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In the periodic table of the elements, elements are arranged in a series of rows (or periods) so that those with similar properties appear in vertical columns. Elements of the same period have the same number of electron shells; with each group across a period, the elements have one more proton and electron and become less metallic. This arrangement reflects the periodic recurrence of similar properties as the atomic number increases. For example, the alkaline metals lie in one group (group 1) and share similar properties, such as high reactivity and the tendency to lose one electron to arrive at a noble-gas electronic configuration. The periodic table of elements has a total of 118 elements. Madelung rule.svg

Modern quantum mechanics explains these periodic trends in properties in terms of electron shells. As atomic number increases, shells fill with electrons in approximately the order shown at right. The filling of each shell corresponds to a row in the table.

In the s-block and p-block of the periodic table, elements within the same period generally do not exhibit trends and similarities in properties (vertical trends down groups are more significant). However in the d-block, trends across periods become significant, and in the f-block elements show a high degree of similarity across periods (particularly the lanthanides). Contents

1 Periods 1.1 Chemical elements in the first period 1.2 Chemical elements in the second period 1.3 Chemical elements in the third period 1.4 Chemical elements in the fourth period 1.5 Chemical elements in the fifth period 1.6 Chemical elements in the sixth period 1.7 Chemical elements in the seventh period 1.8 Chemical elements in the eighth period 2 References

Periods

Seven periods of elements occur naturally on Earth. For period 8, which includes elements which may be synthesized after 2011, see the extended periodic table.

A group in chemistry means a family of objects with similarities like different families. Chemical elements in the first period Main article: Period 1 element Group 	1/17 	2/18 Name 	1 H 	2 He

The first period contains fewer elements than any other, with only two, hydrogen and helium. They therefore do not follow the octet rule. Chemically, helium behaves as a noble gas, and thus is taken to be part of the group 18 elements. However, in terms of its nuclear structure it belongs to the s block, and is therefore sometimes classified as a group 2 element, or simultaneously both 2 and 18. Hydrogen readily loses and gains an electron, and so behaves chemically as both a group 1 and a group 17 element.

Hydrogen (H) is the most abundant of the chemical elements, constituting roughly 75% of the universe's elemental mass.[1] Ionized hydrogen is just a proton. Stars in the main sequence are mainly composed of hydrogen in its plasma state. Elemental hydrogen is relatively rare on Earth, and is industrially produced from hydrocarbons such as methane. Hydrogen can form compounds with most elements and is present in water and most organic compounds.[2] Helium (He) exists only as a gas except in extreme conditions.[3] It is the second lightest element and is the second most abundant in the universe.[4] Most helium was formed during the Big Bang, but new helium is created through nuclear fusion of hydrogen in stars.[5] On Earth, helium is relatively rare, only occurring as a byproduct of the natural decay of some radioactive elements.[6] Such 'radiogenic' helium is trapped within natural gas in concentrations of up to seven percent by volume.[7]

Chemical elements in the second period Main article: Period 2 element Group 	1 	2 	13 	14 	15 	16 	17 	18 Name 	3 Li 	4 Be 	5 B 	6 C 	7 N 	8 O 	9 F 	10 Ne

Period 2 elements involve the 2s and 2p orbitals. They include the biologically most essential elements besides hydrogen: carbon, nitrogen, and oxygen.

Lithium (Li) is the lightest metal and the least dense solid element.[8] In its non-ionized state it is one of the most reactive elements, and so is only ever found naturally in compounds. It is the heaviest primordial element forged in large quantities during the Big Bang. Beryllium (Be) has one of the highest melting points of all the light metals. Small amounts of beryllium were synthesised during the Big Bang, although most of it decayed or reacted further within stars to create larger nucleii, like carbon, nitrogen or oxygen. Beryllium is classified by the International Agency for Research on Cancer as a group 1 carcinogen.[9] Between 1% and 15% of people are sensitive to beryllium and may develop an inflammatory reaction in their respiratory system and skin, called chronic beryllium disease.[10] Boron (B) does not occur naturally as a free element, but in compounds such as borates. It is an essential plant micronutrient, required for cell wall strength and development, cell division, seed and fruit development, sugar transport and hormone development,[11][12] though high levels are toxic. Carbon (C) is the fourth most abundant element in the universe by mass after hydrogen, helium and oxygen[13] and is the second most abundant element in the human body by mass after oxygen,[14] the third most abundant by number of atoms.[15] There are an almost infinite number of compounds that contain carbon due to carbon's ability to form long stable chains of C—C bonds.[16][17] All organic compounds, those essential for life, contain at least one atom of carbon;[16][17] combined with hydrogen, oxygen, nitrogen, sulfur, and phosphorus, carbon is the basis of every important biological compound.[17] Nitrogen (N) is found mainly as mostly inert diatomic gas, N2, which makes up 78% of the Earth's atmosphere. It is an essential component of proteins and therefore of life. Oxygen (O) comprising 21% of the atmosphere and is required for respiration by all (or nearly all) animals, as well as being the principal component of water. Oxygen is the third most abundant element in the universe, and oxygen compounds dominate the Earth's crust. Fluorine (F) is the most reactive element in its non-ionized state, and so is never found that way in nature. Neon (Ne) is a noble gas used in neon lighting.

