, and respiratory tract irritation. May cause central nervous system effects. Inhalation of fumes may cause metal-fume fever.

Q5: What are the symptoms of manganese toxicity?
A5: Manganese toxicity can result in a permanent neurological disorder known as manganism with symptoms that include tremors, difficulty walking, and facial muscle spasms. These symptoms are often preceded by other lesser symptoms, including irritability, aggressiveness, and hallucinations.

Additional Information

Manganese dioxide is the inorganic compound with the formula MnO2. This blackish or brown solid occurs naturally as the mineral pyrolusite, which is the main ore of manganese and a component of manganese nodules. The principal use for MnO2 is for dry-cell batteries, such as the alkaline battery and the zinc–carbon battery, although it is also used for other battery chemistries such as aqueous zinc-ion batteries. MnO2 is also used as a pigment and as a precursor to other manganese compounds, such as potassium permanganate (KMnO4). It is used as a reagent in organic synthesis, for example, for the oxidation of allylic alcohols. MnO2 has an α-polymorph that can incorporate a variety of atoms (as well as water molecules) in the "tunnels" or "channels" between the manganese oxide octahedra.

Key uses of manganese dioxide include:

Battery Manufacturing: It is a key ingredient (depolarizer) in Zinc-carbon (Leclanché) and alkaline batteries.
Water Treatment: Used for removing iron, manganese, and hydrogen sulfide from water supplies.
Catalyst: Functions as a catalyst in chemical processes, such as the decomposition of hydrogen peroxide and in producing oxygen.
Ceramics and Glass: Used as a colorant to create black or brown pigments and to remove the green tint from glass caused by iron impurities.
Chemical Synthesis: Acts as an oxidizing agent for producing aromatic chemicals and in various organic syntheses.
Other Applications: Employed in the production of fireworks, agricultural fungicides/pesticides, and in paints as a drying agent.

Hi,

#10809. What does the term in Geography Discordant coastline mean?

#10810. What does the term in Geography Dissected plateau mean?

Hi,

#2604. What does the medical term Heartburn mean?

Hi,

#6383.

2530) Amphibian

Gist

Amphibians are cold-blooded, vertebrate animals (possessing a backbone) that inhabit both aquatic and terrestrial environments. The name derives from Greek, meaning "living a double life" because they typically undergo metamorphosis, starting life in water with gills and developing lungs for land-based adult life.

The word amphibian was taken from the Greek “amphi” meaning “double” and “bios” meaning “life” which is quite fitting as these creatures do live a double life. Emerging from eggs that are usually laid in the water, most amphibians begin their life with gills.

Summary

Amphibians are ectothermic, anamniotic, four-limbed vertebrate animals that constitute the class Amphibia. In its broadest sense, it is a paraphyletic group encompassing all tetrapods, but excluding the amniotes (tetrapods with an amniotic membrane, such as modern reptiles, birds and mammals). All extant (living) amphibians belong to the monophyletic subclass Lissamphibia, with three living orders: Anura (frogs and toads), Urodela (salamanders), and Gymnophiona (caecilians). Evolved to be mostly semiaquatic, amphibians have adapted to inhabit a wide variety of habitats, with most species living in freshwater, wetland or terrestrial ecosystems (such as riparian woodland, fossorial and even arboreal habitats). Their life cycle typically starts out as aquatic larvae with gills known as tadpoles, but some species have developed behavioural adaptations to bypass this.

Young amphibians generally undergo metamorphosis from an aquatic larval form with gills to an air-breathing adult form with lungs. Amphibians use their skin as a secondary respiratory interface, and some small terrestrial salamanders and frogs even lack lungs and rely entirely on their skin. They are superficially similar to reptiles like lizards, but unlike reptiles and other amniotes, require access to water bodies to breed. With their complex reproductive needs and permeable skins, amphibians are often ecological indicators to habitat conditions; in recent decades there has been a dramatic decline in amphibian populations for many species around the globe.

The earliest amphibians evolved in the Devonian period from tetrapodomorph sarcopterygians (lobe-finned fish with articulated limb-like fins) that evolved primitive lungs, which were helpful in adapting to dry land. They diversified and became ecologically dominant during the Carboniferous and Permian periods, but were later displaced in terrestrial environments by early reptiles and basal synapsids (predecessors of mammals). The origin of modern lissamphibians, which first appeared during the Early Triassic, around 250 million years ago, has long been contentious. The most popular hypothesis is that they likely originated from temnospondyls, the most diverse group of prehistoric amphibians, during the Permian period. Another hypothesis is that they emerged from lepospondyls. A fourth group of lissamphibians, the Albanerpetontidae, became extinct around 2 million years ago.

