Prices of chemical elements

This is a list of prices of chemical elements. Listed here are mainly average market prices for bulk trade of commodities. Data on elements' abundance in Earth's crust is added for comparison.

As of 2020, the most expensive non-synthetic element by both mass and volume is rhodium. It is followed by caesium, iridium and palladium by mass and iridium, gold and platinum by volume. Of those elements, rhodium, caesium and gold have only one stable isotope (133
Cs
, 103
Rh
and 197
Au
respectively), iridium has two (191
Ir
and 193
Ir
) whereas palladium and platinum both have several. Carbon in the form of diamond can be more expensive than rhodium. Per-kilogram prices of some synthetic radioisotopes range to trillions of dollars. While the difficulty of obtaining macroscopic samples of synthetic elements in part explains their high value, there has been interest in converting base metals to gold (Chrysopoeia) since ancient times, but only deeper understanding of nuclear physics has allowed the actual production of a tiny amount of gold from other elements for research purposes as demonstrated by Glenn Seaborg.[1][2] However, both this and other routes of synthesis of precious metals via nuclear reactions is orders of magnitude removed from economic viability.

Chlorine, sulfur and carbon (as coal) are cheapest by mass. Hydrogen, nitrogen, oxygen and chlorine are cheapest by volume at atmospheric pressure.

When there is no public data on the element in its pure form, price of a compound is used, per mass of element contained. This implicitly puts the value of compounds' other constituents, and the cost of extraction of the element, at zero. For elements whose radiological properties are important, individual isotopes and isomers are listed. The price listing for radioisotopes is not exhaustive.

Chart

Z Symbol Name Density[lower-alpha 1] (kg/L) Abundance and total mass in Earth's crust[lower-alpha 2] (mg/kg) Price[7] Year Source Notes
USD/kg USD/L[lower-alpha 3]
1HHydrogen0.000089881400 (3.878×1019 kg)1.390.0001252012DOE Hydrogen[8]Prices of hydrogen produced by distributed steam methane reforming, as predicted by H2A Production Model from United States Department of Energy,[9] assuming price of natural gas of US$3/MMBtu (US$10/MWh; US$0.10/m3). Does not include cost of storage and distribution.
12H (D)Deuterium0.0001667[10]134002.232020CIL[11]99.8% pure compressed deuterium gas, in lot size of 850 L (142 g). Also sold by same supplier in the form of heavy water at price of 3940 USD per kg deuterium.[12]

In 2016 Iran sold 32 tons of heavy water to United States for 1336 USD per kg deuterium.[13]

2HeHelium0.00017850.008 (2.216×1014 kg)24.00.004292018USGS MCS[14]Crude helium sold to non-government users in United States in 2018. In the same year, stockpiles of US government helium were sold on auctions for average price of US$0.00989/L.[15]
3LiLithium0.53420 (5.54×1017 kg)81.485.643.445.72020SMM[16][lower-alpha 4]Min. 99% pure.
4BeBeryllium1.852.8 (7.756×1016 kg)85715902020ISE 2020[17][lower-alpha 5]Min. 99% pure.
5BBoron2.3410 (2.77×1017 kg)3.688.622019CEIC Data[18][lower-alpha 6]In the form of boric acid, price per boron contained. Min. 99% pure.
6CCarbon2.267200 (5.54×1018 kg)0.1220.282018EIA Coal[19]In the form of anthracite, price per carbon contained, assuming 90% carbon content. There is a wide variation of price of carbon depending on its form. Lower ranks of coal can be less expensive, for example sub-bituminous coal can cost around US$0.038/kg carbon.[19] Graphite flakes can cost around US$0.9/kg carbon.[20] Price of synthetic industrial diamond for grinding and polishing can range from 1200 to 13300 USD/kg, while cost per weight of large synthetic diamonds for industrial applications can be on the order of million dollars per kilogram.[21]
7NNitrogen0.001250619 (5.263×1017 kg)0.1400.0001752001Hypertextbook[24]As liquid nitrogen.