Chemical elements in the third period Main article: Period 3 element Group 	1 	2 	13 	14 	15 	16 	17 	18 Name 	11 Na 	12 Mg 	13 Al 	14 Si 	15 P 	16 S 	17 Cl 	18 Ar

All period three elements occur in nature and have at least one stable isotope. All but the noble gas argon are essential to basic geology and biology.

Sodium (Na) is an alkali metal. It is present in Earth's oceans in large quantities in the form of sodium chloride (table salt). Magnesium (Mg) is an alkaline earth metal. Magnesium ions are found in chlorophyll. Aluminium (Al) is a poor metal. It is the most abundant metal in the Earth's crust. Silicon (Si) is a metalloid. It is a semiconductor, making it the principal component in many integrated circuits. Silicon dioxide is the principal constituent of sand. Phosphorus (P) is a nonmetal essential to DNA. It is highly reactive, and as such is never found in nature as a free element. Sulfur (S) is a nonmetal. It is found in two amino acids: cysteine and methionine. Chlorine (Cl) is a halogen. It is used as a disinfectant, especially in swimming pools. Argon (Ar) is a noble gas, making it almost entirely nonreactive. Incandescent lamps are often filled with noble gases such as argon in order to preserve the filaments at high temperatures.

Chemical elements in the fourth period Main article: Period 4 element Group 	1 	2 	3 	4 	5 	6 	7 	8 	9 	10 	11 	12 	13 	14 	15 	16 	17 	18 Atomic number Name 	19 K 	20 Ca 	21 Sc 	22 Ti 	23 V 	24 Cr 	25 Mn 	26 Fe 	27 Co 	28 Ni 	29 Cu 	30 Zn 	31 Ga 	32 Ge 	33 As 	34 Se 	35 Br 	36 Kr From left to right, aqueous solutions of: Co(NO3)2 (red); K2Cr2O7 (orange); K2CrO4 (yellow); NiCl2 (green); CuSO4 (blue); KMnO4 (purple).

Period 4 includes the biologically essential elements potassium and calcium, and is the first period in the d-block with the lighter transition metals. These include iron, the heaviest element forged in main-sequence stars and a principal component of the earth, as well as other important metals such as cobalt, nickel, copper, and zinc. Almost all have biological roles. Chemical elements in the fifth period Main article: Period 5 element Group 	1 	2 	3 	4 	5 	6 	7 	8 	9 	10 	11 	12 	13 	14 	15 	16 	17 	18 Atomic number Name 	37 Rb 	38 Sr 	39 Y 	40 Zr 	41 Nb 	42 Mo 	43 Tc 	44 Ru 	45 Rh 	46 Pd 	47 Ag 	48 Cd 	49 In 	50 Sn 	51 Sb 	52 Te 	53 I 	54 Xe

Period 5 contains the heaviest few elements that have biological roles, molybdenum and iodine. (Tungsten, a period 6 element, is the only heavier element that has a biological role.) It includes technetium, the lightest exclusively radioactive element. Chemical elements in the sixth period Main article: Period 6 element Group 	1 	2 	3 (Lanthanides) 	4 	5 	6 	7 	8 	9 	10 	11 	12 	13 	14 	15 	16 	17 	18 Name 	55 Cs 	56 Ba 	57 La 	58 Ce 	59 Pr 	60 Nd 	61 Pm 	62 Sm 	63 Eu 	64 Gd 	65 Tb 	66 Dy 	67 Ho 	68 Er 	69 Tm 	70 Yb 	71 Lu 	72 Hf 	73 Ta 	74 W 	75 Re 	76 Os 	77 Ir 	78 Pt 	79 Au 	80 Hg 	81 Tl 	82 Pb 	83 Bi 	84 Po 	85 At 	86 Rn

Period 6 is the first period to include the f-block, with the lanthanides (also known as the rare earth elements), and includes the heaviest stable elements. Many of these heavy metals are toxic and some are radioactive, but platinum and gold are largely inert. Chemical elements in the seventh period Main article: Period 7 element Group 	1 	2 	3 (Actinides) 	4 	5 	6 	7 	8 	9 	10 	11 	12 	13 	14 	15 	16 	17 	18 Name 	87 Fr 	88 Ra 	89 Ac 	90 Th 	91 Pa 	92 U 	93 Np 	94 Pu 	95 Am 	96 Cm 	97 Bk 	98 Cf 	99 Es 	100 Fm 	101 Md 	102 No 	103 Lr 	104 Rf 	105 Db 	106 Sg 	107 Bh 	108 Hs 	109 Mt 	110 Ds 	111 Rg 	112 Cn 	113 Uut 	114 Fl 	115 Uup 	116 Lv 	117 Uus 	118 Uuo

All elements of period 7 are radioactive. This period contains the heaviest element which occurs naturally on earth, californium. All of the subsequent elements in the period have been synthesized artificially. Whilst one of these (einsteinium) is now available in macroscopic quantities, most are extremely rare, having only been prepared in microgram amounts or less. Some of the later elements have only ever been identified in laboratories in quantities of a few atoms at a time.

