Isotopes of iodine

"Radioiodine" redirects here. For other uses, see Radioiodine (disambiguation).

A Pheochromocytoma is seen as a dark sphere in the center of the body (it is in the left adrenal gland). Image is by MIBG scintigraphy, with radiation from radioiodine in the MIBG. Two images are seen of the same patient from front and back. Note the dark image of the thyroid due to unwanted uptake of radioiodine from the medication by the thyroid gland in the neck. Accumulation at the sides of the head is from salivary gland uptake of iodide. Radioactivity is also seen in the bladder.

There are 37 known isotopes of iodine (I) from ¹⁰⁸I to ¹⁴⁴I; all undergo radioactive decay except ¹²⁷I, which is stable. Iodine is thus a monoisotopic element.

Its longest-lived radioactive isotope, ¹²⁹I, has a half-life of 15.7 million years, which is far too short for it to exist as a primordial nuclide. Cosmogenic sources of ¹²⁹I produce very tiny quantities of it that are too small to affect atomic weight measurements; iodine is thus also a mononuclidic element—one that is found in nature only as a single nuclide. Most ¹²⁹I derived radioactivity on Earth is man-made, an unwanted long-lived byproduct of early nuclear tests and nuclear fission accidents.

All other iodine radioisotopes have half-lives less than 60 days, and four of these are used as tracers and therapeutic agents in medicine. These are ¹²³I, ¹²⁴I, ¹²⁵I, and ¹³¹I. All industrial production of radioactive iodine isotopes involves these four useful radionuclides.

The isotope ¹³⁵I has a half-life less than seven hours, which is too short to be used in biology. Unavoidable in situ production of this isotope is important in nuclear reactor control, as it decays to ¹³⁵Xe, the most powerful known neutron absorber, and the nuclide responsible for the so-called iodine pit phenomenon.

In addition to commercial production, ¹³¹I (half-life 8 days) is one of the common radioactive fission-products of nuclear fission, and is thus produced inadvertently in very large amounts inside nuclear reactors. Due to its volatility, short half-life, and high abundance in fission products, ¹³¹I, (along with the short-lived iodine isotope ¹³²I from the longer-lived ¹³²Te with a half-life of 3 days) is responsible for the largest part of radioactive contamination during the first week after accidental environmental contamination from the radioactive waste from a nuclear power plant.

The relative atomic mass of iodine is 126.90447(3).

The portion of the total radiation activity (in air) contributed by each isotope versus time after the Chernobyl disaster, at the site. Note the prominence of radiation from I-131 and Te-132/I-132 for the first week. (Image using data from the OECD report, and the second edition of 'The radiochemical manual'.^[1])

Notable radioisotopes

Iodine-129 as an extinct radionuclide

Main article: Iodine-129

Excesses of stable ¹²⁹Xe in meteorites have been shown to result from decay of "primordial" iodine-129 produced newly by the supernovas that created the dust and gas from which the solar system formed. This isotope has long decayed and is thus referred to as "extinct". Historically, ¹²⁹I was the first extinct radionuclide to be identified as present in the early solar system. Its decay is the basis of the I-Xe iodine-xenon radiometric dating scheme, which covers the first 85 million years of solar system evolution.

Iodine-129 as a long-lived marker for nuclear fission contamination

Iodine-129 (¹²⁹I; half-life 15.7 million years) is a product of cosmic ray spallation on various isotopes of xenon in the atmosphere, in cosmic ray muon interaction with tellurium-130, and also uranium and plutonium fission, both in subsurface rocks and nuclear reactors. Artificial nuclear processes, in particular nuclear fuel reprocessing and atmospheric nuclear weapons tests, have now swamped the natural signal for this isotope. Nevertheless, it now serves as a groundwater tracer as indicator of nuclear waste dispersion into the natural environment. In a similar fashion, ¹²⁹I was used in rainwater studies to track fission products following the Chernobyl disaster.