The number of known amphibian species is approximately 8,000, of which nearly 90% are frogs. The smallest amphibian (and vertebrate) in the world is a frog from New Guinea (Paedophryne amauensis) with a length of just 7.7 mm (0.30 in). The largest living amphibian is the 1.8 m (5 ft 11 in) South China giant salamander (Andrias sligoi), but this is dwarfed by prehistoric temnospondyls such as Mastodonsaurus which could reach up to 6 m (20 ft) in length. The study of amphibians is called batrachology, while the study of both reptiles and amphibians is called herpetology.

Details

An amphibian is (class Amphibia), any member of the group of vertebrate animals characterized by their ability to exploit both aquatic and terrestrial habitats. The name amphibian, derived from the Greek amphibios meaning “living a double life,” reflects this dual life strategy—though some species are permanent land dwellers, while other species have a completely aquatic mode of existence.

Approximately 8,100 species of living amphibians are known. First appearing about 340 million years ago during the Middle Mississippian Epoch, they were one of the earliest groups to diverge from ancestral fish-tetrapod stock during the evolution of animals from strictly aquatic forms to terrestrial types. Today amphibians are represented by frogs and toads (order Anura), newts and salamanders (order Caudata), and caecilians (order Gymnophiona). These three orders of living amphibians are thought to derive from a single radiation of ancient amphibians, and although strikingly different in body form, they are probably the closest relatives to one another. As a group, the three orders make up subclass Lissamphibia. Neither the lissamphibians nor any of the extinct groups of amphibians were the ancestors of the group of tetrapods that gave rise to reptiles. Though some aspects of the biology and anatomy of the various amphibian groups might demonstrate features possessed by reptilian ancestors, amphibians are not the intermediate step in the evolution of reptiles from fishes.

Modern amphibians are united by several unique traits. They typically have a moist skin and rely heavily on cutaneous (skin-surface) respiration. They possess a double-channeled hearing system, green rods in their retinas to discriminate hues, and pedicellate (two-part) teeth. Some of these traits may have also existed in extinct groups.

Members of the three extant orders differ markedly in their structural appearance. Frogs and toads are tailless and somewhat squat with long, powerful hind limbs modified for leaping. In contrast, caecilians are limbless, wormlike, and highly adapted for a burrowing existence. Salamanders and newts have tails and two pairs of limbs of roughly the same size; however, they are somewhat less specialized in body form than the other two orders.

Many amphibians are obligate breeders in standing water. Eggs are laid in water, and the developing larvae are essentially free-living embryos; they must find their own food, escape predators, and perform other life functions while they continue to develop. As the larvae complete their embryonic development, they adopt an adult body plan that allows them to leave aquatic habitats for terrestrial ones. Even though this metamorphosis from aquatic to terrestrial life occurs in members of all three amphibian groups, there are many variants, and some taxa bear their young alive. Indeed, the roughly 8,100 living species of amphibians display more evolutionary experiments in reproductive mode than any other vertebrate group. Some taxa have aquatic eggs and larvae, whereas others embed their eggs in the skin on the back of the female; these eggs hatch as tadpoles or miniature frogs. In other groups, the young develop within the oviduct, with the embryos feeding on the wall of the oviduct. In some species, eggs develop within the female’s stomach.

The three living orders of amphibians vary greatly in size and structure. The presence of a long tail and two pairs of limbs of about equal size distinguishes newts and salamanders (order Caudata) from other amphibians, although members of the eel-like family Sirenidae have no hind limbs. Newts and salamanders vary greatly in length; members of the Mexican genus Thorius measure 25 to 30 mm (1 to 1.2 inches), whereas Andrias, a genus of giant aquatic salamanders endemic to China and Japan, reaches a length of more than 1.5 metres (5 feet). Frogs and toads (order Anura) are easily identified by their long hind limbs and the absence of a tail. They have only five to nine presacral vertebrae. The West African goliath frog, which can reach 30 cm (12 inches) from snout to vent and weigh up to 3.3 kg (7.3 pounds), is the largest anuran. Some of the smallest anurans include the South American brachycephalids, which have an adult snout-to-vent length of only 9.8 mm (0.4 inch), and some microhylids, which grow to 9 to 12 mm (0.4 to 0.5 inch) as adults. The long, slender, limbless caecilians (order Gymnophiona) are animals that have adapted to fossorial (burrowing) lifestyles by evolving a body segmented by annular grooves and a short, blunt tail. Caecilians can grow to more than 1 metre (3 feet) long. The largest species, Caecilia thompsoni, reaches a length of 1.5 metres (5 feet), whereas the smallest species, Idiocranium russeli, is only 90 to 114 mm (3.5 to 5 inches) long.

