Atomic Number 5

Fundamental properties of atoms including atomic number and atomic mass. The atomic number is the number of protons in an atom, and isotopes have the same atomic number but differ in the number of neutrons. Atomic Number of Elements from 1 to 50. List of first 50 elements of the periodic table by atomic number including the chemical symbol and the atomic weight. You can print the list of elements by hitting the print button below. Atomic number: 5 Relative atomic mass: 10.81 State at 20°C: Solid Key isotopes 11 B Electron configuration He 2s 2 2p 1 CAS number: 7440-42-8 ChemSpider ID: 4575371: ChemSpider is a free chemical structure database. Crossword Clue The crossword clue Element with atomic number 5 with 5 letters was last seen on the January 01, 2009.We think the likely answer to this clue is BORON.Below are all possible answers to this clue ordered by its rank. You can easily improve your search by specifying the number.

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No.		Atomic weight	Name	Sym.	M.P. (°C)	B.P. (°C)	Density* (g/cm³)	Earth crust (%)*	Discovery (Year)	Group*	Electron configuration	Ionization energy (eV)
1	1.008	Hydrogen	H	-259	-253	0.09	0.14	1776	1	1s¹	13.60
2	4.003	Helium	He	-272	-269	0.18	1895	18	1s²	24.59
3	6.941	Lithium	Li	180	1,347	0.53	1817	1	[He] 2s¹	5.39
4	9.012	Beryllium	Be	1,278	2,970	1.85	1797	2	[He] 2s²	9.32
5	10.811	Boron	B	2,300	2,550	2.34	1808	13	[He] 2s² 2p¹	8.30
6	12.011	Carbon	C	3,500	4,827	2.26	0.09	ancient	14	[He] 2s² 2p²	11.26
7	14.007	Nitrogen	N	-210	-196	1.25	1772	15	[He] 2s² 2p³	14.53
8	15.999	Oxygen	O	-218	-183	1.43	46.71	1774	16	[He] 2s² 2p⁴	13.62
9	18.998	Fluorine	F	-220	-188	1.70	0.03	1886	17	[He] 2s² 2p⁵	17.42
10	20.180	Neon	Ne	-249	-246	0.90	1898	18	[He] 2s² 2p⁶	21.56
11	22.990	Sodium	Na	98	883	0.97	2.75	1807	1	[Ne] 3s¹	5.14
12	24.305	Magnesium	Mg	639	1,090	1.74	2.08	1755	2	[Ne] 3s²	7.65
13	26.982	Aluminum	Al	660	2,467	2.70	8.07	1825	13	[Ne] 3s² 3p¹	5.99
14	28.086	Silicon	Si	1,410	2,355	2.33	27.69	1824	14	[Ne] 3s² 3p²	8.15
15	30.974	Phosphorus	P	44	280	1.82	0.13	1669	15	[Ne] 3s² 3p³	10.49
16	32.065	Sulfur	S	113	445	2.07	0.05	ancient	16	[Ne] 3s² 3p⁴	10.36
17	35.453	Chlorine	Cl	-101	-35	3.21	0.05	1774	17	[Ne] 3s² 3p⁵	12.97
18	39.948	Argon	Ar	-189	-186	1.78	1894	18	[Ne] 3s² 3p⁶	15.76
19	39.098	Potassium	K	64	774	0.86	2.58	1807	1	[Ar] 4s¹	4.34
20	40.078	Calcium	Ca	839	1,484	1.55	3.65	1808	2	[Ar] 4s²	6.11
21	44.956	Scandium	Sc	1,539	2,832	2.99	1879	3	[Ar] 3d¹ 4s²	6.56
22	47.867	Titanium	Ti	1,660	3,287	4.54	0.62	1791	4	[Ar] 3d² 4s²	6.83
23	50.942	Vanadium	V	1,890	3,380	6.11	1830	5	[Ar] 3d³ 4s²	6.75
24	51.996	Chromium	Cr	1,857	2,672	7.19	0.04	1797	6	[Ar] 3d⁵ 4s¹	6.77
25	54.938	Manganese	Mn	1,245	1,962	7.43	0.09	1774	7	[Ar] 3d⁵ 4s²	7.43
26	55.845	Iron	Fe	1,535	2,750	7.87	5.05	ancient	8	[Ar] 3d⁶ 4s²	7.90