8OOxygen0.001429461000 (1.277×1022 kg)0.1540.0002202001Hypertextbook[24]As liquid oxygen.
9FFluorine0.001696585 (1.62×1019 kg)1.842.160.003110.003652017Echemi[25]In the form of anhydrous hydrofluoric acid, price per fluorine contained. Range of prices on Chinese market, week of 1–7 December 2017.
10NeNeon0.00089990.005 (1.385×1014 kg)2400.211999Ullmann[26]Approximate European price for buying small quantities.
11NaSodium0.97123600 (6.537×1020 kg)2.573.432.493.332020SMM[27][lower-alpha 4]Min 99.7% pure industrial grade sodium.
12MgMagnesium1.73823300 (6.454×1020 kg)2.324.032019Preismonitor[20][lower-alpha 7]Min 99.9% pure.
13AlAluminium2.69882300 (2.28×1021 kg)1.794.842019Preismonitor[20][lower-alpha 7]High-grade primary aluminium, at London Metal Exchange warehouse.
14SiSilicon2.3296282000 (7.811×1021 kg)1.703.972019Preismonitor[20][lower-alpha 7]Min. 99.1% pure, max. 0.4% iron, 0.4% aluminium, 0.1% calcium.[28] 10–100 mm.
15PPhosphorus1.821050 (2.909×1019 kg)2.694.902019CEIC Data[18][lower-alpha 6]Min. 99.9% pure yellow phosphorus.
16SSulfur2.067350 (9.695×1018 kg)0.09260.1912019CEIC Data[18][lower-alpha 6]
17ClChlorine0.003214145 (4.075×1018 kg)0.0820.000262013CnAgri[29]As chlorine is manufactured together with sodium hydroxide in chloralkali process, relative demand for one product changes the price for the other. When demand for sodium hydroxide is relatively high, chlorine price can fall to arbitrarily low levels, even to zero.[30]
18ArArgon0.00178373.5 (9.695×1016 kg)0.9310.001662019UNLV[31]Liquid argon supply contract for University of Nevada, Las Vegas.
19KPotassium0.86220900 (5.789×1020 kg)12.113.610.511.72020SMM[32][lower-alpha 4]Min 98.5% pure industrial grade potassium.
20CaCalcium1.5441500 (1.15×1021 kg)2.212.353.413.632020SMM[33][lower-alpha 4]Blocks of 98.5% pure calcium obtained by reduction process.
21ScScandium2.98922 (6.094×1017 kg)3460103002020ISE 2020[34][lower-alpha 8]Min. 99.99% pure.
22TiTitanium4.545650 (1.565×1020 kg)11.111.750.553.12020SMM[35][lower-alpha 4]Min. 99.6% pure titanium sponge.
23VVanadium6.11120 (3.324×1018 kg)357385218023502020SMM[36][lower-alpha 4]Min. 99.5% pure.
24CrChromium7.15102 (2.825×1018 kg)9.4067.22019Preismonitor[20][lower-alpha 7]Min. 99.2% pure.
25MnManganese7.44950 (2.632×1019 kg)1.8213.62019Preismonitor[20][lower-alpha 7]Electrolytic manganese, min. 99.7% pure.
26FeIron7.87456300 (1.565×1021 kg)0.4243.342020SMM[37][lower-alpha 4]L8-10 pig iron. At Tangshan, China.
27CoCobalt8.8625 (6.925×1017 kg)32.82912019Preismonitor[20][lower-alpha 7]Spot price. Min. 99.8% pure. At London Metal Exchange warehouse.
28NiNickel8.91284 (2.327×1018 kg)13.91242019Preismonitor[20][lower-alpha 7]Primary nickel. Spot price. Min. 99.8% pure. At London Metal Exchange warehouse.