In some ways, ¹²⁹I is similar to ³⁶Cl. It is a soluble halogen, fairly non-reactive, exists mainly as a non-sorbing anion, and is produced by cosmogenic, thermonuclear, and in-situ reactions. In hydrologic studies, ¹²⁹I concentrations are usually reported as the ratio of ¹²⁹I to total I (which is virtually all ¹²⁷I). As is the case with ³⁶Cl/Cl, ¹²⁹I/I ratios in nature are quite small, 10⁻¹⁴ to 10⁻¹⁰ (peak thermonuclear ¹²⁹I/I during the 1960s and 1970s reached about 10⁻⁷). ¹²⁹I differs from ³⁶Cl in that its half-life is longer (15.7 vs. 0.301 million years), it is highly biophilic, and occurs in multiple ionic forms (commonly, I⁻ and IO₃⁻), which have different chemical behaviors. This makes it fairly easy for ¹²⁹I to enter the biosphere as it becomes incorporated into vegetation, soil, milk, animal tissue, etc.

Radioiodines I-123, I-124, I-125, and I-131 in medicine and biology

Of the many isotopes of iodine, only two are typically used in a medical setting: iodine-123 and iodine-131. Since ¹³¹I has both a beta and gamma decay mode, it can be used for radiotherapy or for imaging. ¹²³I, which has no beta activity, is more suited for imaging (such as CT scans using iodinated contrast imaging) and less damaging internally to the patient. There are some situations in which iodine-124 and iodine-125 are used in medicine, also.^[2]

Due to preferential uptake of iodine by the thyroid, radioiodine is extensively used in imaging of and, in the case of I-131, destroying dysfunctional thyroid tissues. Other types of tissue selectively take up certain iodine-131-containing tissue-targeting and killing radiopharmaceutical agents (such as MIBG). Iodine-125 is the only other iodine radioisotope used in radiation therapy, but only as an implanted capsule in brachytherapy, where the isotope never has a chance to be released for chemical interaction with the body's tissues.

Iodine-131

Main article: Iodine-131

Iodine-131 (I¹³¹) is a beta-emitting isotope with a half-life of eight days, and comparatively energetic (190 keV average and 606 keV maximum energy) beta radiation, which penetrates 0.6 to 2.0 mm from the site of uptake. This beta radiation can be used for the destruction of thyroid nodules or hyperfunctioning thyroid tissue and for elimination of remaining thyroid tissue after surgery for the treatment of Graves' disease. The purpose of this therapy, which was first explored by Dr. Saul Hertz in 1941,^[3] is to destroy thyroid tissue that could not be removed surgically. In this procedure, I¹³¹ is administered either intravenously or orally following a diagnostic scan. This procedure may also be used, with higher doses of radio-iodine, to treat patients with thyroid cancer.

The I¹³¹ is taken up into thyroid tissue and concentrated there. The beta particles emitted by the radioisotope destroys the associated thyroid tissue with little damage to surrounding tissues (more than 2.0 mm from the tissues absorbing the iodine). Due to similar destruction, I¹³¹ is the iodine radioisotope used in other water-soluble iodine-labeled radiopharmaceuticals (such as MIBG) used therapeutically to destroy tissues.

The high energy beta radiation (up to 606 keV) from I¹³¹ causes it to be the most carcinogenic of the iodine isotopes. It is thought to cause the majority of excess thyroid cancers seen after nuclear fission contamination (such as bomb fallout or severe nuclear reactor accidents like the Chernobyl disaster) However, these epidemiological effects are seen primarily in children, and treatment of adults and children with therapeutic I¹³¹, and epidemiology of adults exposed to low-dose I¹³¹ has not demonstrated carcinogenicity.^[4]

Iodine-123 and iodine-125

Main articles: Iodine-123 and Iodine-125

The gamma-emitting isotopes iodine-123 (half-life 13 hours), and (less commonly) the longer-lived and less energetic iodine-125 (half-life 59 days) are used as nuclear imaging tracers to evaluate the anatomic and physiologic function of the thyroid. Abnormal results may be caused by disorders such as Graves' disease or Hashimoto's thyroiditis. Both isotopes decay by electron capture (EC) to the corresponding tellurium nuclides, but in neither case are these the metastable nuclides Te-123m and Te125m (which are of higher energy, and are not produced from radioiodine). Instead, the excited tellurium nuclides decay immediately (half-life too short to detect). Following EC, the excited Te-123 from I-123 emits a high-speed 127 keV internal conversion electron (not a beta ray) about 13% of the time, but this does little cellular damage due to the nuclide's short half-life and the relatively small fraction of such events. In the remainder of cases, a 159 keV gamma ray is emitted, which is well-suited for gamma imaging.

