Wikipedia newwiki https://new.wikipedia.org/wiki/%E0%A4%AE%E0%A5%82_%E0%A4%AA%E0%A5%8C MediaWiki 1.44.0-wmf.6 first-letter माध्यम विशेष खँलाबँला छ्येलेमि छ्येलेमि खँलाबँला विकिपिडिया विकिपिडिया खँलाबँला किपा किपा खँलाबँला मिडियाविकि मिडियाविकि खँलाबँला Template Template talk ग्वाहालि ग्वाहालि खँलाबँला पुचः पुचः खँलाबँला दबू दबू खँलाबँला TimedText TimedText talk Module Module talk 0 4987 870575 861945 2024-12-11T13:20:32Z Флеровий 27133 870575 wikitext text/x-wiki [[किपा:Periodic table.svg|450px|thumbnail|right|[[पिरियोडिक टेबल]]य् रसायनिक तत्त्वत]] '''रसायनिक तत्त्व''' धागु छगु कथंया [[अणु]] ख। थन्यागु अणुतेत इमिगु [[आणविक ल्याखं]] नं परिभाषित याइ। आणविक ल्याखं धागु अणुया न्युक्लियसय् दुगु प्रोटोनया ल्या ख। थ्व खंग्व छगु हे प्रोटोन ल्या दुगु शुद्ध रसायनिक वस्तुयात इंगीय यायेत नं छ्येलि। <ref>[[Compendium of Chemical Terminology]], [http://goldbook.iupac.org/C01022.html chemical element]</ref> तत्त्वया साधारण दसु [[हाइड्रोजन]], [[नाइट्रोजन]], [[कार्बोन]] आदि ख। सकलय् [[२००७]] तक्कय् ११७ तत्त्वत लुयावगु दु। थुकिलि ९४ प्राकृतिक ख धासा आणविक ल्याखँ ८२ वा अप्व (बिस्मुथ व लिपाया तत्त्वत) मनुनं देकुगु ख। थ्व नापं, तत्त्व ४३ व ६१ ([[टेक्नोसियम]] व [[प्रोमेथियम]])या स्थायी [[आइसोटोप]] मदु। थ्व निगु तत्त्व प्रकृतिय् ध्वगिना वनि। आणविक ल्याखं ९४ तक्कया तत्त्वतेगु स्थायी न्युक्लियस मदुसा थ्व ल्याखं तक्कया तत्त्वत प्रकृतिय् [[युर्‍यानियम]] व [[थोरियम]]या ध्वगीगु प्रकृयाय् प्राकृतिक तवलं दयाच्वनि। <ref>A. Earnshaw, Norman Greenwood. ''Chemistry of the Elements, Second Edition''. Butterworth-Heinemann, 1997</ref> सकल [[रसायनिक वस्तु]]य् थ्व तत्त्वत दै। न्हुगु तत्त्वत इ-इले अप्राकृतिक [[न्युक्लियर रियाक्सन]]नं बुया वया च्वंगु खने दु। == इतिहास == '[[तत्त्व]]' धागु खंग्व संस्कृतं वगु ख। पाश्चात्य हलिमे युनानी दार्शनिक [[प्लेटो]]नं ३६०य् छगु खंल्हाबंल्हा ज्याझ्वले इनर्ग्यानिक व अर्ग्यानिक तत्त्वतेगु बारेय् धयादिगु खं तत्त्वया बारेय् दक्ले पुलांगु मुनातगु दस्ताबेजय् छगु ख। प्लेटो कथं सकल तत्त्वया चिधंगु पार्टिकलया विशेष आकार दै : [[टेट्राहेड्रन]] (मि), [[अक्टाहेड्रन]] (वायु), [[आइकोसाहेड्रन]] (ल), व [[क्युब]] (पृथ्वी)<ref>{{cite web | last = Hillar | first = Marian | year = 2004 | url = http://www.socinian.org/aristotles_de_anima.html | title = The Problem of the Soul in Aristotle's De anima | publisher = NASA WMAP | accessdate = 2006-08-10 }}</ref> {| style="border:1px solid #ddd; text-align:center; margin: auto;" cellspacing="20" | [[किपा:Tetrahedron.gif|140px]] || [[किपा:Octahedron.gif|150px]] || [[किपा:Icosahedron.gif|150px]] || [[किपा:Hexahedron.gif|125px]] || |- | [[टेट्राहेड्रन]] (मि) || [[अक्टाहेड्रन]] (वायु) || [[आइकोसाहेड्रन]] (ल) || [[क्युब]] (पृथ्वी) || |} Adding to the [[four elements]] of the Greek philosopher [[Empedocles]], in about 350 BC, [[Aristotle]] also used the term "element" and conceived of a fifth element called "[[Aether (classical element)|quintessence]]", which formed the heavens. Aristotle defined an element as: {{quote|'''Element''' – one of those bodies into which other bodies can be decomposed and which itself is not capable of being divided into other.<ref> {{cite book | last=Partington | first=J.R. | year=1937 | title=A Short History of Chemistry | location=New York | publisher=Dover Publications, Inc. | isbn=0486659771}}</ref>}} Building on this theory, in c. 790 Arabian chemist Jabir ibn-Hayyan ([[Geber]]) postulated that metals were formed out of two elements: sulphur, ‘the stone which burns’, which characterized the principle of combustibility, and mercury, which contained the idealized principle of metallic properties.