29CuCopper8.9660 (1.662×1018 kg)6.0053.82019Preismonitor[20][lower-alpha 7]Spot price. Grade A.[38] At London Metal Exchange warehouse.
30ZnZinc7.13470 (1.939×1018 kg)2.5518.22019Preismonitor[20][lower-alpha 7]Min. 99.995% pure special high grade zinc metal. Spot price. At London Metal Exchange warehouse.
31GaGallium5.90719 (5.263×1017 kg)1488722019Preismonitor[20][lower-alpha 7]Min. 99.99% pure. Free on Board China.
32GeGermanium5.3231.5 (4.155×1016 kg)9141010486053902020SMM[39][lower-alpha 4]Ingot. 50 Ω/cm.
33AsArsenic5.7761.8 (4.986×1016 kg)0.9991.315.777.582020SMM[40][lower-alpha 4]Min. 99.5% pure.
34SeSelenium4.8090.05 (1.385×1015 kg)21.41032019Preismonitor[20][lower-alpha 7]Selenium powder, min. 99.9% pure.
35BrBromine3.1222.4 (6.648×1016 kg)4.3913.72019CEIC Data[18][lower-alpha 6]
36KrKrypton0.0037331×10−4 (2.77×1012 kg)2901.11999Ullmann[26]Approximate European price for buying small quantities.
37RbRubidium1.53290 (2.493×1018 kg)15500237002018USGS MCS[14]100 g ampoules of 99.75% pure rubidium metal.
38SrStrontium2.64370 (1.025×1019 kg)6.536.6817.217.62019ISE 2019[41]Min. 99% pure, Ex Works China.
39YYttrium4.46933 (9.141×1017 kg)31.01392019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
40ZrZirconium6.506165 (4.571×1018 kg)35.737.12322412020SMM[42][lower-alpha 4]Zirconium sponge, min. 99% pure.
41NbNiobium8.5720 (5.54×1017 kg)61.485.65267342020SMM[43][lower-alpha 4]Min. 99.9% pure.
42MoMolybdenum10.221.2 (3.324×1016 kg)40.14102019Preismonitor[20][lower-alpha 7]Min. 99.95% pure.
43TcTechnetium11.5~ 3×10−9[lower-alpha 9] (8.31×107 kg)10000012000002004[lower-alpha 10]CRC Handbook[lower-alpha 11]
4399mTcTechnetium-99m11.51.9×101222×10122008NRC[46]In the form of medical doses of sodium pertechnetate made on-site in technetium-99m generators. Price per technetium contained. Range of prices for medical doses available in the United States. Technetium-99m has half-life of 6 hours, which limits its ability to be directly traded.
44RuRuthenium12.370.001 (2.77×1013 kg)10400106001290001310002020SMM[47][lower-alpha 4]99.95% pure.
45RhRhodium12.410.001 (2.77×1013 kg)14700018200002019Preismonitor[20][lower-alpha 7]99.95% pure.
46PdPalladium12.020.015 (4.155×1014 kg)495005950002019Preismonitor[20][lower-alpha 7]99.95% pure. London bullion market afternoon fix. In warehouse.
47AgSilver10.5010.075 (2.0775×1015 kg)52154702019Preismonitor[20][lower-alpha 7]99.5% pure. Spot price. At London Metal Exchange warehouse.
48CdCadmium8.690.159 (4.4043×1015 kg)2.7323.82019Preismonitor[20][lower-alpha 7]Ingot, min. 99.99% pure.
49InIndium7.310.25 (6.925×1015 kg)16712202019Preismonitor[20][lower-alpha 7]Min. 99.99% pure.
50SnTin7.2872.3 (6.371×1016 kg)18.71362019Preismonitor[20][lower-alpha 7]Min. 99.85% pure. Spot price. At London Metal Exchange warehouse.
51SbAntimony6.6850.2 (5.54×1015 kg)5.7938.72019Preismonitor[20][lower-alpha 7]Ingot, min. 99.65% pure.