Excited Te-125 from EC decay of I-125 also emits a much lower-energy internal conversion electron (35.5 keV), which does relatively little damage due to its low energy, even though its emission is more common. The relatively low-energy gamma from I-125/Te-125 decay is poorly suited for imaging, but can still be seen, and this longer-lived isotope is necessary in tests that require several days of imaging, for example, fibrinogen scan imaging to detect blood clots.

Both I-123 and I-125 emit copious low energy Auger electrons after their decay, but these do not cause serious damage (double-stranded DNA breaks) in cells, unless the nuclide is incorporated into a medication that accumulates in the nucleus, or into DNA (this is never the case is clinical medicine, but it has been seen in experimental animal models).^[5]

Iodine-125 is also commonly used by radiation oncologists in low dose rate brachytherapy in the treatment of cancer at sites other than the thyroid, especially in prostate cancer. When I-125 is used therapeutically, it is encapsulated in titanium seeds and implanted in the area of the tumor, where it remains. The low energy of the gamma spectrum in this case limits radiation damage to tissues far from the implanted capsule. Iodine-125, due to its suitable longer half-life and less penetrating gamma spectrum, is also often preferred for laboratory tests that rely on iodine as a tracer that is counted by a gamma counter, such as in radioimmunoassaying.

Most medical imaging with iodine is done with a standard gamma camera. However, the gamma rays from iodine-123 and iodine-131 can also be seen by single photon emission computed tomography (SPECT) imaging.

Iodine-124

Main article: Iodine-124

Iodine-124 is a proton-rich isotope of iodine with a half-life of 4.18 days. Its modes of decay are: 74.4% electron capture, 25.6% positron emission. ¹²⁴I decays to ¹²⁴Te. Iodine-124 can be made by numereous nuclear reactions via a cyclotron. The most common starting material used is ¹²⁴Te.

Iodine-124 as the iodide salt can be used to directly image the thyroid using positron emission tomography (PET).^[6] Iodine-124 can also be used as a PET radiotracer with a usefully longer half-life compared with fluorine-18^[7] In this use, the nuclide is chemically bonded to a pharmaceutical to form a positron-emitting radiopharmaceutical, and injected into the body, where again it is imaged by PET scan.

Iodine-135 and nuclear reactor control

Iodine-135 is an isotope of iodine with a half-life of 6.6 hours. It is an important isotope from the viewpoint of nuclear reactor physics. It is produced in relatively large amounts as a fission product, and decays to xenon-135, which is a nuclear poison with a very large thermal neutron cross section, which is a cause of multiple complications in the control of nuclear reactors. The process of buildup of xenon-135 from an accumulated iodine-135 can temporarily preclude a shut-down reactor from restarting. This is known as xenon-poisoning or "falling into an iodine pit".

Iodine-128 and other isotopes

Iodine fission-produced isotopes not discussed above (iodine-128, iodine-130, iodine-132, and iodine-133) have a half lives of a couple of hours or minutes, rendering them almost useless in other applicable areas. Those mentioned are neutron-rich and so go through beta decay to their xenon counterparts. Iodine-128 (25 min half-life) can decay to either tellurium-128 by electron capture, or to xenon-128 by beta decay. It has a specific radioactivity of 2.177 x 10⁶ TBq/g.

Non-radioactive iodide (I-127) as protection from unwanted radioiodine uptake by the thyroid

Colloquially, radioactive materials can be described as "hot," and non-radioactive materials can be described as "cold." There are instances in which cold iodide is administered to people in order to prevent the uptake of hot iodide by the thyroid gland. For example, blockade of thyroid iodine uptake with potassium iodide is used in nuclear medicine scintigraphy and therapy with some radioiodinated compounds that are not targeted to the thyroid, such as iobenguane (MIBG), which used to image or treat neural tissue tumors, or iodinated fibrinogen, which is used in fibrinogen scans to investigate clotting. These compounds contain iodine, but not in the iodide form. However, since they may be ultimately metabolized or break down to radioactive iodide, it is common to administer non-radioactive potassium iodide to insure that metabolites of these radiopharmaceuticals is not sequestered by thyroid gland and inadvertently administer a radiological dose to that tissue.