<ref name="r8">Strathern, Paul. (2000). Mendeleyev’s Dream – the Quest for the Elements. New York: Berkley Books.</ref> Shortly thereafter, this evolved into the Arabic concept of the three principles: sulphur giving flammability or combustion, mercury giving volatility and stability, and salt giving solidity. In 1524, Swiss chemist [[Paracelsus]] adopted Aristotle’s four element theory, but reasoned that they appeared in bodies as Geber’s three principles. Paracelsus saw these principles as fundamental, and justified them by recourse to the description of how wood burns in fire. Mercury included the cohesive principle, so that when it left in smoke the wood fell apart. Smoke represented the volatility (the mercury principle), the heat-giving flames represented flammability (sulphur), and the remnant ash represented solidity (salt).<ref name="r8"/> In 1669, German physician and chemist [[Johann Becher]] published his Physica Subterranea, in which, in modification on the ideas of Paracelsus, he argued that the constituents of bodies are air, water, and three types of earth: ''terra fluida'', the mercurial element, which contributes fluidity and volatility; ''terra lapida'', the solidifying element, which produces fusibility or the binding quality; and ''terra pinguis'', the fatty element, which gives material substance its oily and combustible qualities.<ref name="r9">Partington, J.R. (1937). A Short History of Chemistry. New York: Dover Publications, Inc.</ref> These three earths correspond with Geber’s three principles. A piece of wood, for example, according to Becher, is composed of ash and terra pinguis; when the wood is burnt, the terra pinguis is released, leaving the ash. In other words, in combustion the fatty earth burns away. In 1661, [[Robert Boyle]] showed that there were more than just four [[classical element]]s as the ancients had assumed.<ref name="boyle" /> The first modern list of chemical elements was given in [[Antoine Lavoisier]]'s 1789 ''Elements of Chemistry'', which contained thirty-three elements, including [[light]] and caloric. By 1818, [[Jöns Jakob Berzelius]] had determined atomic weights for forty-five of the forty-nine accepted elements. In 1869, in [[Mendeleev]]'s famous [[periodic table]], shown below, there were sixty-six elements. [[किपा:Mendeleev's 1869 periodic table.png|300px|thumbnail|center|[[Mendeleev]]'s 1869 [[periodic table]]]] From Boyle until the early 20th century, an element was defined as a pure [[chemical substance|substance]] that cannot be decomposed into any simpler substance.<ref name="boyle">{{cite book | first=Robert | last=Boyle | authorlink=Robert Boyle | year=1661 | title=The Sceptical Chymist | location=London }}</ref> Said another way, an "element" cannot be transformed into other chemical substances by [[chemistry|chemical]] processes. In 1913, [[Henry Moseley]] discovered that the physical basis of the atomic number of the atom was its nuclear charge, which eventually led to the current definition. The current definition also avoids some ambiguities due to [[isotopes]] and [[allotropes]]. By 1919, there were seventy-two known elements.