27	58.933	Cobalt	Co	1,495	2,870	8.90	1735	9	[Ar] 3d⁷ 4s²	7.88
28	58.693	Nickel	Ni	1,453	2,732	8.90	0.02	1751	10	[Ar] 3d⁸ 4s²	7.64
29	63.546	Copper	Cu	1,083	2,567	8.96	ancient	11	[Ar] 3d¹⁰ 4s¹	7.73
30	65.390	Zinc	Zn	420	907	7.13	ancient	12	[Ar] 3d¹⁰ 4s²	9.39
31	69.723	Gallium	Ga	30	2,403	5.91	1875	13	[Ar] 3d¹⁰ 4s² 4p¹	6.00
32	72.640	Germanium	Ge	937	2,830	5.32	1886	14	[Ar] 3d¹⁰ 4s² 4p²	7.90
33	74.922	Arsenic	As	81	613	5.72	ancient	15	[Ar] 3d¹⁰ 4s² 4p³	9.79
34	78.960	Selenium	Se	217	685	4.79	1817	16	[Ar] 3d¹⁰ 4s² 4p⁴	9.75
35	79.904	Bromine	Br	-7	59	3.12	1826	17	[Ar] 3d¹⁰ 4s² 4p⁵	11.81
36	83.800	Krypton	Kr	-157	-153	3.75	1898	18	[Ar] 3d¹⁰ 4s² 4p⁶	14.00
37	85.468	Rubidium	Rb	39	688	1.63	1861	1	[Kr] 5s¹	4.18
38	87.620	Strontium	Sr	769	1,384	2.54	1790	2	[Kr] 5s²	5.69
39	88.906	Yttrium	Y	1,523	3,337	4.47	1794	3	[Kr] 4d¹ 5s²	6.22
40	91.224	Zirconium	Zr	1,852	4,377	6.51	0.03	1789	4	[Kr] 4d² 5s²	6.63
41	92.906	Niobium	Nb	2,468	4,927	8.57	1801	5	[Kr] 4d⁴ 5s¹	6.76
42	95.940	Molybdenum	Mo	2,617	4,612	10.22	1781	6	[Kr] 4d⁵ 5s¹	7.09
43	*	98.000	Technetium	Tc	2,200	4,877	11.50	1937	7	[Kr] 4d⁵ 5s²	7.28
44	101.070	Ruthenium	Ru	2,250	3,900	12.37	1844	8	[Kr] 4d⁷ 5s¹	7.36
45	102.906	Rhodium	Rh	1,966	3,727	12.41	1803	9	[Kr] 4d⁸ 5s¹	7.46
46	106.420	Palladium	Pd	1,552	2,927	12.02	1803	10	[Kr] 4d¹⁰	8.34
47	107.868	Silver	Ag	962	2,212	10.50	ancient	11	[Kr] 4d¹⁰ 5s¹	7.58
48	112.411	Cadmium	Cd	321	765	8.65	1817	12	[Kr] 4d¹⁰ 5s²	8.99
49	114.818	Indium	In	157	2,000	7.31	1863	13	[Kr] 4d¹⁰ 5s² 5p¹	5.79
50	118.710	Tin	Sn	232	2,270	7.31	ancient	14	[Kr] 4d¹⁰ 5s² 5p²	7.34
51	121.760	Antimony	Sb	630	1,750	6.68	ancient	15	[Kr] 4d¹⁰ 5s² 5p³	8.61
52	127.600	Tellurium	Te	449	990	6.24	1783	16	[Kr] 4d¹⁰ 5s² 5p⁴	9.01
53	126.905	Iodine	I	114	184	4.93	1811	17	[Kr] 4d¹⁰ 5s² 5p⁵	10.45
54	131.293	Xenon	Xe	-112	-108	5.90	1898	18	[Kr] 4d¹⁰ 5s² 5p⁶	12.13
55	132.906	Cesium	Cs	29	678	1.87	1860	1	[Xe] 6s¹	3.89
56	137.327	Barium	Ba	725	1,140	3.59	0.05	1808	2	[Xe] 6s²	5.21
57	138.906	Lanthanum	La	920	3,469	6.15	1839	3	[Xe] 5d¹ 6s²	5.58
58	140.116	Cerium	Ce	795	3,257	6.77	1803	101	[Xe] 4f¹ 5d¹ 6s²	5.54
59	140.908	Praseodymium	Pr	935	3,127	6.77	1885	101	[Xe] 4f³ 6s²	5.47
60	144.240	Neodymium	Nd	1,010	3,127	7.01	1885	101	[Xe] 4f⁴ 6s²	5.53
61	*	145.000	Promethium	Pm	1,100	3,000	7.30	1945	101	[Xe] 4f⁵ 6s²	5.58
62	150.360	Samarium	Sm	1,072	1,900	7.52	1879	101	[Xe] 4f⁶ 6s²	5.64
63	151.964	Europium	Eu	822	1,597	5.24	1901	101	[Xe] 4f⁷ 6s²	5.67
64	157.250	Gadolinium	Gd	1,311	3,233	7.90	1880	101	[Xe] 4f⁷ 5d¹ 6s²	6.15
65	158.925	Terbium	Tb	1,360	3,041	8.23	1843	101	[Xe] 4f⁹ 6s²	5.86
66	162.500	Dysprosium	Dy	1,412	2,562	8.55	1886	101	[Xe] 4f¹⁰ 6s²	5.94
67	164.930	Holmium	Ho	1,470	2,720	8.80	1867	101	[Xe] 4f¹¹ 6s²	6.02
68	167.259	Erbium	Er	1,522	2,510	9.07	1842	101	[Xe] 4f¹² 6s²	6.11
69	168.934	Thulium	Tm	1,545	1,727	9.32	1879	101	[Xe] 4f¹³ 6s²	6.18