Potassium iodide has been distributed to populations exposed to nuclear fission accidents such as the Chernobyl disaster. The iodide solution SSKI, a saturated solution of potassium (K) iodide in water, has been used to block absorption of the radioiodine (it has no effect on other radioisotopes from fission). Tablets containing potassium iodide are now also manufactured and stocked in central disaster sites by some governments for this purpose. In theory, many harmful late-cancer effects of nuclear fallout might be prevented in this way, since an excess of thyroid cancers, presumably due to radioiodine uptake, is the only proven radioisotope contamination effect after a fission accident, or from contamination by fallout from an atomic bomb (prompt radiation from the bomb also causes other cancers, such as leukemias, directly). Taking large amounts of iodide saturates thyroid receptors and prevents uptake of most radioactive iodine-131 that may be present from fission product exposure (although it does not protect from other radioisotopes, nor from any other form of direct radiation). The protective effect of KI lasts approximately 24 hours, so must be dosed daily until a risk of significant exposure to radioiodines from fission products no longer exists.^[8]^[9] Iodine-131 (the most common radioiodine contaminant in fallout) also decays relatively rapidly with a half-life of eight days, so that 99.95% of the original radioiodine has vanished after three months.

Table

nuclide symbol	Z(p)	N(n)	isotopic mass (u)	half-life	decay mode(s)^[10]^{[n 1]}	daughter isotope(s)^{[n 2]}	nuclear spin	representative isotopic composition (mole fraction)	range of natural variation (mole fraction)
nuclide symbol	excitation energy			half-life	decay mode(s)^[10]^{[n 1]}	daughter isotope(s)^{[n 2]}	nuclear spin	representative isotopic composition (mole fraction)	range of natural variation (mole fraction)
¹⁰⁸I	53	55	107.94348(39)#	36(6) ms	α (90%)	¹⁰⁴Sb	(1)#