<ref>{{cite book | last=Carey | first=George, W. | year=1914 | title=The Chemistry of Human Life | location=Los Angeles|}}</ref> In 1955, element 101 was discovered and named [[mendelevium]] in honor of Mendeleev, the first to arrange the elements in a periodic manner. In October 2006, the synthesis of element 118 was reported; however, element 117 has not yet been created in the laboratory. ==दुखँ== दकलय् यांगु तत्त्व [[हाइद्रोजन]] व [[हिलियम]] ख। अन्य झ्यातूगु तत्त्व प्राकृतिक व मानवनिर्मित रुपय् न्युक्लियोसिन्थेसिस पद्धतिं दयावइ। थ्व पद्धति आपालं न्युक्लियर फिजियन पद्धतिं जुइ। सन् २००६तक म्हस्यूगु ११७ गू तत्त्व दु। थ्व परिभासाय् म्हसूगु तत्त्व धाःगु तत्त्वं ध्वगिया दयावःगु क्षणिक तत्त्वतेत न सूचीकृत यानातःगु दु। <ref>{{cite web | last = Sanderson | first = Katherine | title = Heaviest element made - again | work = nature@news.com | publisher = [[Nature (journal)]] | date = [[17 October]] [[2006]] | url = http://www.nature.com/news/2006/061016/full/061016-4.html | accessdate = 2006-10-19 }}</ref><ref>{{cite web | author = Phil Schewe and Ben Stein | title = Elements 116 and 118 Are Discovered | work = Physics News Update | publisher = [[American Institute of Physics]] | date = [[17 October]] [[2006]] | url = http://www.aip.org/pnu/2006/797.html | accessdate = 2006-10-19 }}</ref> अथेजुसां पृथ्वीइ प्राकृतिक रुपय् ९४ तत्त्व दयाच्वनि। थ्व तत्त्वय् खुता तत्त्व तसकं म्हो मात्राय् जक दयाच्वनि। थ्व खुगू तत्त्व थ्व कथं दु: [[तेक्नेसियम]], तत्त्व ल्या ४३; [[प्रोमेथियम]], तत्त्व ल्या ६१; [[एस्तातिन]], तत्त्व ल्या ८५; [[फ्रान्सियम]], तत्त्व ल्या ८७; [[नेप्चुनियम]], तत्त्व ल्या ९३; व [[प्लुतोनियम]], तत्त्व ल्या ९४। थ्व ९४ तत्त्व व सम्भवतः तत्त्व ९८ [[क्यालिफोर्नियम]] ब्रह्माण्डय् खनेदु। नगुतेगु स्पेक्त्रा जः व सुपरनोभाया चि-हाकःगु इतक दयाच्वनिगु रेदियोएक्तिभ जलय् न थ्व तत्त्वत दयाच्वं। ल्यंगु २२गू तत्त्व पृथ्वी व ब्रह्माण्डय् मदसां वैज्ञानिकतेसं रसायनिक पद्धतिं दयेकूगु दु। सन् १९३७स दकलय् न्हापांगु मानवनिर्मित तत्त्व [[तेक्नेसियम]]या विकास जुल। लिपा, थ्व तत्त्व प्रकृतिइ म्हो मात्राय् नं लुयावल। थथे मानवनिर्मित तत्त्व लिपा प्रकृतिइ लुयावैगु झका मेमेगु तत्त्वत नाप नं जूगु दु। === आणविक ल्याखँ === छगु तत्त्वया आणविक ल्याखँ थुकिलि दैगु प्रोटोनया ल्या बराबर जुइ। दसु- सकल [[कार्बोन]] अणुया [[आणविक न्युक्लियस]]य् ६गः प्रोटोन दै, अथे जुगुलिं कार्बोनया आणविक ल्याखँ (Z)=६ ख। थन्यागु अणुय् न्युट्रोनया ल्याखं पाय्‌फु, थथे न्युट्रोनया ल्याखँ पागु अणुतेत [[आइसोटोप]] धाइ। === आणविक मात्रा === The [[mass number]] of an element, ''A'', is the number of [[nucleons]] (protons and neutrons) in the atomic nucleus. Different isotopes of a given element are distinguished by their mass numbers, which are conventionally written as a super-index on the left hand side of the atomic symbol (e.g., ²³⁸U). The [[relative atomic mass]] of an element is the average of the atomic masses of all the chemical element's isotopes as found in a particular environment, weighted by isotopic abundance, relative to the [[atomic mass unit]] (u). This number may be a fraction which is not close to a whole number, due to the averaging process. On the other hand, the atomic mass of a pure isotope is quite close to its mass number. Whereas the mass number is a natural (or whole) number, the atomic mass of a single isotope is a real number which is close to a natural number, which in general differs slightly from the mass number because the mass of the protons and neutrons is not exactly 1 u, because the electrons also contribute slightly to the atomic mass, and because of the [[nuclear binding energy]]. For example, the mass of ¹⁹F is 18.9984032 u. The only exception to the atomic mass of an isotope not being a natural number is ¹²C, which has a mass of ''exactly'' 12, due to the ''definition of u'' (it is fixed as 1/12th of the mass of a free carbon-12 atom, exactly). === आइसोटोप === छुं आइसोतोप [[रेदियोएक्तिभ]] जुइ व अल्फा व बेता पार्तिकल विकिरण यासें ध्वगिना मेगु तत्त्वय् हिला वनि। छुं तत्त्वया धाःसा गैह्र-रेदियोएक्तिभ आइसोतोप हे मदु: स्थिर आइसोतोप मदूगु तत्त्वया धलखय् तेक्नेसियम (ल्या ४३), प्रोमेथियल (ल्या ६१) व तत्त्व ल्या ८२ स्वया अप्व तत्त्वल्या दूगु सकल तत्त्व ला। === एलोट्रोफी === छुं तत्त्व प्रकृतिइ थीथी आधारभूत रुपय् दयाच्वनि। छगू हे तत्त्वया थन्याःगु थीथी रुपयात [[एलोत्रोप]] धाइ। दसु: कार्बन तत्त्व [[हेरा]]या रुपय् दयाच्वनि, गुकि थ्व तत्त्वया तेत्राहेद्रल संरचना ख। नापं, कार्बन ग्राफाइतया संरचनाय् नं दयाच्वनि। ग्राफाइत कार्बनया हेक्सागनल संरचना ख। धाःसा फुतेरिन (fullerene)या संरचना ग्वलाःगु जुइ। === स्ट्यान्डर्ड स्टेट === The [[standard state]], or reference state, of an element is defined as its thermodynamically most stable state at 1 bar at a given temperature (typically at 298.15 K). In [[thermochemistry]], an element is defined to have an [[Standard enthalpy change of formation|enthalpy of formation]] of zero in its standard state. For example, the reference state for carbon is graphite, because it is more stable than the other allotropes. == Nomenclature == The naming of elements precedes the atomic theory of matter, although at the time it was not known which chemicals were elements and which compounds. When it was learned, existing names (''e.g.,'' gold, mercury, iron) were kept in most countries, and national differences emerged over the names of elements either for convenience, linguistic niceties, or nationalism. For example, the Germans use "Wasserstoff" for "hydrogen" and "Sauerstoff" for "oxygen", while [[English language|English]] and some [[romance language]]s use "sodium" for "natrium" and "potassium" for "kalium", and the French, Greeks and Poles prefer "azote/azot" for "nitrogen". But for international trade, the [[Table of chemical elements|official names]] of the chemical elements both ancient and recent are decided by the [[International Union of Pure and Applied Chemistry]], which has decided on a sort of international English language. That organization has recently prescribed that "aluminium" and "caesium" take the place of the US spellings "aluminum" and "cesium", while the US "sulfur" takes the place of the British "sulphur". But chemicals which are practicable to be sold in bulk within many countries, however, still have national names, and those which do not use the [[Latin alphabet]] cannot be expected to use the IUPAC name. According to IUPAC, the full name of an element is not capitalized, even if it is derived from a proper noun such as the elements [[californium]] or [[einsteinium]] (unless it would be capitalized by some other [[capitalization|rule]]). Isotopes of chemical elements are also uncapitalized if written out: [[carbon-12]] or [[uranium-235]]. In the second half of the twentieth century physics laboratories became able to produce nuclei of chemical elements that have a [[half life]] too short for them to remain in any appreciable amounts. These are also named by IUPAC, which generally adopts the name chosen by the discoverer. This can lead to the controversial question of which research group actually discovered an element, a question which delayed the naming of elements with atomic number of 104 and higher for a considerable time. (See [[element naming controversy]]). Precursors of such controversies involved the nationalistic namings of elements in the late nineteenth century. For example, ''[[lutetium]]'' was named in reference to Paris, France. The Germans were reluctant to relinquish naming rights to the French, often calling it ''cassiopeium''. The British discoverer of ''[[niobium]]'' originally named it ''columbium,'' in reference to the [[New World]]. It was used extensively as such by American publications prior to international standardization. == रसायनिक चिंत == === विषेश रसायनिक तत्त्व === Before chemistry became a science, [[alchemy|alchemists]] had designed arcane symbols for both metals and common compounds. These were however used as abbreviations in diagrams or procedures; there was no concept of atoms combining to form molecules. With his advances in the atomic theory of matter, [[John Dalton]] devised his own simpler symbols, based on circles, which were to be used to depict molecules. The current system of chemical notation was invented by [[Jöns Jakob Berzelius|Berzelius]]. In this typographical system chemical symbols are not used as mere abbreviations - though each consists of letters of the [[Latin alphabet]] - they are symbols intended to be used by peoples of all languages and alphabets. The first of these symbols were intended to be fully universal; since Latin was the common language of science at that time, they were abbreviations based on the [[Latin]] names of metals - Fe comes from Ferrum, Ag from Argentum. The symbols were not followed by a period (full stop) as abbreviations were. Later chemical elements were also assigned unique chemical symbols, based on the name of the element, but not necessarily in English. For example, [[sodium]] has the chemical symbol 'Na' after the Latin ''natrium''. The same applies to "W" (wolfram) for [[tungsten]], "Hg" (hydrargyrum) for [[Mercury (element)|mercury]], "K" (kalium) for [[potassium]], "Au" (aurum) for [[gold]], "Pb" (plumbum) for [[lead]], and "Sb" (stibium) for [[antimony]]. Chemical symbols are understood internationally when element names might need to be translated. There are sometimes differences; for example, the Germans have used "J" instead of "I" for iodine, so the character would not be confused with a [[roman numeral]]. The first letter of a chemical symbol is always capitalized, as in the preceding examples, and the subsequent letters, if any, are always lower case (small letters). === साधारण रसायनिक चिं === There are also symbols for series of chemical elements, for comparative formulas. These are one capital letter in length, and the letters are reserved so they are not permitted to be given for the names of specific elements. For example, an "X" is used to indicate a variable group amongst a class of compounds (though usually a [[halogen]]), while "R" is used for a [[Radical (chemistry)|radical]], meaning a compound structure such as a hydrocarbon chain. The letter "Q" is reserved for "heat" in a chemical reaction. "Y" is also often used as a general chemical symbol, although it is also the symbol of [[yttrium]]. "Z" is also frequently used as a general variable group. "L" is used to represent a general [[ligand]] in inorganic and organometallic chemistry. "M" is also often used in place of a general metal. === आइसोटोप चिंत === The three main isotopes of the element [[hydrogen]] are often written as H for protium, D