Isotopes of thallium

The only stable isotopes of thallium (81Tl) are 203Tl and 205Tl, which make up all natural thallium. The five short-lived isotopes 206Tl through 210Tl also occur in nature, but only as part of the natural decay chains of heavier elements. Synthetic radioisotopes are known from 176Tl to 217Tl; the most stable is 204Tl with a half-life of 3.78 years, followed by 202Tl (half-life 12.31 days) and 201Tl (half-life 3.0421 days). The naturally-occurring radioisotopes live minutes only, with the longest being 207Tl, with a half-life of 4.77 minutes. All isotopes of thallium are either radioactive or observationally stable, meaning that they are predicted to be radioactive but no actual decay has been observed.

The isotope 204Tl is made by the neutron activation of stable thallium in a nuclear reactor. while 202Tl can be made in a cyclotron as can 201Tl (see section below).

In the fully ionized state, the isotope 205Tl81+ becomes unstable, undergoing bound-state β− decay to 205Pb81+ with a half-life of 291+33 −27 days, but 203Tl remains stable.

205Tl is the decay product of bismuth-209, an isotope that was once thought to be stable but is now known to undergo alpha decay with an extremely long half-life of 2.01×1019 y. Thus 205Tl is now placed at the end of the neptunium decay chain.

List of isotopes

Nuclide	Historic name	Z	N	Isotopic mass (Da)	Discovery year	Half-life	Decay mode	Daughter isotope	Spin and parity	Natural abundance (mole fraction)
Excitation energy	Normal proportion	Range of variation
176Tl		81	95	176.000628(89)		2.4+1.6 −0.7 ms	p (50%)	175Hg	(3−,4−)
α (50%)	172Au
176mTl		671 keV	(2020)	290+200 −80 μs	p (50%)	175Hg
α (50%)	172mAu
177Tl		81	96	176.996414(23)		18(5) ms	α (73%)	173Au	(1/2+)
p (27%)	176Hg
177mTl		807(18) keV		230(40) μs	p (51%)	176Hg	(11/2−)
α (49%)	173Au
178Tl		81	97	177.99505(11)#		255(9) ms	α (62%)	174Au	(4-,5-)
β+ (38%)	178Hg
β+, SF (0.15%)	(various)
179Tl		81	98	178.991122(41)		437(9) ms	α (60%)	175Au	1/2+
β+ (40%)	179Hg
179m1Tl		825(10)# keV		1.41(2) ms	α	175Au	(11/2−)
179m2Tl		904.5(9) keV		119(14) ns	IT	179Tl	(9/2−)
180Tl		81	99	179.989919(75)		1.09(1) s	β+ (93%)	180Hg	(4-)
α (7%)	176Au
β+, SF (0.0032%)	(various)
181Tl		81	100	180.9862600(98)		2.9(1) s	β+ (91.4%)	181Hg	1/2+
α (8.6%)	177Au
181mTl		835.9(4) keV		1.40(3) ms	IT (99.60%)	181Tl	(9/2−)
α (0.40%)	177Au
182Tl		81	101	181.985693(13)		1.9(1) s	β+ (<99.41%)	182Hg	(4−)
α (>0.49%)	178Au
β+, SF (<3.4×10−6%)	182Hg
182mTl		50(50)# keV		3.1(10) s	β+ (97.5%)	182Hg	(7+)
α (2.5%)	178Au
183Tl		81	102	182.982193(10)		6.9(7) s	β+ (?%)	183Hg	1/2+
α (?%)	179Au
183m1Tl		628.7(5) keV		53.3(3) ms	IT (?%)	183Tl	(9/2−)
α (1.5%)	179Au
β+ (?%)	183Hg
183m2Tl		975.3(6) keV		1.48(10) μs	IT	183Tl	(13/2+)
184Tl		81	103	183.981875(11)		9.5(2) s	β+ (98.78%)	184Hg	2−
α (1.22%)	180Au
184m1Tl		−50(30) keV		10.6(5) s	β+ (99.53%)	184Hg	(7+)
α (0.47%)	180Au