					β⁺ (9%)	¹⁰⁸Te
					p (1%)	¹⁰⁷Te
¹⁰⁹I	53	56	108.93815(11)	103(5) µs	p (99.5%)	¹⁰⁸Te	(5/2+)
¹⁰⁹I	53	56	108.93815(11)	103(5) µs	α (.5%)	¹⁰⁵Sb	(5/2+)
¹¹⁰I	53	57	109.93524(33)#	650(20) ms	β⁺ (83%)	¹¹⁰Te	1+#
					α (17%)	¹⁰⁶Sb
					β⁺, p (11%)	¹⁰⁹Sb
					β⁺, α (1.09%)	¹⁰⁶Sn
¹¹¹I	53	58	110.93028(32)#	2.5(2) s	β⁺ (99.92%)	¹¹¹Te	(5/2+)#
¹¹¹I	53	58	110.93028(32)#	2.5(2) s	α (.088%)	¹⁰⁷Sb	(5/2+)#
¹¹²I	53	59	111.92797(23)#	3.42(11) s	β⁺ (99.01%)	¹¹²Te
					β⁺, p (.88%)	¹¹¹Sb
					β⁺, α (.104%)	¹⁰⁸Sn
					α (.0012%)	¹⁰⁸Sb
¹¹³I	53	60	112.92364(6)	6.6(2) s	β⁺ (100%)	¹¹³Te	5/2+#
					α (3.3×10⁻⁷%)	¹⁰⁹Sb
					β⁺, α	¹⁰⁹Sn
¹¹⁴I	53	61	113.92185(32)#	2.1(2) s	β⁺	¹¹⁴Te	1+
¹¹⁴I	53	61	113.92185(32)#	2.1(2) s	β⁺, p (rare)	¹¹³Sb	1+
^114mI	265.9(5) keV			6.2(5) s	β⁺ (91%)	¹¹⁴Te	(7)
^114mI	265.9(5) keV			6.2(5) s	IT (9%)	¹¹⁴I	(7)
¹¹⁵I	53	62	114.91805(3)	1.3(2) min	β⁺	¹¹⁵Te	(5/2+)#
¹¹⁶I	53	63	115.91681(10)	2.91(15) s	β⁺	¹¹⁶Te	1+
^116mI	400(50)# keV			3.27(16) µs			(7−)
¹¹⁷I	53	64	116.91365(3)	2.22(4) min	β⁺	¹¹⁷Te	(5/2)+
¹¹⁸I	53	65	117.913074(21)	13.7(5) min	β⁺	¹¹⁸Te	2−
^118mI	190.1(10) keV			8.5(5) min	β⁺	¹¹⁸Te	(7−)
^118mI	190.1(10) keV			8.5(5) min	IT (rare)	¹¹⁸I	(7−)
¹¹⁹I	53	66	118.91007(3)	19.1(4) min	β⁺	¹¹⁹Te	5/2+
¹²⁰I	53	67	119.910048(19)	81.6(2) min	β⁺	¹²⁰Te	2−
^120m1I	72.61(9) keV			228(15) ns			(1+,2+,3+)
^120m2I	320(15) keV			53(4) min	β⁺	¹²⁰Te	(7−)
¹²¹I	53	68	120.907367(11)	2.12(1) h	β⁺	¹²¹Te	5/2+
^121mI	2376.9(4) keV			9.0(15) µs
¹²²I	53	69	121.907589(6)	3.63(6) min	β⁺	¹²²Te	1+
¹²³I^{[n 3]}	53	70	122.905589(4)	13.2235(19) h	EC	¹²³Te	5/2+
¹²⁴I^{[n 3]}	53	71	123.9062099(25)	4.1760(3) d	β⁺	¹²⁴Te	2−
¹²⁵I^{[n 3]}	53	72	124.9046302(16)	59.400(10) d	EC	¹²⁵Te	5/2+
¹²⁶I	53	73	125.905624(4)	12.93(5) d	β⁺ (56.3%)	¹²⁶Te	2−
¹²⁶I	53	73	125.905624(4)	12.93(5) d	β⁻ (43.7%)	¹²⁶Xe	2−
¹²⁷I^{[n 4]}	53	74	126.904473(4)	Stable^{[n 5]}			5/2+	1.0000
¹²⁸I	53	75	127.905809(4)	24.99(2) min	β⁻ (93.1%)	¹²⁸Xe	1+
¹²⁸I	53	75	127.905809(4)	24.99(2) min	β⁺ (6.9%)	¹²⁸Te	1+