for [[deuterium]] and T for [[tritium]]. This is in order to make it easier to use them in chemical equations, as it replaces the need to write out the mass number for each atom. थ्व थे याना च्वै: D_२O ([[हेभी वाटर]]) थे याना च्वइ मखु: ²H_२O == मात्रा == {{main|रसायनिक तत्त्वतेगु मात्रा}} During the early phases of the [[Big Bang]], [[Big Bang nucleosynthesis|nucleosynthesis]] of hydrogen nuclei resulted in the production of hydrogen and helium isotopes, as well as very minuscule amounts (on the order of 10^-10) of lithium and beryllium. No heavier elements were produced. As a result, the primordial abundance of atoms consisted of roughly 75% ¹H, 25% ⁴He, and 0.01% [[deuterium]].<ref>{{cite web | last = Wright | first = Edward L. | date = [[September 12]], [[2004]] | url = http://www.astro.ucla.edu/~wright/BBNS.html | title = Big Bang Nucleosynthesis | publisher = UCLA Division of Astronomy | accessdate = 2007-02-22 }}</ref> Subsequent enrichment of [[galactic halo]]s occurred due to [[Stellar nucleosynthesis]] and [[Supernova nucleosynthesis]].<ref name="synthesis">{{cite journal | author = G. Wallerstein, I. Iben Jr., P. Parker, A. M. Boesgaard, G. M. Hale, A. E. Champagne, C. A. Barnes, F. KM-dppeler, V. V. Smith, R. D. Hoffman, F. X. Timmes, C. Sneden, R.N. Boyd, B.S. Meyer, D.L. Lambert | title=Synthesis of the elements in stars: forty years of progress | journal=Reviews of Modern Physics | year=1999 | volume=69 | issue=4 | pages=995–1084 | url=http://www.cococubed.com/papers/wallerstein97.pdf | format=pdf | accessdate=2006-08-04 }}</ref> However [[intergalactic space]] can still closely resemble the primordial abundance, unless it has been enriched by some means. The following table shows the ten most common elements in our galaxy (estimated spectroscopically), as measured in parts per million, by mass.{{Fact|date=February 2007}} Nearby galaxies that have evolved along similar lines have a corresponding enrichment of elements heavier than hydrogen and helium. The more distant galaxies are being viewed as they appeared in the past, so their abundances of elements appear closer to the primordial mixture. As physical laws and processes appear common throughout the [[visible universe]], however, it is expected that these galaxies will likewise have evolved similar abundances of elements. {|class="wikitable" |- !तत्त्व!!पार्टस् प्रति मिलियन<br />मास कथं |- |[[हाइड्रोजन]] |७३९,००० |- |[[हेलियम]] |२४०,००० |- |[[अक्सिजन]] |१०,७०० |- |[[कार्बोन]] |४,६०० |- |[[नियोन]] |१,३४० |- |[[न]] |१,०४० |- |[[नाइट्रोजन]] |९७० |- |[[सिलिकन]] |६५० |- |[[म्याग्नेजियम]] |५८० |- |[[सल्फर]] |४४० |} == लिधंसा == <div class="references-small"> <references/> </div> == स्वयादिसँ == <div style="-moz-column-count:2; column-count:2;"> * [[रसायनिक चिं]] * [[रसायनशास्त्र|रसायन शास्त्र]] * [[पिरियोडिक टेबल]] </div> == पिनेया स्वापूत == {{Commons|Chemical elements}} * [http://www.vanderkrogt.net/elements/ Elementymology & Elements Multidict] word history and language dictionary * [http://glossary.dataenabled.com/ SDV Nuclear Glossary] === रसायनिक सूचं === * [http://www.webelements.com/ वेबइलेमेन्टस्] * [http://www.chemicool.com/ केमिकूल] * [http://www.chemicalelements.com/ केमिकलइलेमेन्ट] * [https://web.archive.org/web/20050119093914/http://pearl1.lanl.gov/periodic/default.htm लस एलामोस देय् प्रयोगशाला] {{तत्त्व}} {{Commonscat|Chemical elements}} [[पुचः:रसायनिक तत्त्व]] qjukg56vkegpf384uzi52307aegjhz5