Distribution and abundance

Amphibians occur widely throughout the world, even edging north of the Arctic circle in Eurasia; they are absent only in Antarctica, most remote oceanic islands, and extremely xeric (dry) deserts. Frogs and toads show the greatest diversity in humid tropical environments. Salamanders primarily inhabit the Northern Hemisphere and are most abundant in cool, moist, montane forests; however, members of the family Plethodontidae, the lungless salamanders, are diverse in the humid tropical montane forests of Mexico, Central America, and northwestern South America. Caecilians are found spottily throughout the African, American, and Asian wet tropics.

For many years, habitat destruction has had a severe impact on the distribution and abundance of numerous amphibian species. Since the 1980s, a severe decline in the populations of many frog species has been observed. Although acid rain, global warming, and ozone depletion are contributing factors to these reductions, a full explanation of the disappearance in diverse environment remains uncertain. A parasitic fungus, the so-called amphibian chytrid (Batrachochytrium dendrobatidis), however, appears to be a major cause of substantial frog die-offs in parts of Australia and southern Central America and milder events in North America and Europe.

Economic importance

Amphibians, especially anurans, are economically useful in reducing the number of insects that destroy crops or transmit diseases. Frogs are exploited as food, both for local consumption and commercially for export, with thousands of tons of frog legs harvested annually. The skin secretions of various tropical anurans are known to have hallucinogenic effects and effects on the central nervous and respiratory systems in humans. Some secretions have been found to contain magainin, a substance that provides a natural antibiotic effect. Other skin secretions, especially toxins, have potential use as anesthetics and painkillers. Biochemists are currently investigating these substances for medicinal use.

Natural history:

Reproduction

The three living groups of amphibians have distinct evolutionary lineages and exhibit a diverse range of life histories. The breeding behaviour of each group is outlined below. One similar tendency among amphibians has been the evolution of direct development, in which the aquatic egg and free-swimming larval stages are eliminated. Development occurs fully within the egg capsule, and juveniles hatch as miniatures of the adult body form. Most species of lungless salamanders (family Plethodontidae), the largest salamander family, some caecilians, and many species of anurans have direct development. In addition, numerous caecilians and a few species of anurans and salamanders give birth to live young (viviparity).

Anurans display a wide variety of life histories. Centrolenids and phyllomedusine hylids deposit eggs on vegetation above streams or ponds; upon hatching, the tadpoles (anuran larvae) drop into the water where they continue to develop throughout their larval stage. Some species from the families Leptodactylidae and Rhacophoridae create foam nests for their eggs in aquatic, terrestrial, or arboreal habitats; after hatching, tadpoles of these families usually develop in water. Dendrobatids and other anurans deposit their eggs on land and transport them to water. Female hylid marsupial frogs are so called because they carry their eggs in a pouch on their backs. A few species lack a pouch and the tadpoles are exposed on the back; in some species, the female deposits her tadpoles in a pond as soon as they emerge.

Embryonic stage

Inside the egg, the embryo is enclosed in a series of semipermeable gelatinous capsules and suspended in perivitelline fluid, a fluid that also surrounds the yolk. The hatching larvae dissolve these capsules with enzymes secreted from glands on the tips of their snouts. The original yolk mass of the egg provides all nutrients necessary for development; however, various developmental stages utilize different nutrients. In early development, fats are the major energy source. During gastrulation, an early developmental stage in which the embryo consists of two cell layers, there is an increasing reliance on carbohydrates. After gastrulation, a return to fat utilization occurs. During the later developmental stages, when morphological structures form, proteins are the primary energy source. By the neurula stage, an embryonic stage in which nervous tissue develops, cilia appear on the embryo, and the graceful movement of these hairlike structures rotates the embryo within the perivitelline fluid. The larvae of direct developing and live-bearing caecilians, salamanders, and some anurans have external gills that press against the inner wall of the egg capsule, which permits an exchange of gases (oxygen and carbon dioxide) with the outside air or with maternal tissues. During development, ammonia is the principal form of nitrogenous waste, and it is diluted by a constant diffusion of water in the perivitelline fluid.

The development of limbs in the embryos of aquatic salamanders begins in the head region and proceeds in a wave down the body, and digits appear sequentially on both sets of limbs. Salamanders that deposit their eggs in streams produce embryos that develop both sets of limbs before they hatch, but salamanders that deposit their eggs in still water have embryos that develop only forelimbs before hatching. (In contrast, the limbs of anurans do not appear until after hatching.) Soon after the appearance of forelimbs, most pond-dwelling salamanders develop an ectodermal projection known as a balancer on each side of the head. These rodlike structures arise from the mandibular arch, contain nerves and capillaries, and produce a sticky secretion. They keep newly hatched larvae from sinking into the sediment and aid the salamander in maintaining its balance before its forelimbs develop. After the forelimbs appear, the balancers degenerate.