184m2Tl		450(30) keV		47.1(7) ms	IT (99.91%)		(10−)
α (0.089%)	180Au
185Tl		81	104	184.978789(22)		19.5(5) s	β+	185Hg	1/2+
185mTl		454.8(15) keV		1.93(8) s	IT	185Tl	9/2−
α (?%)	181Au
186Tl		81	105	185.978655(22)		3.5(5) s	β+ (?%)	186Hg	(2−)
α (?%)	182Au
186m1Tl		20(40) keV		27.5(10) s	β+ (99.99%)	186Hg	7+
α (0.006%)	182Au
186m2Tl		390(40) keV		3.40(9) s	IT (<94.1%)	186Tl	10−
β+ (>5.9%)	186Hg
187Tl		81	106	186.9759047(86)		~51 s	β+	187Hg	1/2+
187m1Tl		334(3) keV		15.60(12) s	β+ (?%)	187Hg	9/2−
IT (?%)	187Tl
α (0.15%)	183Au
187m2Tl		1875(50)# keV		1.11(7) μs	IT	187Tl
187m3Tl		2582.5(3) keV		693(38) ns	IT	187Tl	29/2+#
188Tl		81	107	187.976021(32)		71(2) s	β+	188Hg	2−#
188m1Tl		30(30) keV		71.5(15) s	β+	188Hg	7+
188m2Tl		299(30) keV		41(4) ms	IT	188Tl	9−
189Tl		81	108	188.9735735(90)		2.3(2) min	β+	189Hg	1/2+
189mTl		285(6) keV		1.4(1) min	β+	189Hg	9/2−
190Tl		81	109	189.9738418(78)		2.6(3) min	β+	190Hg	2−
190m1Tl		70(7) keV		3.6(3) min	β+	190Hg	7+
190m2Tl		306(10) keV		60# ms	IT	190Tl	(9−)
191Tl		81	110	190.9717841(79)		20# min	β+	191Hg	1/2+
191mTl		297(7) keV		5.22(16) min	β+	191Hg	9/2−
192Tl		81	111	191.972225(34)		9.6(4) min	β+	192Hg	2−
192m1Tl		196(7) keV		10.8(2) min	β+	192Hg	7+
192m2Tl		447(7) keV		296(5) ns	IT	192Tl	(8−)
192m3Tl		180(40) keV	(1991)		α	188Au	(3+)
193Tl		81	112	192.9705020(72)		21.6(8) min	β+	193Hg	1/2+
193mTl		372(4) keV		2.11(15) min	IT (~75%)	193Tl	9/2−
β+ (~25%)	193Hg
194Tl		81	113	193.971081(15)		33.0(5) min	β+	194Hg	2−
194mTl		260(14) keV		32.8(2) min	β+	194Hg	7+
195Tl		81	114	194.969774(12)		1.16(5) h	β+	195Hg	1/2+
195mTl		482.63(17) keV		3.6(4) s	IT	195Tl	9/2−
196Tl		81	115	195.970481(13)		1.84(3) h	β+	196Hg	2−
196mTl		394.2(5) keV		1.41(2) h	β+ (96.2%)	196Hg	7+
IT (3.8%)	196Tl
197Tl		81	116	196.969560(15)		2.84(4) h	β+	197Hg	1/2+
197mTl		608.22(8) keV		540(10) ms	IT	197Tl	9/2−
198Tl		81	117	197.9704467(81)		5.3(5) h	β+	198Hg	2−
198m1Tl		543.6(4) keV		1.87(3) h	β+ (55.9%)	198Hg	7+
IT (44.1%)	198Tl
198m2Tl		686.8(5) keV		150(40) ns	IT	198Tl	(5)+
198m3Tl		742.4(4) keV		32.1(10) ms	IT	198Tl	10−
199Tl		81	118	198.969877(30)		7.42(8) h	β+	199Hg	1/2+
199mTl		748.87(6) keV		28.4(2) ms	IT	199Tl	9/2−
200Tl		81	119	199.9709636(62)		26.1(1) h	β+	200Hg	2−
200m1Tl		753.60(24) keV		34.0(9) ms	IT	200Tl	7+
200m2Tl		762.00(24) keV		397(17) ns	IT	200Tl	5+
201Tl		81	120	200.970820(15)		3.0421(8) d	EC	201Hg	1/2+
201mTl		919.16(21) keV		2.01(7) ms	IT	201Tl	9/2−
202Tl		81	121	201.9721089(20)		12.31(8) d	EC	202Hg	2−
202mTl		950.19(10) keV		591(3) μs	IT	202Tl	7+
203Tl		81	122	202.9723441(13)		Observationally Stable	1/2+	0.29515(44)
203m1Tl		1483.7(9) keV	(2020)	<1 μs	IT	203Tl	(9/2−)
203m2Tl		3565(50)# keV		7.7(5) μs	IT	203Tl	(25/2+)
204Tl		81	123	203.9738634(12)		3.783(12) y	β− (97.08%)	204Pb	2−
EC (2.92%)	204Hg
204m1Tl		1104.1(2) keV		61.7(10) μs	IT	204Tl	7+
204m2Tl		2319.0(3) keV		2.6(2) μs	IT	204Tl	12−