70	173.040	Ytterbium	Yb	824	1,466	6.90	1878	101	[Xe] 4f¹⁴ 6s²	6.25
71	174.967	Lutetium	Lu	1,656	3,315	9.84	1907	101	[Xe] 4f¹⁴ 5d¹ 6s²	5.43
72	178.490	Hafnium	Hf	2,150	5,400	13.31	1923	4	[Xe] 4f¹⁴ 5d² 6s²	6.83
73	180.948	Tantalum	Ta	2,996	5,425	16.65	1802	5	[Xe] 4f¹⁴ 5d³ 6s²	7.55
74	183.840	Tungsten	W	3,410	5,660	19.35	1783	6	[Xe] 4f¹⁴ 5d⁴ 6s²	7.86
75	186.207	Rhenium	Re	3,180	5,627	21.04	1925	7	[Xe] 4f¹⁴ 5d⁵ 6s²	7.83
76	190.230	Osmium	Os	3,045	5,027	22.60	1803	8	[Xe] 4f¹⁴ 5d⁶ 6s²	8.44
77	192.217	Iridium	Ir	2,410	4,527	22.40	1803	9	[Xe] 4f¹⁴ 5d⁷ 6s²	8.97
78	195.078	Platinum	Pt	1,772	3,827	21.45	1735	10	[Xe] 4f¹⁴ 5d⁹ 6s¹	8.96
79	196.967	Gold	Au	1,064	2,807	19.32	ancient	11	[Xe] 4f¹⁴ 5d¹⁰ 6s¹	9.23
80	200.590	Mercury	Hg	-39	357	13.55	ancient	12	[Xe] 4f¹⁴ 5d¹⁰ 6s²	10.44
81	204.383	Thallium	Tl	303	1,457	11.85	1861	13	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p¹	6.11
82	207.200	Lead	Pb	327	1,740	11.35	ancient	14	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p²	7.42
83	208.980	Bismuth	Bi	271	1,560	9.75	ancient	15	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p³	7.29
84	*	209.000	Polonium	Po	254	962	9.30	1898	16	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p⁴	8.42
85	*	210.000	Astatine	At	302	337	0.00	1940	17	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p⁵	9.30
86	*	222.000	Radon	Rn	-71	-62	9.73	1900	18	[Xe] 4f¹⁴ 5d¹⁰ 6s² 6p⁶	10.75
87	*	223.000	Francium	Fr	27	677	0.00	1939	1	[Rn] 7s¹	4.07
88	*	226.000	Radium	Ra	700	1,737	5.50	1898	2	[Rn] 7s²	5.28
89	*	227.000	Actinium	Ac	1,050	3,200	10.07	1899	3	[Rn] 6d¹ 7s²	5.17
90	232.038	Thorium	Th	1,750	4,790	11.72	1829	102	[Rn] 6d² 7s²	6.31
91	231.036	Protactinium	Pa	1,568	0	15.40	1913	102	[Rn] 5f² 6d¹ 7s²	5.89
92	238.029	Uranium	U	1,132	3,818	18.95	1789	102	[Rn] 5f³ 6d¹ 7s²	6.19
93	*	237.000	Neptunium	Np	640	3,902	20.20	1940	102	[Rn] 5f⁴ 6d¹ 7s²	6.27
94	*	244.000	Plutonium	Pu	640	3,235	19.84	1940	102	[Rn] 5f⁶ 7s²	6.03
95	*	243.000	Americium	Am	994	2,607	13.67	1944	102	[Rn] 5f⁷ 7s²	5.97
96	*	247.000	Curium	Cm	1,340	0	13.50	1944	102	5.99
97	*	247.000	Berkelium	Bk	986	0	14.78	1949	102	6.20
98	*	251.000	Californium	Cf	900	0	15.10	1950	102	6.28
99	*	252.000	Einsteinium	Es	860	0	0.00	1952	102	6.42
100	*	257.000	Fermium	Fm	1,527	0	0.00	1952	102	6.50
101	*	258.000	Mendelevium	Md	0	0	0.00	1955	102	6.58
102	*	259.000	Nobelium	No	827	0	0.00	1958	102	6.65
103	*	262.000	Lawrencium	Lr	1,627	0	0.00	1961	102	4.90
104	*	261.000	Rutherfordium	Rf	0	0	0.00	1964	4	0.00
105	*	262.000	Dubnium	Db	0	0	0.00	1967	5	0.00
106	*	266.000	Seaborgium	Sg	0	0	0.00	1974	6	0.00
107	*	264.000	Bohrium	Bh	0	0	0.00	1981	7	0.00
108	*	277.000	Hassium	Hs	0	0	0.00	1984	8	0.00
109	*	268.000	Meitnerium	Mt	0	0	0.00	1982	9	0.00
No.		Atomic weight	Name	Sym.	M.P. (°C)	B.P. (°C)	Density* (g/cm³)	Earth crust (%)*	Discovery (Year)	Group*	Electron configuration	Ionization energy (eV)

