Drūkšiai and Carbon group: Difference between pages

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Group →	14
↓ Period
2	6 C
3	14 Si
4	32 Ge
5	title="Sn, Tin" style="text-align:center; color:#000000; background-color:transparent; border:2px solid #6e6e8e; ;"\| 50 Sn
6	title="Pb, Lead" style="text-align:center; color:#000000; background-color:transparent; border:2px solid #6e6e8e; ;"\| 82 Pb
7	title="Uuq, Ununquadium" style="text-align:center; color:#000000; background-color:transparent; border:2px dotted #6e6e8e; ;"\| 114 Uuq

The carbon group is group 14 (IUPAC style) in the periodic table. Once also known as the tetrels (from Latin tetra, four), stemming from the earlier naming convention of this group as Group IVA. The group consists of carbon (C), silicon (Si), germanium (Ge), tin (Sn), lead (Pb), and ununquadium (Uuq).

Each of the elements in this group has 4 electrons in its outer energy level. The last orbital of all these elements is the p2 orbital. In most cases, the elements share their electrons. The tendency to lose electrons increases as the size of the atom increases, as it does with increasing atomic number. Carbon alone forms negative ions, in the form of carbide (C⁴⁻) ions. Silicon and germanium, both metalloids, each can form +4 ions. Tin and lead both are metals while unquadium is a synthetic shortlived radioactive metal.

Except for germanium, all of these elements are familiar in daily life either as the pure element or in the form of compounds. However, except for silicon, none of these elements are particularly plentiful in the Earth’s crust. Carbon forms an almost infinite variety of compounds, in both the plant and animal kingdoms. Silicon and silicate minerals are fundamental components of the Earth’s crust; silica (silicon dioxide) is sand. Tin and lead, although with very low abundances in the crust, are nevertheless common in everyday life. They occur in highly concentrated mineral deposits, can be obtained easily in the metallic state from those minerals, and are useful as metals and as alloys in many applications. Germanium, on the other hand, forms few characteristic minerals and is most commonly found only in small concentrations in association with the mineral zinc blende and in coals. Although germanium is indeed one of the rarer elements, it assumed importance upon recognition of its properties as a semiconductor.

History

Carbon, tin, and lead, are a few of the elements well known in the ancient world - together with sulfur, iron, copper, mercury, silver, and gold.

Carbon as an element was discovered by the first man to handle charcoal from his fire. Modern carbon chemistry dates from the development of coals, petroleum, and natural gas as fuels and from the elucidation of synthetic organic chemistry, both substantially developed since the 1800s.

Amorphous elemental silicon was first obtained pure in 1824 by the Swedish chemist Jöns Jacob Berzelius; impure silicon had already been obtained in 1811. Crystalline elemental silicon was not prepared until 1854, when it was obtained as a product of electrolysis. In the form of rock crystal, however, silicon was familiar to the predynastic Egyptians, who used it for beads and small vases; to the early Chinese; and probably to many others of the ancients. The manufacture of glass containing silica was carried out both by the Egyptians — at least as early as 1500 BCE — and by the Phoenicians. Certainly, many of the naturally occurring compounds called silicates were used in various kinds of mortar for construction of dwellings by the earliest people.

Germanium is one of three elements the existence of which was predicted in 1871 by the Russian chemist Dmitry Mendeleyev when he first devised his periodic table. Not until 1886, however, was germanium identified as one of the elements in a newly found mineral.

The origins of tin also are lost in antiquity. Apparently, bronzes, which are copper–tin alloys, were used by man in prehistory long before pure tin metal itself was isolated. Bronzes were common in early Mesopotamia, the Indus Valley, Egypt, Crete, Israel, and Peru. Much of the tin used by the early Mediterranean peoples apparently came from the Scilly Islands and from Cornwall in the British Isles, where tin mining dates to at least 300–200 BCE. Tin mines were operating in both the Inca and Aztec domains of South and Central America before the Spanish conquest.

Lead is mentioned often in early Biblical accounts. The Babylonians used the metal as plates on which to record inscriptions. The Romans used it for tablets, water pipes, coins, and even cooking utensils; indeed, as a result of the last use, lead poisoning was recognized in the time of Augustus Caesar. The compound known as white lead was apparently prepared as a decorative pigment at least as early as 200 BCE. Modern developments date to the exploitation in the late 1700s of deposits in the Missouri–Kansas–Oklahoma area in the United States.

