Bromine Isotopes

Posted By admin On 02.05.21

Bromine (Br) has two stable isotopes and 30 known unstable isotopes, the most stable of which is 77 Br with a half-life of 57.036 hours Standard atomic mass: 79.904(1) u Table. Bromine has two stable isotopes, 79 Br and 81 Br, having relative mass abundances of 50.686% and 49.314%, respectively (Eggenkamp and Coleman, 2000). Variations in isotopic composition are reported as δ 81 Br (SMOB), where SMOB is standard mean oceanic bromide. Isotopes of Bromine (click to see decay chain): 67 Br 68 Br 69 Br 70 Br 71 Br 72 Br 73 Br 74 Br 75 Br 76 Br 77 Br 78 Br 79 Br 80 Br 81 Br 82 Br 83 Br 84 Br 85 Br 86 Br 87 Br 88 Br 89 Br 90 Br 91 Br 92 Br 93 Br 94 Br 95 Br 96 Br 97 Br. Isotopes Two naturally existing isotopes of bromine exist, bromine-79 and bromine-81. Isotopes are two or more forms of an element. Isotopes differ from each other according to their mass number. The number written to the right of the element's name is the mass number. The longest decaying fission product is a bromine isotope (Br-87) which has a 55.72 sec half-life (decay constant) for beta decay into stable isotopes of Sr-87 and Kr-86. The second group of delayed neutrons with the 23-second half-life (decay constant) is mainly composed of iodine (I-137) which has a 22-sec half-life, and forms an excited.

Bromine consists of two isotopes with masses of 78.92 and 80.92 amu. What is the abundances of these two isotopes?

1 Answer

Isotopes#color(white)(XX)#mass(amu)#color(white)(X)#Isotopic abundance

Br-79#color(white)(XXXX)#78.92#color(white)(XXXXXXX)#? Software you have to download for mac.

Br-81#color(white)(XXXX)#80.92#color(white)(XXXXXXX)#?

#'average atomic mass'=('mass*%'+'mass*%'+'mass*%'..)#

Let x be % abundance of Br-79

Let 1-x be % abundance of Br-81

Br is 79. 904g/mol on the periodic table#color(orange)'(average atomic mass)'#

#79.904%=x+(1-x)#

#79.904%=(78.92*x)+(80.92*(1-x))#

#79.904%=(78.92x)+(80.92-80.92x))# Onenote classroom permissions.

#79.904%=78.92x+80.92-80.92x#

#79.904%=-2x+80.92#

#79.904%-80.92=78.92x#

#-1.016=-2x#

#x=0.508#

Bromine Isotopes

Use our x to find that % abundance of Br-79

#x*100%#

#0.508*100%#

#=50.8##'%##abundance'#

Use our x to find that % abundance of Br-79

#(1-x)*100%#

#0.492*100%#

#=49.2##'%##abundance'#

#:.# The % abundance of the isotope with a mass of 78.92 amu has a % abundance of 50.8% and the isotope with a mass 80.92 amu has a % abundance of 49.2%

Related questions

Isotopes of the Element Bromine

[Click for Main Data]

Most of the isotope data on this site has been obtained from the National Nuclear Data Center. Please visit their site for more information.

Bromine 81

Isotopes With A Known Natural Abundance

Mass Number	Natural Abundance	Half-life
79	50.69%	STABLE
81	49.31%	STABLE

WebElements Periodic Table » Bromine » Isotope Data

Known Isotopes

Mass Number	Half-life	Decay Mode	Branching Percentage
67	No Data Available	Proton Emission (suspected)	No Data Available
68	1.2 microseconds	Proton Emission (suspected)	No Data Available
69	24 nanoseconds	Proton Emission (suspected)	No Data Available
70	79.1 milliseconds	Electron Capture	100.00%
70_m	2.2 seconds	Electron Capture	100.00%
71	21.4 seconds	Electron Capture	100.00%
72	78.6 seconds	Electron Capture	100.00%
72_m	10.6 seconds	Isomeric Transition	100.00%
Electron Capture	No Data Available
73	3.4 minutes	Electron Capture	100.00%
74	25.4 minutes	Electron Capture	100.00%
74_m	46 minutes	Electron Capture	100.00%
75	96.7 minutes	Electron Capture	100.00%
76	16.2 hours	Electron Capture	100.00%
76_m	1.31 seconds	Isomeric Transition	> 99.40%
Electron Capture	< 0.60%
77	57.036 hours	Electron Capture	100.00%
77_m	4.28 minutes	Isomeric Transition	100.00%
78	6.45 minutes	Electron Capture	>= 99.99%
Beta-minus Decay	<= 0.01%
79	STABLE	-	-
79_m	5.1 seconds	Isomeric Transition	100.00%
80	17.68 minutes	Beta-minus Decay	91.70%
Electron Capture	8.30%
80_m	4.4205 hours	Isomeric Transition	100.00%
81	STABLE	-	-
82	35.282 hours	Beta-minus Decay	100.00%
82_m	6.13 minutes	Isomeric Transition	97.60%
Beta-minus Decay	2.40%
83	2.40 hours	Beta-minus Decay	100.00%
84	31.76 minutes	Beta-minus Decay	100.00%
84_m	6.0 minutes	Beta-minus Decay	100.00%
85	2.90 minutes	Beta-minus Decay	100.00%
86	55.1 seconds	Beta-minus Decay	100.00%
87	55.65 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	2.60%
88	16.29 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	6.58%
89	4.40 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	13.80%
90	1.91 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	25.20%
91	0.541 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	20.00%
92	0.343 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	33.10%
93	102 milliseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	68.00%
94	70 milliseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	68.00%
95	>= 150 nanoseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	34.00%
96	>= 150 nanoseconds	Beta-minus Decay with delayed Neutron Emission	27.60%
Beta-minus Decay	100.00%
97	> 300 nanoseconds	Beta-minus Decay	No Data Available
98	> 634 nanoseconds	Beta-minus Decay	No Data Available
Beta-minus Decay with delayed Neutron Emission	No Data Available
Beta-minus Decay with delayed Double Neutron Emission	No Data Available

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