Notes:
• Density of elements with boiling points below 0°C is given in g/l. In a sorted list, these elements are shown before other elements that have boiling points >0°C.
• Earth crust composition average values are from a report by F. W. Clarke and H. S. Washington, 1924. Elemental composition of crustal rocks differ between different localities (see article).
• Group: There are only 18 groups in the periodic table that constitute the columns of the table. Lanthanoids and Actinoids are numbered as 101 and 102 to separate them in sorting by group.
• The elements marked with an asterisk (in the 2nd column) have no stable nuclides. For these elements the weight value shown represents the mass number of the longest-lived isotope of the element.

Abbreviations and Definitions:

No. - Atomic Number; M.P. - melting point; B.P. - boiling point

Atomic number: The number of protons in an atom. Each element is uniquely defined by its atomic number.

Atomic mass: The mass of an atom is primarily determined by the number of protons and neutrons in its nucleus. Atomic mass is measured in Atomic Mass Units (amu) which are scaled relative to carbon, ¹²C, that is taken as a standard element with an atomic mass of 12. This isotope of carbon has 6 protons and 6 neutrons. Thus, each proton and neutron has a mass of about 1 amu.

Isotope: Atoms of the same element with the same atomic number, but different number of neutrons. Isotope of an element is defined by the sum of the number of protons and neutrons in its nucleus. Elements have more than one isotope with varying numbers of neutrons. For example, there are two common isotopes of carbon, ¹²C and ¹³C which have 6 and 7 neutrons respectively. The abundances of different isotopes of elements vary in nature depending on the source of materials. For relative abundances of isotopes in nature see reference on Atomic Weights and Isotopic Compositions.

Atomic weight: Atomic weight values represent weighted average of the masses of all naturally occurring isotopes of an element. The values shown here are based on the IUPAC Commission determinations (Pure Appl. Chem. 73:667-683, 2001). The elements marked with an asterisk have no stable nuclides. For these elements the weight value shown represents the mass number of the longest-lived isotope of the element.

Electron configuration: See next page for explanation of electron configuration of atoms.