^128m1I	137.850(4) keV			845(20) ns			4−
^128m2I	167.367(5) keV			175(15) ns			(6)−
¹²⁹I^{[n 4]}^{[n 6]}	53	76	128.904988(3)	1.57(4)×10⁷ y	β⁻	¹²⁹Xe	7/2+	Trace^{[n 7]}
¹³⁰I	53	77	129.906674(3)	12.36(1) h	β⁻	¹³⁰Xe	5+
^130m1I	39.9525(13) keV			8.84(6) min	IT (84%)	¹³⁰I	2+
^130m1I	39.9525(13) keV			8.84(6) min	β⁻ (16%)	¹³⁰Xe	2+
^130m2I	69.5865(7) keV			133(7) ns			(6)−
^130m3I	82.3960(19) keV			315(15) ns			-
^130m4I	85.1099(10) keV			254(4) ns			(6)−
¹³¹I^{[n 4]}^{[n 3]}	53	78	130.9061246(12)	8.02070(11) d	β⁻	¹³¹Xe	7/2+
¹³²I	53	79	131.907997(6)	2.295(13) h	β⁻	¹³²Xe	4+
^132mI	104(12) keV			1.387(15) h	IT (86%)	¹³²I	(8−)
^132mI	104(12) keV			1.387(15) h	β⁻ (14%)	¹³²Xe	(8−)
¹³³I	53	80	132.907797(5)	20.8(1) h	β⁻	¹³³Xe	7/2+
^133m1I	1634.174(17) keV			9(2) s	IT	¹³³I	(19/2−)
^133m2I	1729.160(17) keV			~170 ns			(15/2−)
¹³⁴I	53	81	133.909744(9)	52.5(2) min	β⁻	¹³⁴Xe	(4)+
^134mI	316.49(22) keV			3.52(4) min	IT (97.7%)	¹³⁴I	(8)−
^134mI	316.49(22) keV			3.52(4) min	β⁻ (2.3%)	¹³⁴Xe	(8)−
¹³⁵I^{[n 8]}	53	82	134.910048(8)	6.57(2) h	β⁻	¹³⁵Xe	7/2+
¹³⁶I	53	83	135.91465(5)	83.4(10) s	β⁻	¹³⁶Xe	(1−)
^136mI	650(120) keV			46.9(10) s	β⁻	¹³⁶Xe	(6−)
¹³⁷I	53	84	136.917871(30)	24.13(12) s	β⁻ (92.86%)	¹³⁷Xe	(7/2+)
¹³⁷I	53	84	136.917871(30)	24.13(12) s	β⁻, n (7.14%)	¹³⁶Xe	(7/2+)
¹³⁸I	53	85	137.92235(9)	6.23(3) s	β⁻ (94.54%)	¹³⁸Xe	(2−)
¹³⁸I	53	85	137.92235(9)	6.23(3) s	β⁻, n (5.46%)	¹³⁷Xe	(2−)
¹³⁹I	53	86	138.92610(3)	2.282(10) s	β⁻ (90%)	¹³⁹Xe	7/2+#
¹³⁹I	53	86	138.92610(3)	2.282(10) s	β⁻, n (10%)	¹³⁸Xe	7/2+#
¹⁴⁰I	53	87	139.93100(21)#	860(40) ms	β⁻ (90.7%)	¹⁴⁰Xe	(3)(−#)
¹⁴⁰I	53	87	139.93100(21)#	860(40) ms	β⁻, n (9.3%)	¹³⁹Xe	(3)(−#)
¹⁴¹I	53	88	140.93503(21)#	430(20) ms	β⁻ (78%)	¹⁴¹Xe	7/2+#
¹⁴¹I	53	88	140.93503(21)#	430(20) ms	β⁻, n (22%)	¹⁴⁰Xe	7/2+#
¹⁴²I	53	89	141.94018(43)#	~200 ms	β⁻ (75%)	¹⁴²Xe	2−#
¹⁴²I	53	89	141.94018(43)#	~200 ms	β⁻, n (25%)	¹⁴¹Xe	2−#
¹⁴³I	53	90	142.94456(43)#	100# ms [> 300 ns]	β⁻	¹⁴³Xe	7/2+#
¹⁴⁴I	53	91	143.94999(54)#	50# ms [> 300 ns]	β⁻	¹⁴⁴Xe	1−#