@@ Line 1: / Line 1: @@
+{| style="float: right; border: 1px solid #ccc; margin: 0.5em 0pt 0.8em 1.4em; padding: 3px !important; width: 75px;"
-{{Infobox_lake
+! [[Group (periodic table)|Group]]&nbsp;→!! 14
- |lake_name = Lake Drūkšiai
+|-
- |image_lake =
+! ↓&nbsp;[[Period (periodic table)|Period]]
- |caption_lake =
+|-
- |image_bathymetry =
+! [[Period 2 element|2]]
- |caption_bathymetry =
+| {{element cell| 6|Carbon|C| |Solid|Nonmetals|Primordial}}
- |location =
+|-
- |coords = {{coord|55|37|17|N|26|36|21|E|type:waterbody|display=inline,title}}
+! [[Period 3 element|3]]
- |type =
+| {{element cell|14|Silicon|Si| |Solid|Metalloids|Primordial}}
- |inflow =
+|-
- |outflow =
+! [[Period 4 element|4]]
- |catchment = {{convert|613|km2|mi2|abbr=on}}
+| {{element cell|32|Germanium|Ge| |Solid|Metalloids|Primordial}}
- |basin_countries = Lithuania, Belarus
+|-
- |length =
+! [[Period 5 element|5]]
- |width =
+| {{element cell|50|Tin|Sn| |Solid|Poor metals|Primordial}}
- |area = {{convert|44.79|km2|mi2|abbr=on}}
+|-
- |depth = {{convert|7.6|m|ft|abbr=on}}
+! [[Period 6 element|6]]
- |max-depth = {{convert|33.3|m|ft|abbr=on}}
+| {{element cell|82|Lead|Pb| |Solid|Poor metals|Primordial}}
- |volume =
+|-
- |residence_time =
+! [[Period 7 element|7]]
- |shore =
+| {{element cell|114|Ununquadium|Uuq| |Solid|Poor metals|Synthetic}}
- |elevation = {{convert|141.6|m|ft|abbr=on}}
+|}
- |islands =
- |cities =
-}}
-'''Lake Drūkšiai''' ({{lang-lt|Drūkšiai}}, {{lang-be|Дрысвяты}}, {{IPA2|drɨ'sʲvʲatɨ}}) is a [[lake]] located in the northeast of [[Lithuania]] and [[Vitebsk Voblast]], [[Belarus]]. The lake supports the [[Ignalina Nuclear Power Plant]].
+The '''carbon group''' is group 14 ([[IUPAC]] style) in the [[periodic table]].  Once also known as the '''tetrels''' (from Latin ''tetra'', four), stemming from the earlier naming convention of this group as Group IVA. The group consists of [[carbon]] ('''C'''), [[silicon]] ('''Si'''), [[germanium]] ('''Ge'''), [[tin]] ('''Sn'''), [[lead]] ('''Pb'''), and [[ununquadium]] ('''Uuq''').
-The biggest depth of the lake is 33.3 m, and average is 7.6 m. The channel of the lake was formed during the movement of the [[glacier]]s by two perpendicular runways, which were extended from the north to the south and from the west to the east. Maximum depth of the first runway was 29 m, and second one - 33.3 m. The largest depths are located in the middle of the lake. The most shallow water is on the south ridge of the lake, the depth of which does not exceed 3 to 7 m.
+Each of the elements in this group has 4 [[electron]]s in its outer [[energy level]]. The last orbital of all these [[element]]s is the p2 [[orbital]]. In most cases, the elements share their electrons. The tendency to lose electrons increases as the size of the [[atom]] increases, as it does with increasing atomic number.
+[[Carbon]] alone forms negative [[ion]]s, in the form of [[carbide]] (C<sup>4−</sup>) ions.
+[[Silicon]] and [[germanium]], both [[metalloids]], each can form +4 ions.
+[[Tin]] and [[lead]] both are [[metal]]s while unquadium is a synthetic shortlived [[radioactive]] metal.
+Except for germanium, all of these elements are familiar in daily life either as the pure element or in the form of [[compounds]]. However, except for silicon, none of these elements are particularly plentiful in the Earth’s crust. Carbon forms an almost infinite variety of [[compounds of carbon|compounds]], in both the plant and animal kingdoms. Silicon and silicate minerals are fundamental components of the Earth’s crust; silica ([[silicon dioxide]]) is [[sand]]. Tin and lead, although with very low abundances in the crust, are nevertheless common in everyday life. They occur in highly concentrated mineral deposits, can be obtained easily in the metallic state from those minerals, and are useful as metals and as alloys in many applications. Germanium, on the other hand, forms few characteristic minerals and is most commonly found only in small concentrations in association with the mineral [[zinc blende]] and in coals. Although germanium is indeed one of the rarer elements, it assumed importance upon recognition of its properties as a [[semiconductor]].
+==History==
+[[Carbon]], [[tin]], and [[lead]], are a few of the elements well known in the ancient world - together with  [[sulfur]], [[iron]], [[copper]], [[mercury (element)|mercury]], [[silver]], and [[gold]].