Ionization energy (IE): The energy required to remove the outermost electron from an atom or a positive ion in its ground level. The table lists only the first IE in eV units. To convert to kJ/mol multiply by 96.4869. Reference: NIST Reference Table on Ground states and ionization energies for the neutral atoms. IE decreases going down a column of the periodic table, and increases from left to right in a row. Thus, alkali metals have the lowest IE in a period and Rare gases have the highest.

Other resources related to the Periodic Table

Chemical Evolution of the Universe

Learning Objectives

List the properties of the three main subatomic particles.
Define atomic mass unit (amu).
Define atomic number and mass number.
Define isotopes.
Determine the number of protons, neutrons, and electrons in an atom with a given mass number.

The historical development of the different models of the atom’s structure is summarized in Figure (PageIndex{1}). J.J. Thomson and Robert Millikan conducted experiments to study the properties of electrons. Rutherford established that the nucleus of the hydrogen atom was a positively charged particle, for which he coined the name proton in 1920. He also suggested that the nuclei of elements other than hydrogen must contain electrically neutral particles with approximately the same mass as the proton. The neutron, however, was not discovered until 1932, when James Chadwick (1891–1974, a student of Rutherford; Nobel Prize in Physics, 1935) discovered it. As a result of Rutherford’s work, it became clear that an α particle contains two protons and neutrons, and is therefore the nucleus of a helium atom.

Figure (PageIndex{1}) A summary of the historical development of models of the components and structure of the atom. The dates in parentheses are the years in which the key experiments were performed. (CC BY-SA-NC).

Rutherford’s model of the atom is essentially the same as the modern model, except that it is now known that electrons are not uniformly distributed throughout an atom’s volume. Instead, they are distributed according to a set of principles described by Quantum Mechanics.

Figure (PageIndex{2}) shows how the model of the atom has evolved over time from the indivisible unit of Dalton to the modern view taught today.

Figure (PageIndex{2})The Evolution of Atomic Theory, as Illustrated by Models of the Oxygen Atom. Bohr’s model and the current model are described in Chapter 6, 'The Structure of Atoms.' Image used with Permission (CC BY-SA-NC).

The nucleus (plural, nuclei) is a positively charged region at the center of the atom. It consists of two types of subatomic particles packed tightly together. The particles are protons, which have a positive electric charge, and neutrons, which are neutral in electric charge. Outside of the nucleus, an atom is mostly empty space, with orbiting negative particles called electrons whizzing through it. Figure (PageIndex{3}) below shows these parts of the atom.

Figure (PageIndex{3}) The nuclear atom

The nucleus of the atom is extremely small. Its radius is only about 1/100,000 of the total radius of the atom. If an atom were the size of a football stadium, the nucleus would be about the size of a pea! Electrons have virtually no mass, but protons and neutrons have a lot of mass for their size. As a result, the nucleus has virtually all the mass of an atom. Given its great mass and tiny size, the nucleus is very dense. If an object the size of a penny had the same density as the nucleus of an atom, its mass would be greater than 30 million tons!

Holding It All Together

Particles with opposite electric charges attract each other. This explains why negative electrons orbit the positive nucleus. Particles with the same electric charge repel each other. This means that the positive protons in the nucleus push apart from one another. So why doesn't the nucleus fly apart? An even stronger force - called the strong nuclear force - holds protons and neutrons together in the nucleus.

Table (PageIndex{1}) gives the properties and locations of electrons, protons, and neutrons. The third column shows the masses of the three subatomic particles in 'atomic mass units.' An atomic mass unit ((text{amu})) is defined as one-twelfth the mass of a carbon-12 atom. Atomic mass units ((text{amu})) are useful, because, as you can see, the mass of a proton and the mass of a neutron are almost exactly (1) in this unit system.

Table (PageIndex{1}): Properties of Subatomic Particles
Particle	Symbol	Mass (amu)	Relative Mass (proton = 1)	Relative Charge	Location
proton	p⁺	1	1	+1	inside the nucleus
electron	e⁻	5.45× 10⁻⁴	0.00055	−1	outside nucleus
neutron	n⁰	1	1	0	inside the nucleus

amu in gram and kilogram

1 amu = 1.6605 × 10⁻²⁴g = 1.6605 × 10⁻²⁷kg

Atomic Number

Negative and positive charges of equal magnitude cancel each other out. This means that the negative charge on an electron perfectly balances the positive charge on the proton. In other words, a neutral atom must have exactly one electron for every proton. If a neutral atom has 1 proton, it must have 1 electron. If a neutral atom has 2 protons, it must have 2 electrons. If a neutral atom has 10 protons, it must have 10 electrons. You get the idea. In order to be neutral, an atom must have the same number of electrons and protons.