52TeTellurium6.2320.001 (2.77×1013 kg)63.53962019Preismonitor[20][lower-alpha 7]Min. 99.99% pure. Europe.
53IIodine4.930.45 (1.2465×1016 kg)351732019Industrial Minerals[48]Min 99.5% pure. Spot market price on 2 August 2019.
54XeXenon0.0058873×10−5 (8.31×1011 kg)1800111999Ullmann[26]Approximate European price for buying small quantities.
55CsCaesium1.8733 (8.31×1016 kg)618001160002018USGS MCS[14]1 g ampoules of 99.8% pure caesium.
56BaBarium3.594425 (1.177×1019 kg)0.2460.2750.8860.9902016USGS MYB 2016[49]In the form of chemical-grade barite (barium sulfate) exported from China to United States. Price per barium contained, includes cost, insurance, and freight. Barium sulfate is the primary feedstock for production of barium chemicals.[50]
57LaLanthanum6.14539 (1.08×1018 kg)4.784.9229.430.32020SMM[51][lower-alpha 4]Min. 99% pure.
58CeCerium6.7766.5 (1.84205×1018 kg)4.574.7130.931.92020SMM[52][lower-alpha 4]Min. 99% pure.
59PrPraseodymium6.7739.2 (2.5484×1017 kg)1036952019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
60NdNeodymium7.00741.5 (1.14955×1018 kg)57.54032019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
61147PmPromethium-1477.2646000034000002003Radiochemistry Society[53]From Periodic Table of the Elements published on website of Radiochemistry Society. There is no further information as to source or specifics of this price.
62SmSamarium7.527.05 (1.95285×1017 kg)13.91042019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
63EuEuropium5.2432 (5.54×1016 kg)31.41652020ISE 2020[34][lower-alpha 8]Min. 99.999% pure.
64GdGadolinium7.8956.2 (1.7174×1017 kg)28.62262020ISE 2020[34][lower-alpha 8]Min. 99.5% pure.
65TbTerbium8.2291.2 (3.324×1016 kg)65854102019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
66DyDysprosium8.555.2 (1.4404×1017 kg)30726302019Preismonitor[20][lower-alpha 7]Min. 99% pure, Free on Board China.
67HoHolmium8.7951.3 (3.601×1016 kg)57.15032020ISE 2020[34][lower-alpha 8]Min. 99.5% pure.
68ErErbium9.0663.5 (9.695×1016 kg)26.42402020ISE 2020[34][lower-alpha 8]Min. 99.5% pure.
69TmThulium9.3210.52 (1.4404×1016 kg)3000280002003IMAR[54][lower-alpha 12]Price quotes from Canadian producer, for 1 kg order. 99.5–99.99% purity, Free on Board Vancouver, Canada.
70YbYtterbium6.9653.2 (8.864×1016 kg)17.11192020ISE 2020[34][lower-alpha 8]Min. 99.99% pure.
71LuLutetium9.840.8 (2.216×1016 kg)64363302020ISE 2020[34][lower-alpha 8]Min. 99.99% pure.
72HfHafnium13.313 (8.31×1016 kg)900120002017USGS MCS[14]Unwrought hafnium.
73TaTantalum16.6542 (5.54×1016 kg)298312496052002019ISE 2019[41]Min. 99.95% pure. Ex Works China.
74WTungsten19.251.3 (3.601×1016 kg)35.36792019Preismonitor[20][lower-alpha 7]Powder, particle size 2–10 µm, 99.7% pure. Free on Board China.
75ReRhenium21.027×10−4 (1.939×1013 kg)3010415063300873002020SMM[55][lower-alpha 4]99.99% pure.
76OsOsmium22.610.002 (5.54×1013 kg)120002800002016Fastmarkets[lower-alpha 13]
77IrIridium22.560.001 (2.77×1013 kg)5550056200125000012700002020SMM[58][lower-alpha 4]99.95% pure.