During the embryonic and early larval stages in anurans, paired adhesive organs arise from the hyoid arch, located at the base of the tongue. The sticky mucus they secrete can form a threadlike attachment between a newly hatched tadpole and the egg capsule or vegetation. Consequently, the tadpole that is still developing can remain in a stable position until it is capable of swimming and feeding on its own, after which the adhesive organs degenerate.

Larval stage

The amphibian larva represents a morphologically distinct stage between the embryo and adult. The larva is a free-living embryo. It must find food, avoid predators, and participate in all other aspects of free-living existence while it completes its embryonic development and growth. Salamander and caecilian larvae are carnivorous, and they have a morphology more like their respective adult forms than do anuran larvae. Not long after emerging from their egg capsules, larval salamanders, which have four fully developed limbs, start to feed on small aquatic invertebrates. The salamander larvae are smaller versions of adults, although they differ from their adult counterparts by the presence of external gills, a tailfin, distinctive larval dentition, a rudimentary tongue, and the absence of eyelids. Larval caecilians, also smaller models of adults, have external gills, a lateral-line system (a group of epidermal sense organs located over the head and along the side of the body), and a thin skin.

In anurans, tadpoles are fishlike when they hatch. They have short, generally ovoid bodies and long, laterally compressed tails that are composed of a central axis of musculature with dorsal and ventral fins. The mouth is located terminally (recessed), ringed with an oral disk that is often fringed by papillae and bears many rows of denticles made of keratin. Tadpoles often have horny beaks. Their gills are internal and covered by an operculum. Water taken in through the mouth passes over the gills and is expelled through one or more spiracular openings on the side of an opercular chamber. Anuran larvae are microphagous and thus feed largely on bacteria and algae that coat aquatic plants and debris.

Salamander larvae usually reach full size within two to four months, although they may remain larvae for two to three years before metamorphosis occurs. Some large aquatic species, such as the hellbender (Cryptobranchus alleganiensis) and the mud puppy (Necturus maculosus), never fully metamorphose and retain larval characteristics as adults (see below heterochrony). Tadpole development varies in length between species. Some anuran species living in xeric (dry) habitats, in which ephemeral ponds may exist for only a few weeks, develop and metamorphose within two to three weeks; however, most species require at least two months. Species living in cold mountain streams or lakes often require much more time. For example, the development of the tailed frog (Ascaphus truei) takes three years to complete.

Metamorphosis

Metamorphosis entails an abrupt and thorough change in an animal’s physiology and biochemistry, with concomitant structural and behavioral modifications. These changes mark the transformation from embryo to juvenile and the completion of development. Hormones ultimately control all events of larval growth and metamorphosis, and in many instances, development is accompanied by a shift from a fully aquatic life to a semiaquatic or fully terrestrial one.

Although salamanders undergo many structural modifications, these changes are not dramatic. The skin thickens as dermal glands develop and the caudal fin is resorbed. Gills are resorbed and gill slits close as lungs develop and branchial (gill) circulation is modified. Eyelids, tongue, and a maxillary bone are formed, and teeth develop on the maxillary and parasphenoid bones. Changes that occur in caecilians—the closure of the gill slit, the degeneration of the caudal fin, and the development of a tentacle and skin glands—are also minor.

Skeletal changes are much more dramatic in anurans because tadpoles make an abrupt and radical transition to their adult form. Limbs complete their development, and the forelimbs break through the opercular wall, early in metamorphosis. The tail shrinks as it is resorbed by the body, dermal glands develop, and the skin becomes thicker. As lungs and pulmonary ventilation develop, gills and their associated blood circulation disappear. Adult mouthparts replace their degenerating larval equivalents, and hyolaryngeal structures develop. All anurans except pipids (family Pipidae) develop a tongue. In the newly differentiated digestive tract, the intestine is shortened. The eyes become larger and are structurally altered; eyelids appear. These extreme changes of anuran metamorphosis clearly demarcate the shift from an aquatic to a terrestrial mode of life. Other less obvious yet nonetheless radical modifications of the larval skull and hyobranchial apparatus (that is, the part of the skeleton that serves as base for the tongue on the floor of the mouth) occur to make room for newly developed sense organs. These modifications also facilitate the transition from larval modes of feeding and respiration to those of the adult.