+[[Carbon]] as an element was discovered by the first man to handle charcoal from his fire. Modern carbon chemistry dates from the development of coals, petroleum, and natural gas as fuels and from the elucidation of synthetic organic chemistry, both substantially developed since the 1800s.
+[[amorphous silicon|Amorphous elemental silicon]] was first obtained pure in 1824 by the Swedish chemist [[Jöns Jacob Berzelius]]; impure silicon had already been obtained in 1811. [[crystalline silicon|Crystalline elemental silicon]] was not prepared until 1854, when it was obtained as a product of electrolysis. In the form of rock crystal, however, silicon was familiar to the predynastic Egyptians, who used it for beads and small vases; to the early Chinese; and probably to many others of the ancients. The manufacture of glass containing silica was carried out both by the Egyptians — at least as early as 1500 BCE — and by the [[Phoenicians]]. Certainly, many of the naturally occurring compounds called silicates were used in various kinds of mortar for construction of dwellings by the earliest people.
+Germanium is one of three elements the existence of which was predicted in 1871 by the Russian chemist [[Dmitry Mendeleyev]] when he first devised his periodic table. Not until 1886, however, was germanium identified as one of the elements in a newly found mineral.
+The origins of tin also are lost in antiquity. Apparently, [[bronze]]s, which are copper–tin alloys, were used by man in prehistory long before pure tin metal itself was isolated. Bronzes were common in early Mesopotamia, the Indus Valley, Egypt, Crete, Israel, and Peru. Much of the tin used by the early Mediterranean peoples apparently came from the [[Scilly Island]]s and from [[Cornwall]] in the [[British Isles]], where tin mining dates to at least 300–200 BCE. Tin mines were operating in both the Inca and Aztec domains of [[South America|South]] and [[Central America]] before the Spanish conquest.
+Lead is mentioned often in early Biblical accounts. The [[Babylonians]] used the metal as plates on which to record inscriptions. The [[Romans]] used it for tablets, water pipes, coins, and even cooking utensils; indeed, as a result of the last use, lead poisoning was recognized in the time of [[Augustus Caesar]]. The compound known as white lead was apparently prepared as a decorative pigment at least as early as 200 BCE. Modern developments date to the exploitation in the late 1700s of deposits in the Missouri–Kansas–Oklahoma area in the United States.
 ==See also==
-*[[Lakes of Lithuania]]
+*[[Noble gas]]
+{|style="text-align: center;" border="1" cellpadding="2"
+|+ '''Explanation of above periodic table slice:'''
+! bgcolor="{{element color/Nonmetals}}" | [[Nonmetal]]s
+! bgcolor="{{element color/Metalloids}}" | [[Metalloid]]s
+! bgcolor="{{element color/Poor metals}}" | [[Poor metal]]s
+| atomic number in <font color="{{element color/Solid}}">{{element color/Solid}}</font> are solids
+| style="border:{{element frame/Primordial}};" | solid borders are [[primordial element]]s (older than the [[Earth]])
+| style="border:{{element frame/Synthetic}};" | dotted borders are [[radioactive decay|radioactive]], [[synthetic element]]s
+|}
+{{PeriodicTablesFooter}}
-{{Belarus-geo-stub}}
+[[Category:Chemical element groups|Group 14]]
-{{lithuania-geo-stub}}
+[[Category:Periodic table]]
+{{Link FA|lmo}}
-[[Category:Lakes of Lithuania|Druksiai]]
-[[Category:Lakes of Belarus|Drisvjaty]]
-[[Category:Utena County]]
+[[ar:مجموعة كربون]]
-[[cs:Drysvjaty]]
+[[ast:Elementos del grupu 14]]
-[[de:See Drūkšiai]]
-[[et:Drūkšiai]]
+[[ca:Grup del carboni]]
-[[es:Lago Druksiai]]
+[[cs:Tetrely]]
-[[eo:Drūkšiai]]
+[[de:Kohlenstoffgruppe]]
-[[fr:Lac Drūkšiai]]
+[[es:Elementos del grupo 14]]
-[[lv:Drūkšu ezers]]
+[[eo:Elemento de grupo 14]]
+[[eu:14. taldeko elementu]]
-[[lt:Drūkšiai]]
-[[nl:Drūkšiaimeer]]
+[[fr:Cristallogène]]
-[[nn:Drūkšiai]]
+[[ko:14족 원소]]
+[[it:Gruppo del carbonio]]
-[[pl:Dryświaty]]
+[[lmo:Grupp del carbòni]]
-[[tr:Drukşiai Gölü]]
+[[nl:Koolstofgroep]]
+[[ja:第14族元素]]
+[[nn:Gruppe 14]]
+[[nds:Cheemsch Elementen vun de 14. Grupp]]
+[[pl:Węglowce]]
+[[pt:Grupo do carbono]]
+[[sk:Tetrely]]
+[[sr:14. група хемијских елемената]]
+[[sh:14. grupa hemijskih elemenata]]
+[[fi:Hiiliryhmä]]
+[[sv:Kolgruppen]]
+[[th:หมู่คาร์บอน]]
+[[vi:Nhóm nguyên tố 14]]
+[[tr:Karbon grubu]]
+[[zh:碳族元素]]