Scientists distinguish between different elements by counting the number of protons in the nucleus (Table (PageIndex{2})). If an atom has only one proton, we know it's a hydrogen atom. An atom with two protons is always a helium atom. If scientists count four protons in an atom, they know it's a beryllium atom. An atom with three protons is a lithium atom, an atom with five protons is a boron atom, an atom with six protons is a carbon atom . . . the list goes on.

Since an atom of one element can be distinguished from an atom of another element by the number of protons in its nucleus, scientists are always interested in this number, and how this number differs between different elements. The number of protons in an atom is called its atomic number ((Z)). This number is very important because it is unique for atoms of a given element. All atoms of an element have the same number of protons, and every element has a different number of protons in its atoms. For example, all helium atoms have two protons, and no other elements have atoms with two protons.

Table (PageIndex{2}): Atoms of the First Six Elements
Name	Protons	Neutrons	Electrons	Atomic Number (Z)	Mass Number(A)
Hydrogen	1	0	1	1	1
Helium	2	2	2	2	4
Lithium	3	4	3	3	7
Beryllium	4	5	4	4	9
Boron	5	6	5	5	11
Carbon	6	6	6	6	12

Of course, since neutral atoms have to have one electron for every proton, an element's atomic number also tells you how many electrons are in a neutral atom of that element. For example, hydrogen has an atomic number of 1. This means that an atom of hydrogen has one proton, and, if it's neutral, one electron as well. Gold, on the other hand, has an atomic number of 79, which means that an atom of gold has 79 protons, and, if it's neutral, 79 electrons as well.

Neutral Atoms

Atoms are neutral in electrical charge because they have the same number of negative electrons as positive protons (Table (PageIndex{2})). Therefore, the atomic number of an atom also tells you how many electrons the atom has. This, in turn, determines many of the atom's chemical properties.

Mass Number

The mass number ((A)) of an atom is the total number of protons and neutrons in its nucleus. The mass of the atom is a unit called the atomic mass unit (left( text{amu} right)). One atomic mass unit is the mass of a proton, or about (1.67 times 10^{-27}) kilograms, which is an extremely small mass. A neutron has just a tiny bit more mass than a proton, but its mass is often assumed to be one atomic mass unit as well. Because electrons have virtually no mass, just about all the mass of an atom is in its protons and neutrons. Therefore, the total number of protons and neutrons in an atom determines its mass in atomic mass units (Table (PageIndex{2})).

Consider helium again. Most helium atoms have two neutrons in addition to two protons. Therefore the mass of most helium atoms is 4 atomic mass units ((2 : text{amu}) for the protons + (2 : text{amu}) for the neutrons). However, some helium atoms have more or less than two neutrons. Atoms with the same number of protons but different numbers of neutrons are called isotopes. Because the number of neutrons can vary for a given element, the mass numbers of different atoms of an element may also vary. For example, some helium atoms have three neutrons instead of two (these are called isotopes and are discussed in detail later on)

Why do you think that the 'mass number' includes protons and neutrons, but not electrons? You know that most of the mass of an atom is concentrated in its nucleus. The mass of an atom depends on the number of protons and neutrons. You have already learned that the mass of an electron is very, very small compared to the mass of either a proton or a neutron (like the mass of a penny compared to the mass of a bowling ball). Counting the number of protons and neutrons tells scientists about the total mass of an atom. An atom's mass number is very easy to calculate provided you know the number of protons and neutrons in an atom. The mass number of a carbon atom with 6 protons and 7 neutrons is calculated and shown as follows:

[text{mass number} : A = left( text{number of protons} right) + left( text{number of neutrons} right)]

[text{mass number} = text{6} + text{6} = text{12}]

Example 4.5.1

What is the mass number of an atom of helium that contains 2 neutrons?

Solution

(left( text{number of protons} right) = 2) (Remember that an atom of helium always has 2 protons.)