↑ Abbreviations:
EC: Electron capture
IT: Isomeric transition
↑ Bold for stable isotopes, bold italics for nearly-stable isotopes (half-life longer than the age of the universe)
1 2 3 4 Has medical uses
1 2 3 Fission product
↑ Theoretically capable of spontaneous fission
↑ Can be used to date certain early events in Solar System history and some use for dating groundwater
↑ Cosmogenic nuclide, also found as nuclear contamination
↑ Produced as a decay product of ¹³⁵Te in nuclear reactors, in turn decays to ¹³⁵Xe, which, if allowed to build up, can shut down reactors due to the iodine pit phenomenon

Notes

Values marked # are not purely derived from experimental data, but at least partly from systematic trends. Spins with weak assignment arguments are enclosed in parentheses.
Uncertainties are given in concise form in parentheses after the corresponding last digits. Uncertainty values denote one standard deviation, except isotopic composition and standard atomic mass from IUPAC, which use expanded uncertainties.

References

Isotope masses from:
- G. Audi; A. H. Wapstra; C. Thibault; J. Blachot; O. Bersillon (2003). "The NUBASE evaluation of nuclear and decay properties" (PDF). Nuclear Physics A. 729: 3–128. Bibcode:2003NuPhA.729....3A. doi:10.1016/j.nuclphysa.2003.11.001.
Isotopic compositions and standard atomic masses from:
- J. R. de Laeter; J. K. Böhlke; P. De Bièvre; H. Hidaka; H. S. Peiser; K. J. R. Rosman; P. D. P. Taylor (2003). "Atomic weights of the elements. Review 2000 (IUPAC Technical Report)". Pure and Applied Chemistry. 75 (6): 683–800. doi:10.1351/pac200375060683.
- M. E. Wieser (2006). "Atomic weights of the elements 2005 (IUPAC Technical Report)". Pure and Applied Chemistry. 78 (11): 2051–2066. doi:10.1351/pac200678112051. Lay summary.
Half-life, spin, and isomer data selected from the following sources. See editing notes on this article's talk page.
- G. Audi; A. H. Wapstra; C. Thibault; J. Blachot; O. Bersillon (2003). "The NUBASE evaluation of nuclear and decay properties" (PDF). Nuclear Physics A. 729: 3–128. Bibcode:2003NuPhA.729....3A. doi:10.1016/j.nuclphysa.2003.11.001.
- National Nuclear Data Center. "NuDat 2.1 database". Brookhaven National Laboratory. Retrieved September 2005. Check date values in: |access-date= (help)
- N. E. Holden (2004). "Table of the Isotopes". In D. R. Lide. CRC Handbook of Chemistry and Physics (85th ed.). CRC Press. Section 11. ISBN 978-0-8493-0485-9.

↑ "Nuclear Data Evaluation Lab". Retrieved 2009-05-13.
↑ Augustine George; James T Lane; Arlen D Meyers (January 17, 2013). "Radioactive Iodine Uptake Testing". Medscape.
↑ Hertz, Barbara; Schuleller, Kristin (2010). "Saul Hertz, MD (1905 - 1950) A Pioneer in the Use of Radioactive Iodine". Endocrine Practice. 16 (4): 713–715.
↑ Robbins, Jacob; Schneider, Arthur B. (2000). "Thyroid cancer following exposure to radioactive iodine". Reviews in Endocrine and Metabolic Disorders. 1 (3): 197–203. doi:10.1023/A:1010031115233. ISSN 1389-9155. PMID 11705004.
↑ V. R. Narra; et al. (1992). "Radiotoxicity of Some Iodine-123, Iodine-125, and Iodine-131-Labeled Compounds in Mouse Testes: Implications for Radiopharmaceutical Design" (PDF). Journal of Nuclear Medicine. 33 (12): 2196.
↑ E. Rault; et al. (2007). "Comparison of Image Quality of Different Iodine Isotopes (I-123, I-124, and I-131)". Cancer Biotherapy & Radiopharmaceuticals. 22 (3): 423–430. doi:10.1089/cbr.2006.323. PMID 17651050.
↑ BV Cyclotron VU, Amsterdam, 2016, Information on Iodine-124 for PET
↑ "Frequently Asked Questions on Potassium Iodide". Food and Drug Administration. Retrieved 2009-06-06.
↑ "Potassium Iodide as a Thyroid Blocking Agent in Radiation Emergencies". Federal Register. Food and Drug Administration. Retrieved 2009-06-06.
↑ "Universal Nuclide Chart". nucleonica. (registration required (help)).

External links

Isotopes of tellurium	Isotopes of iodine	Isotopes of xenon
Table of nuclides

Isotopes of the chemical elements
1 H																	2 He
3 Li	4 Be											5 B	6 C	7 N	8 O	9 F	10 Ne
11 Na	12 Mg											13 Al	14 Si	15 P	16 S	17 Cl	18 Ar
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
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
55 Cs	56 Ba		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
87 Fr	88 Ra		104 Rf	105 Db	106 Sg	107 Bh	108 Hs	109 Mt	110 Ds	111 Rg	112 Cn	113 Nh	114 Fl	115 Mc	116 Lv	117 Ts	118 Og

		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
		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
Table of nuclides Categories: Isotopes Tables of nuclides Metastable isotopes Isotopes by element

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