During metamorphosis, the urogenital system of all amphibians is also modified. A mesonephric or opisthonephric kidney—which uses nephrons located either in the middle or at the end of the nephric ridge in the developing embryo—replaces the degenerating rudimentary pronephric kidney. This transition is linked to the shift from production of a large volume of dilute ammonia to a small amount of concentrated urea. Gonads and associated ducts also appear and begin their maturation.

Heterochrony

Neoteny, once a widely used label for the condition of sexually mature larvae, has been discontinued by biologists and replaced by the concept of heterochrony. Heterochrony refers to the change in the timing and rate of developmental events, and it is a widespread feature in amphibian evolution, particularly in salamanders. During development, a structure can begin to develop sooner (predisplacement) or later (postdisplacement) in an organism than it occurred in the ancestral species or parents. Also, a structure may continue to develop beyond the previous embryological sequence (hypermorphosis) or the developmental sequence can stop earlier than normal (progenesis or hypomorphosis). Each of these heterochronic events can produce a structurally or functionally different organism.

The classical “neotenic” salamander, the axolotl (Ambystoma mexicanum), is a paedomorphic species (that is, a species that retains aspects of its juvenile form during its adult phase); it retains its larval gills. In the mole salamander (Ambystoma talpoideum), some populations also display hypomorphic development in which the development of several larval traits to the adult condition is delayed. Since the gonads mature, a population of sexually mature salamanders with a larval morphology is produced. Heterochrony also explains the presence of larval traits in adults of the salamander families Cryptobranchidae (hellbenders) and Proteidae (olms and mud puppies).

Heterochrony is not confined to salamanders. The different sized eardrums in the American bullfrog (Lithobates catesbeianus) are examples of hypermorphism in male bullfrogs. The development of the eardrums in the male extends beyond that of the female.

Life cycle

Many amphibians have a biphasic life cycle involving aquatic eggs and larvae that metamorphose into terrestrial or semiaquatic juveniles and adults. Commonly, they deposit large numbers of eggs in water; clutches of the tiger salamander (Ambystoma tigrinum) may exceed 5,000 eggs, and large bullfrogs (L. catesbeianus) may produce clutches of 45,000 eggs. Egg size and water temperature are important factors that influence an embryo’s development time. Eggs of many anuran species laid in warm water require only one or two days to develop, whereas eggs deposited in cold mountain lakes or streams may not hatch for 30 to 40 days. The development of salamander eggs often requires more time, with hatching occurring 20 to 270 days after fertilization.

Food and feeding

Adult amphibians consume a wide variety of foods. Earthworms are the main diet of burrowing caecilians, whereas anurans and salamanders feed primarily on insects and other arthropods. Large salamanders and some large anurans eat small vertebrates, including birds and mammals. Most anurans and salamanders locate prey by sight, although some use their sense of smell. The majority of salamanders and diurnal (that is, active during daylight) terrestrial anurans are active foragers, but many other anurans employ a sit-and-wait technique. Caecilians locate their underground prey with a chemosensory tentacle and capture their quarry with a powerful bite (see chemoreception). Aquatic salamanders lunge at their prey with an open mouth and appear to drag the victim in by expanding their buccal (oral) cavity. The terrestrial lunged salamander extends its sticky tongue, which is attached anteriorly to the floor of the mouth, to ensnare a meal. In lungless salamanders, the hyobranchial apparatus is not part of the process of buccal respiration; this apparatus is modified so that it can project the tongue from the mouth. The end of the tongue is sticky to adhere to prey, and prey can be captured at distances ranging from 40 to 80 percent of the salamander’s body length.

Primitive anurans have feeding mechanisms that resemble those of the typical terrestrial salamanders. More advanced anurans employ a “lingual flip,” in which the surfaces of the retracted tongue are twisted and inverted in the fully extended tongue. The pipids, which are completely aquatic, are unique among anurans; they lack a tongue and thus must essentially drag food and water into their mouth.

Form and function:

Common features

Although the structure of the muscular, skeletal, and other anatomical systems are specifically modified for each group, amphibians are often set apart from other groups of animals by their characteristic skin, or integument, and evolutionary advances in vision and hearing.

The circulatory and respiratory systems work with the integument to provide cutaneous respiration. A broad network of cutaneous capillaries facilitates gas exchange and the diffusion of water and ions between the animal and the environment. Several species of salamanders and at least one species of frog (Barbourula kalimantanensis) are lungless. Amphibians also employ various combinations of branchial and pulmonary strategies to breathe. The buccal pump mechanism, which involves the pushing of air between the lungs and the closed mouth, is present in amphibians and some groups of fishes.

In addition to its roles in respiration and maintaining water balance, the integument of amphibians contains poison glands that release toxins. Specific toxins are found only in amphibians and are used to defend against predators.