204m3Tl		4391.6(5) keV		420(30) ns	IT	204Tl	18+
204m4Tl		6239.4(5) keV	(2011)	90(3) ns	IT	204Tl	22−
205Tl		81	124	204.9744273(13)		Observationally Stable	1/2+	0.70485(44)
205m1Tl		3290.61(17) keV		2.6(2) μs	IT	205Tl	25/2+
205m2Tl		4835.6(15) keV	(2004)	235(10) ns	IT	205Tl	(35/2–)
206Tl	Radium E"	81	125	205.9761101(14)		4.202(11) min	β−	206Pb	0−	Trace
206mTl		2643.10(18) keV		3.74(3) min	IT	206Tl	(12)–
207Tl	Actinium C"	81	126	206.9774186(58)		4.77(2) min	β−	207Pb	1/2+	Trace
207mTl		1348.18(16) keV		1.33(11) s	IT	207Tl	11/2–
208Tl	Thorium C"	81	127	207.9820180(20)		3.053(4) min	β−	208Pb	5+	Trace
208mTl		1807(1) keV		1.3(1) μs	IT	208Tl	(0–)
209Tl		81	128	208.9853517(66)		2.162(7) min	β−	209Pb	1/2+	Trace
209mTl		1228.1(20) keV		146(10) ns	IT	209Tl	17/2+
210Tl	Radium C″	81	129	209.990073(12)		1.30(3) min	β− (99.99%)	210Pb	5+#	Trace
β−, n (0.009%)	209Pb
210mTl		1200(200)# keV		1# min [>3 μs]			(9+,10+)
211Tl		81	130	210.993475(45)		81(16) s	β− (97.8%)	211Pb	1/2+
β−, n (2.2%)	210Pb
211mTl		1244(100)# keV		580(80) ns	IT	211Tl	17/2+#
212Tl		81	131	211.99834(22)#		31(8) s	β− (98.2%)	212Pb	(5+)
β−, n (1.8%)	211Pb
213Tl		81	132	213.001915(29)		23.8(44) s	β− (92.4%)	213Pb	1/2+#
β−, n (7.6%)	212Pb
213m1Tl		680(300)# keV		4.1(5) μs	IT	213Tl
213m2Tl		1250(100)# keV		0.6(3) μs	IT	213Tl	17/2+#
214Tl		81	133	214.00694(21)#		11.0(24) s	β− (66%)	214Pb	5+#
β−, n (34%)	213Pb
215Tl		81	134	215.01077(32)#		9.7(38) s	β− (95.4%)	215Pb	1/2+#
β−, n (4.6%)	214Pb
216Tl		81	135	216.01596(32)#		5.9(33) s	β− (>88.5%)	216Pb	5+#
β−, n (<11.5%)	215Pb
217Tl		81	136	217.02003(43)#		2# s [>300 ns]			1/2+#
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Thallium-201

Thallium-201 (201Tl) is a synthetic radioisotope of thallium. It has a half-life of 3.0421 days and decays by electron capture, emitting photons consisting mainly of K X-rays (~70–80 keV), and gammas of 135 and 167 keV (the latter stronger, emitted in 10% of decays). Thallium-201 is synthesized by the neutron activation of stable thallium in a nuclear reactor, or by the 203Tl(p, 3n)201Pb nuclear reaction in cyclotrons, as 201Pb then decays to 201Tl. It is a radiopharmaceutical, as it has fair imaging characteristics without excessive patient radiation dose. It was the most popular isotope used for nuclear cardiac stress tests.

This nuclide has largely been replaced by technetium-99m, which has a shorter half-life (6 hours instead of 3 days) and a single high-energy photon peak (140 keV), which is better for imaging than the 3 energy peaks of thallium-201. Thallium-201 is now mostly used for myocardial viability studies. It will redistribute in body tissues, whereas Tc will not; Tl is taken up by the cardiac muscle via Na+/K+ pumps. Delayed imaging will show uptake in damaged but still living myocardial cells, which would appear as a scar with Tc or 82Rb.

Isotopes of thallium

List of isotopes

Thallium-201

See also