(left( text{number of neutrons} right) = 2)

(text{mass number} = left( text{number of protons} right) + left( text{number of neutrons} right))

(text{mass number} = 2 + 2 = 4)

Isotopes

All atoms of the same element have the same number of protons, but some may have different numbers of neutrons. For example, all carbon atoms have six protons, and most have six neutrons as well. But some carbon atoms have seven or eight neutrons instead of the usual six. Atoms of the same element that differ in their numbers of neutrons are called isotopes. Many isotopes occur naturally. Usually one or two isotopes of an element are the most stable and common. Different isotopes of an element generally have the same physical and chemical properties. That's because they have the same numbers of protons and electrons.

An Example: Hydrogen Isotopes

Hydrogen is an example of an element that has isotopes. Three isotopes of hydrogen are modeled in Figure (PageIndex{4}). Most hydrogen atoms have just one proton and one electron and lack a neutron. These atoms are just called hydrogen. Some hydrogen atoms have one neutron as well. These atoms are the isotope named deuterium. Other hydrogen atoms have two neutrons. These atoms are the isotope named tritium.

Atomic Number 54

Figure (PageIndex{4}):The three most stable isotopes of hydrogen: protium (A = 1), deuterium (A = 2), and tritium (A = 3). (CC SA-BY 3.0; Balajijagadesh).

For most elements other than hydrogen, isotopes are named for their mass number. For example, carbon atoms with the usual 6 neutrons have a mass number of 12 (6 protons + 6 neutrons = 12), so they are called carbon-12. Carbon atoms with 7 neutrons have atomic mass of 13 (6 protons + 7 neutrons = 13). These atoms are the isotope called carbon-13.

Example (PageIndex{1}): Lithium Isotopes

What is the atomic number and the mass number of an isotope of lithium containing 3 neutrons.
What is the atomic number and the mass number of an isotope of lithium containing 4 neutrons?

Solution

A lithium atom contains 3 protons in its nucleus irrespective of the number of neutrons or electrons.

[ begin{align}text{atomic number} = left( text{number of protons} right) &= 3 nonumber left( text{number of neutrons} right) &= 3 nonumberend{align} nonumber ]

[ begin{align} text{mass number} & = left( text{number of protons} right) + left( text{number of neutrons} right) nonumber text{mass number} & = 3 + 3 nonumber &= 6 nonumber end{align}nonumber]

[ begin{align}text{atomic number} = left( text{number of protons} right) &= 3 nonumber left( text{number of neutrons} right) & = 4nonumberend{align}nonumber]

[ begin{align}text{mass number} & = left( text{number of protons} right) + left( text{number of neutrons} right)nonumber text{mass number} & = 3 + 4nonumber &= 7 nonumber end{align}nonumber]

Notice that because the lithium atom always has 3 protons, the atomic number for lithium is always 3. The mass number, however, is 6 in the isotope with 3 neutrons, and 7 in the isotope with 4 neutrons. In nature, only certain isotopes exist. For instance, lithium exists as an isotope with 3 neutrons, and as an isotope with 4 neutrons, but it doesn't exist as an isotope with 2 neutrons or as an isotope with 5 neutrons.

Symbols for Isotopes

There are two main ways in which scientists frequently show the mass number of an atom they are interested in. It is important to note that the mass number is not given on the periodic table. These two ways include writing a nuclear symbol or by giving the name of the element with the mass number written.

To write a nuclear symbol, the mass number is placed at the upper left (superscript) of the chemical symbol and the atomic number is placed at the lower left (subscript) of the symbol. The complete nuclear symbol for helium-4 is drawn below:

The following nuclear symbols are for a nickel nucleus with 31 neutrons and a uranium nucleus with 146 neutrons.

[ce{^{59}_{28}Ni}]

[ ce{ ^{238}_{92}U}]

In the nickel nucleus represented above, the atomic number 28 indicates the nucleus contains 28 protons, and therefore, it must contain 31 neutrons in order to have a mass number of 59. The uranium nucleus has 92 protons as do all uranium nuclei and this particular uranium nucleus has 146 neutrons.

Another way of representing isotopes is by adding a hyphen and the mass number to the chemical name or symbol. Thus the two nuclei would be Nickel-59 or Ni-59 and Uranium-238 or U-238, where 59 and 238 are the mass numbers of the two atoms, respectively. Note that the mass numbers (not the number of neutrons) are given to the side of the name.