Although the rarity of many of these elements means that experimental results are not very extensive, periodic and group trends in behaviour appear to be less well defined for period 7 than for other periods. Whilst francium and radium do show typical properties of Groups 1 and 2 respectively, the actinides display a much greater variety of behaviour and oxidation states than the lanthanides. Initial studies suggest Group 14 element flerovium appears to be a noble gas instead of a poor metal, and group 18 element ununoctium probably is not a noble gas.[18] These peculiarities of period 7 may be due to a variety of factors, including a large degree of spin-orbit coupling and relativistic effects, ultimately caused by the very high positive electrical charge from their massive atomic nuclei. Chemical elements in the eighth period Main article: Period 8 element Main article: Extended periodic table

No element of the eighth period has yet been synthesized. A g-block is predicted. It is not clear if all elements predicted for the eighth period are in fact physically possible. There may therefore be no ninth period.

Some element categories in the periodic table Metals 	Metalloids 	Nonmetals 	Unknown chemical properties Alkali metals 	Alkaline earth metals 	Inner transition metals 	Transition metals 	Post-transition metals 	Other nonmetals 	Halogens 	Noble gases Lanthanides 	Actinides [show]

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^ Palmer, David (November 13, 1997). "Hydrogen in the Universe". NASA. Retrieved 2008-02-05. ^ "hydrogen". Encyclopædia Britannica. 2008.   ^ "Helium: physical properties". WebElements. Retrieved 2008-07-15. ^ "Helium: geological information". WebElements. Retrieved 2008-07-15. ^ Cox, Tony (1990-02-03). "Origin of the chemical elements". New Scientist. Retrieved 2008-07-15. ^ "Helium supply deflated: production shortages mean some industries and partygoers must squeak by.". Houston Chronicle. 2006-11-05.   ^ Brown, David (2008-02-02). "Helium a New Target in New Mexico". American Association of Petroleum Geologists. Retrieved 2008-07-15. ^ Lithium at WebElements. ^ "IARC Monograph, Volume 58". International Agency for Research on Cancer. 1993. Retrieved 2008-09-18. ^ Information about chronic beryllium disease. ^ "Functions of Boron in Plant Nutrition" (PDF). U.S. Borax Inc.. ^ Blevins, Dale G.; Lukaszewski, Krystyna M. (1998). "Functions of Boron in Plant Nutrition". Annual Review of Plant Physiology and Plant Molecular Biology 49: 481–500. doi:10.1146/annurev.arplant.49.1.481. .   ^ Ten most abundant elements in the universe, taken from The Top 10 of Everything, 2006, Russell Ash, page 10. Retrieved October 15, 2008. ^ Chang, Raymond (2007). Chemistry, Ninth Edition. McGraw-Hill. pp. 52. ISBN 0-07-110595-6. ^ Freitas Jr., Robert A. (1999). Nanomedicine. Landes Bioscience. Tables 3-1 & 3-2. ISBN 1-57059-680-8. ^ a b "Structure and Nomenclature of Hydrocarbons". Purdue University. Retrieved 2008-03-23. ^ a b c Alberts, Bruce; Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, Peter Walter. Molecular Biology of the Cell. Garland Science. ^ See references in the articles Flerovium, Ununoctium

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Periodic table 1 	2 		3 	4 	5 	6 	7 	8 	9 	10 	11 	12 	13 	14 	15 	16 	17 	18 1 	H 		He 2 	Li 	Be 		B 	C 	N 	O 	F 	Ne 3 	Na 	Mg 		Al 	Si 	P 	S 	Cl 	Ar 4 	K 	Ca 		Sc 	Ti 	V 	Cr 	Mn 	Fe 	Co 	Ni 	Cu 	Zn 	Ga 	Ge 	As 	Se 	Br 	Kr 5 	Rb 	Sr 		Y 	Zr 	Nb 	Mo 	Tc 	Ru 	Rh 	Pd 	Ag 	Cd 	In 	Sn 	Sb 	Te 	I 	Xe 6 	Cs 	Ba 	La 	Ce 	Pr 	Nd 	Pm 	Sm 	Eu 	Gd 	Tb 	Dy 	Ho 	Er 	Tm 	Yb 	Lu 	Hf 	Ta 	W 	Re 	Os 	Ir 	Pt 	Au 	Hg 	Tl 	Pb 	Bi 	Po 	At 	Rn 7 	Fr 	Ra 	Ac 	Th 	Pa 	U 	Np 	Pu 	Am 	Cm 	Bk 	Cf 	Es 	Fm 	Md 	No 	Lr 	Rf 	Db 	Sg 	Bh 	Hs 	Mt 	Ds 	Rg 	Cn 	Uut 	Fl 	Uup 	Lv 	Uus 	Uuo Alkali metal 	Alkaline earth metal 	Lanthanide 	Actinide 	Transition metal 	Post-transition metal 	Metalloid 	Other nonmetal 	Halogen 	Noble gas 	Unknown chemical properties Large version Help improve this page What's this?

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