The eye of the modern amphibian (or lissamphibian) has a lid, associated glands, and ducts. It also has muscles that allow its accommodation within or on top of the head, depth perception, and true colour vision. These adaptations are regarded as the first evolutionary improvements in vertebrate terrestrial vision. Green rods in the retina, which permit the perception of a wide range of wavelengths, are found only in lissamphibians.

The amphibian auditory system is also specially adapted. One modification is the papilla amphibiorum, a patch of sensory tissues that is sensitive to low-frequency sound. Also unique to lissamphibians is the columella-opercular complex, a pair of elements associated with the auditory capsule that transmit airborne (columella) or seismic (operculum) signals.

Structural differences

The environment helps to mold the morphology of an organism. The markedly different structural forms of the three living orders demonstrate that each group has had a long, separate evolutionary history.

Salamanders

Salamanders have less-specialized morphologies than do the other two orders. They have small heads and long slender bodies made up of four limbs and a tail. Although the skulls of most terrestrial salamanders consist of more individual pieces than do those of either caecilians or anurans, they are arched, narrow, and not well roofed. These skulls have an extra set of articulations with the vertebral column, a characteristic that may have been an evolutionary strategy for stabilizing the head on the axial skeleton (vertebral column) in terrestrial salamanders; other amphibians developed a specialized trunk musculature to meet this challenge.

The hyoid apparatus in the floor of the mouth enables salamanders to capture prey by projecting their fleshy tongues from the buccal cavity, although most are only able to roll their tongues forward over their lower jaws to snare their dinner. Food is held and manipulated in the buccal cavity by the teeth and tongue. This mechanism does not require adaptations to the mandibular and jaw muscles or sturdy, specialized teeth—features that most salamanders lack. Well-developed eyes and nasal organs, however, are needed to locate prey. Because salamanders do not depend on their vocal abilities, their auditory apparatus is less specialized than that of anurans.

Most salamander species have a generalized mode of locomotion, which is reflected by a lack of specialization in the musculoskeletal system. Salamanders walk methodically and move the limbs in the standard diagonal-sequence gait of quadrupeds. Aquatic salamanders show the greatest divergence from this generalized morphological pattern. Because they are kept afloat by their aquatic environment, they are often larger, devoid of limbs, and swim via the lateral undulation of the trunk and tail.

Caecilians

Of the three living amphibian orders, caecilians show the least divergence in structure and form. All caecilians, except for a few aquatic species, lead subterranean existences and thus have similar specialized morphologies. They have a wormlike appearance, with compact and bony heads in which the centres of ossification have fused to provide a strong, spadelike braincase. While useful in tunneling through the soil, this compact cranium does not allow much room for the jaw muscles to develop. Thus, the lower jaw is attached to the main adductor muscle of the jaw by a retroarticular process outside the cranium, and the caecilian cannot extend its tongue from the buccal cavity.

Vision, of little importance in the caecilian’s environment, is not acute; however, the nasal organs are well developed, and chemosensory perception is greatly enhanced by the existence of a tentacle (see chemoreception). The sense of hearing is probably less sensitive than that of salamanders or anurans. If the operculum (a feature analogous to auditory stapes) is present, it is incorporated into the columella (the rod made of bone or cartilage connecting the tympanic membrane with the internal ear).

Subterranean movement and feeding are aided by alterations of the axial musculoskeletal system. The overlying skin is attached to the axial muscles, and this creates a tough sheath that encases the long, muscular body and covers the posterior part of the skull. Caecilians move through soil by a process called concertina locomotion, in which the body alternately folds and extends itself along its entire length, often occurring within the envelope of skin as well as by flexures of the entire body.

Anurans

Anurans are more widespread, diverse, and numerous than either salamanders or caecilians. Anurans display a broader range of specialization in locomotion, feeding, and reproduction in their adaptation to many different environments and lifestyles. In general, anurans have a broad, flat head—which is almost as wide as their body—and a short trunk that, aside from the sacral area, is relatively inflexible. Long, powerful hind limbs propel the fused head and trunk in a forward trajectory. These leaping movements require more complex pectoral and pelvic girdles than that of salamanders. The pectoral girdle is designed to absorb the shock of the anuran as it lands on its forelimbs; an elastic, muscular suspension connecting the pectoral girdle to the skull and vertebral column provides this ability. The pelvic girdle horizontally flanks the coccyx, the bony rod at the posterior end of the vertebral column. Muscles and ligaments attach the pelvic girdle to the coccyx, sacrum, presacral vertebrae, and proximal part of the hind limb. Thus, when the animal jumps, the pelvic girdle lies in the same plane as the axial column, and, when the animal sits, the posterior end of the girdle is deflected ventrally.