Example (PageIndex{2}): POTASSIUM-40

How many protons, electrons, and neutrons are in an atom of (^{40}_{19}ce{K})?

Solution

Atomic Number 58

[text{atomic number} = left( text{number of protons} right) = 19]

For all atoms with no charge, the number of electrons is equal to the number of protons.

[text{number of electrons} = 19]

The mass number, 40 is the sum of the protons and the neutrons.

To find the number of neutrons, subtract the number of protons from the mass number.

[text{number of neutrons} = 40 - 19 = 21.]

Atomic Number 52

Example (PageIndex{3}): Zinc-65

How many protons, electrons, and neutrons are in an atom of zinc-65?

Solution

[text{number of protons} = 30]

For all atoms with no charge, the number of electrons is equal to the number of protons.

[text{number of electrons} = 30]

The mass number, 65 is the sum of the protons and the neutrons.

To find the number of neutrons, subtract the number of protons from the mass number.

[text{number of neutrons} = 65 - 30 = 35]

Exercise (PageIndex{1})

How many protons, electrons, and neutrons are in each atom?

(^{60}_{27}ce{Co})
Na-24
(^{45}_{20}ce{Ca})
Sr-90

Answer a:: 27 protons, 27 electrons, 33 neutrons
Answer b:: 11 protons, 11 electrons, 13 neutrons
Answer c:: 20 protons, 20 electrons, 25 neutrons
Answer d:: 38 protons, 38 electrons, 52 neutrons

The properties of the isotopes of hydrogen, helium, lithium, berrylium, boron, and carbon are in Table (PageIndex{3}).

Table (PageIndex{3}): Properties of Isotopes of the First Six Elements.
Element	Symbol	Atomic Number	Number of Protons	Number of Neutrons	Mass (amu)	% Natural Abundance
hydrogen	(ce{^1_1H}) (protium)	1	1	0	1.0078	99.989
	(ce{^2_1H}) (deuterium)	1	1	1	2.0141	0.0115
	(ce{^3_1H}) (tritium)	1	1	2	3.01605	— (trace)
helium	(ce{^3_2He})	2	2	1	3.01603	0.00013
helium	(ce{^4_2He})	2	2	2	4.0026	100
lithium	(ce{^6_3Li})	3	3	3	6.0151	7.59
lithium	(ce{^7_3Li})	3	3	4	7.0160	92.41
beryllium	(ce{^9_4Be})	4	4	5	9.0122	100
boron	(ce{^{10}_5B})	5	5	5	10.0129	19.9
boron	(ce{^{11}_5B})	5	5	6	11.0093	80.1
carbon	(ce{^{12}_6C})	6	6	6	12.0000	98.89
	(ce{^{13}_6C})	6	6	7	13.0034	1.11
	(ce{^{14}_6C})	6	6	8	14.0032	— (trace)

Summary

Atomic Number 56

The atom consists of discrete particles that govern its chemical and physical behavior.
Each atom of an element contains the same number of protons, which is the atomic number (Z).
Neutral atoms have the same number of electrons and protons.
Atoms of an element that contain different numbers of neutrons are called isotopes.
Each isotope of a given element has the same atomic number but a different mass number (A), which is the sum of the numbers of protons and neutrons.
The relative masses of atoms are reported using the atomic mass unit (amu) which is defined as one-twelfth of the mass of one atom of carbon-12, with 6 protons, 6 neutrons, and 6 electrons. The nuclear model of the atom consists of a small and dense positively charged interior surrounded by a cloud of electrons.

Atomic Number 57

Contributors and Attributions

Atomic Number 54

CK-12 Foundation by Sharon Bewick, Richard Parsons, Therese Forsythe, Shonna Robinson, and Jean Dupon.
Paul Flowers (University of North Carolina - Pembroke), Klaus Theopold (University of Delaware) and Richard Langley (Stephen F. Austin State University) with contributing authors. Textbook content produced by OpenStax College is licensed under a Creative Commons Attribution License 4.0 license. Download for free at http://cnx.org/contents/85abf193-2bd...a7ac8df6@9.110).
TextMap: Chemistry-The Central Science (Brown et al.)
Marisa Alviar-Agnew (Sacramento City College)
Henry Agnew (UC Davis)