In addition to the specializations for leaping, many anurans have developed structures that allow them to burrow or climb trees. These structures primarily involve modifications in limb proportions and iliosacral articulation. Arboreal (tree-dwelling) anurans have long limbs and digits with large, terminal, adhesive pads; anurans that burrow have short sturdy limbs and large spatulate tubercles made of keratin on their feet. The pipids, specialized for their aquatic environment, have little flexibility in their axial skeletons and instead propel their flat, fused bodies through the water with powerful hind limbs and large, fully webbed feet.

Anurans depend on their visual acumen for feeding and locomotion, and hence the eyes of most species are large and well developed. Because vocalizing is part of their mating and territorial behaviour, their ears are also well developed. Most species have an external tympanum (eardrum), a structure that is absent in salamanders and caecilians.

Additional Information

Amphibians are a class of cold-blooded vertebrates made up of frogs, toads, salamanders, newts, and caecilians (wormlike animals with poorly developed eyes). All amphibians spend part of their lives in water and part on land, which is how they earned their name—“amphibian” comes from a Greek word meaning “double life.” These animals are born with gills, and while some outgrow them as they transform into adults, others retain them for their entire lives.

Amphibians are the most threatened class of animals in nature. They are extremely susceptible to environmental threats because of their porous eggs and semipermeable skin. Every major threat, from climate change to pollution to disease, affects amphibians and has put them at serious risk.

Amphibians live part of their lives in water and part on land. They are vertebrates and are also ectothermic; they cannot regulate their own body heat, so they depend on sunlight to become warm and active. Amphibians also can't cool down on their own, so if they get too hot, they have to find a burrow or some other shade. In cold weather, amphibians tend to be sluggish and do not move around much.

Metamorphosis

Young amphibians do not look like their parents. Generally called larvae, they change in body shape, diet, and lifestyle as they develop, a process called metamorphosis. A frog is a good example, starting out as a tadpole with gills to breathe underwater and a tail to swim with. As the young frog gets older, it develops lungs, legs, and a different mouth. Its eyes also change position, and it loses its tail. At this point it is an adult frog and spends most of its time hopping on land rather than swimming like a fish in the water.

Moist is Best

Most amphibians have soft, moist skin that is protected by a slippery secretion of mucus. They also tend to live in moist places or near water to keep their bodies from drying out. Many adult amphibians also have poison-producing glands in their skin, which make them taste bad to predators and might even poison a predator that bites or swallows them. Some of these amphibians, like poison frogs, are brightly colored as a warning: Don't eat me, or you'll be sorry!

Three Groups

There are about 5,500 known amphibian species, divided into three main groups: salamanders and newts, caecilians, and frogs and toads. The largest amphibian is the Chinese giant salamander at nearly 6 feet (1.8 meters) and 140 pounds (63 kilograms), and the smallest is the gold frog at 0.39 inches (1 centimeter) long.

2467) Cecil Frank Powell

Gist:

Work

Charged particles moving through photographic emulsions leave tracks that can be examined in the images developed afterward. Cecil Powell made improvements to this technique in order to study radiation and nuclear reactions. In 1947 he discovered that incident cosmic ray particles could react with atomic nuclei in the emulsion, creating other, short-lived particles. These particles turned out to be pi-mesons, the particles proposed by Yukawa as mediating the strong force binding protons and neutrons in nuclei.

Summary

Cecil Frank Powell (born December 5, 1903, Tonbridge, Kent, England—died August 9, 1969, Casargo, Italy) was a British physicist and winner of the Nobel Prize for Physics in 1950 for his development of the photographic method of studying nuclear processes and for the resulting discovery of the pion (pi-meson), a heavy subatomic particle. The pion proved to be the hypothetical particle proposed in 1935 by Yukawa Hideki of Japan in his theory of nuclear physics.

In 1928 Powell was appointed research assistant at the Henry Herbert Wills Physical Laboratory at the University of Bristol. He became professor of physics at Bristol in 1948 and director of the Wills Laboratory in 1964. Between 1939 and 1945 he developed the necessary techniques for using sensitive photographic emulsions to record the paths of cosmic rays. In plates exposed at the top of high mountains or sent up in high-altitude balloons, cosmic-ray interactions were recorded, and in 1947 the data revealed the existence of the pion (π+) as well as the process whereby it decays into two other particles, an antimuon (mu-meson) and a neutrino. Powell also discovered the antipion (π−) and, in 1949, the modes of decay of kaons (K-mesons).

Details

Cecil Frank Powell (5 December 1903 – 9 August 1969) was a British experimental physicist who received the Nobel Prize in Physics in 1950 for heading the team that developed the photographic method of studying nuclear processes, and for the resulting discovery of the pion (pi-meson).

Education

Cecil Frank Powell was born on 5 December 1903 in Tonbridge, England, the son of Frank Powell, a gunsmith, and Elizabeth Caroline Bisacre.

Powell was educated at a local primary school before gaining a scholarship to The Judd School. He then entered Sidney Sussex College, Cambridge, graduating in 1925 with First Class Honours in the Natural Sciences Tripos. After completing his bachelor's degree, he worked under Ernest Rutherford and C. T. R. Wilson in the Cavendish Laboratory, conducting research on condensation phenomena. He received his Ph.D. in Physics in 1927.

In 1932, Powell married Isobel Artner (1907–1995). They had two daughters, Jane and Annie.

Career and research

In 1927, Powell became a research assistant to Arthur Mannering Tyndall in the H. H. Wills Physical Laboratory at the University of Bristol. He was later appointed lecturer and, in 1948, Melville Wills Professor of Physics.[6] In 1936, he took part in a Royal Society expedition to Montserrat in the West Indies as part of a study of a damaging earthquake swarm. He appears on a stamp issued in Grenada.

During his time at Bristol University, Powell applied himself to the development of techniques for measuring the mobility of positive ions, to establishing the nature of the ions in common gases, and to the construction and use of a Walton generator to study the scattering of atomic nuclei. He also began to develop methods employing specialised photographic emulsions to facilitate the recording of the tracks of elementary particles, and in 1938 began applying this technique to the study of cosmic radiation, exposing photographic plates at high-altitude, at the tops of mountains and using specially designed balloons, collaborating in the study with Giuseppe Occhialini, Hugh Muirhead, and César Lattes. This work led in 1947 to the discovery of the pion (pi-meson), which proved to be the hypothetical particle proposed in 1935 by Hideki Yukawa in his theory of nuclear forces.

In 1950, Powell was awarded the Nobel Prize in Physics "for his development of the photographic method of studying nuclear processes and his discoveries regarding mesons made with this method." Lattes was working with him at the time of the discovery and had improved the sensitivity of the photographic emulsion. Lattes was the first to write an article describing the discovery that would lead to the Nobel Prize. Debendra Mohan Bose and Bibha Chowdhuri published three consecutive papers in Nature, but could not continue further investigation on account of "non-availability of more sensitive emulsion plates" during the war years.

Seven years after this discovery of mesons by Bose and Chowdhuri, Powell made the same discovery of pions and muons and further decay of muons to electrons… using the same technique". He acknowledged in his book, "In 1941, Bose and Chaudhuri had pointed it out that it is possible, in principle, to distinguish between the tracks of protons and mesons in an emulsion… They concluded that many of the charged particles arrested in their plates were lighter than protons, their mean mass being … the physical basis of their method was correct and their work represents the first approach to the scattering method of determining momenta of charged particles by observation of their tracks in emulsion". In fact, the measured mass of the particle by Bose and Chowdhuri was very close to the accepted value measured by Powell who used improved "full-tone" plates. From 1952, Powell was appointed director of several expeditions to Sardinia and the Po Valley, Italy, utilizing high-altitude balloon flights.

In 1955, Powell, also a member of the World Federation of Scientific Workers, added his signature to the Russell–Einstein Manifesto put forward by Bertrand Russell, Albert Einstein, and Joseph Rotblat, and was involved in preparations for the first Pugwash Conference on Science and World Affairs. As Rotblat put it, "Cecil Powell has been the backbone of the Pugwash Movement. He gave it coherence, endurance and vitality." Powell chaired the meetings of the Pugwash Continuing Committee, often standing in for Bertrand Russell, and attended meetings until 1968.

In 1961, Powell served on the Scientific Policy Committee of the European Organization for Nuclear Research (CERN).

Global policy

He was one of the signatories of the agreement to convene a convention for drafting a world constitution. As a result, for the first time in human history, a World Constituent Assembly convened to draft and adopt the Constitution for the Federation of Earth.

Death

On 9 August 1969, Powell died of a heart attack while on holiday with his wife in the Valsassina region of Italy, lodging in a house in Sanico, in the Province of Lecco.

Giuseppe Occhialini had a wooden bench built with Powell's name carved into a commemorative plaque, and then transported it to Premana, a village in the mountains above Lake Como. It was installed on the path where he died, outside the Rifugio Capanna Vittoria (now the Capanna Vittoria restaurant), on the Alpe Giumello, in Casargo. Occhialini's reason was, "...if that bench had already been there, Powell would probably have stopped to rest there."

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