78PtPlatinum21.460.005 (1.385×1014 kg)278005960002019Preismonitor[20][lower-alpha 7]99.95% pure. London bullion market morning fix. In warehouse.
79AuGold19.2820.004 (1.108×1014 kg)448008630002019Preismonitor[20][lower-alpha 7]99.9% pure. Morning London gold fix.
80HgMercury13.53360.085 (2.3545×1015 kg)30.24092017USGS MCS[14]Average European Union price of 99.99% pure mercury.
81TlThallium11.850.85 (2.3545×1016 kg)4200498002017USGS MCS[14]
82PbLead11.34214 (3.878×1017 kg)2.0022.62019Preismonitor[20][lower-alpha 7]Min. 99.97% pure. Spot price. At London Metal Exchange warehouse.
83BiBismuth9.8070.009 (2.493×1014 kg)6.3662.42019Preismonitor[20][lower-alpha 7]Refined bismuth, min. 99.99% pure.
84209PoPolonium-2099.3249.2×1012458×10122004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
85AtAstatine73×10−20[lower-alpha 9] (8.31×10−4 kg)Not traded.Only under a tenth of microgram of astatine has ever been produced.[44] Most stable isotope has half-life of 8.1 hours.
86RnRadon0.009734×10−13[lower-alpha 9] (1.108×104 kg)Not traded.Used in brachytherapy until 1960s,[59] currently radon is not used commercially.[60]
87FrFrancium1.87~ 1×10−18[lower-alpha 9] (2.77×10−2 kg)Not traded.Only quantities of the order of millions of atoms have been obtained for research.[61] Most stable isotope, 223Fr, has half-life of 22 minutes. Francium has no commercial or medical uses.[60]
88RaRadium5.59×10−7[lower-alpha 9] (2.493×1010 kg)Negative price.Radium was historically used in the treatment of cancer, but stopped being used when more effective treatments were introduced. As medical facilities had to pay for its disposal, its price can be considered negative.[62]
89225AcActinium-22510.0729×1012290×10122004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
90ThThorium11.729.6 (2.6592×1017 kg)28733602010USGS MYB 2012[63]As 99.9% pure thorium oxide, price per thorium contained. Free on Board port of entry, duty paid.
91PaProtactinium15.371.4×10−6[lower-alpha 9] (3.878×1010 kg)No reliable price available.In 1959–1961 Great Britain Atomic Energy Authority produced 125 g of 99.9% pure protactinium at a cost of $500000, giving the cost of 4000000 USD per kg.[44] Periodic Table of Elements at Los Alamos National Laboratory website at one point listed protactinium-231 as available from Oak Ridge National Laboratory at a price of 280000 USD/kg.[64]
92UUranium18.952.7 (7.479×1016 kg)10119102018EIA Uranium Marketing[65]Mainly as triuranium octoxide, price per uranium contained.
93NpNeptunium20.45 3×10−12[lower-alpha 9] (8.31×104 kg)660000135000002003[lower-alpha 10]Pomona[66]Periodic Table published by Pomona College Chemistry Department lists neptunium-237 as available from Oak Ridge National Laboratory at 660 USD/g plus packing costs.
94239PuPlutonium-23919.8464900001290000002019DOE OSTI[67]Certified reference material sample in the form of plutonium(IV) oxide, price per plutonium-239 contained.
95241AmAmericium-24113.69072800099700001998NWA[68][lower-alpha 15]Available from Oak Ridge National Laboratory as reported in Nuclear Weapons FAQ.
95243AmAmericium-24313.690750000103000002004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
96244CmCurium-24413.5101850000002.50×1092004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
96248CmCurium-24813.510160×1092.16×10122004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
97249BkBerkelium-24914.790185×1092.74×10122004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
98249CfCalifornium-24915.10185×1092.79×10122004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
98252CfCalifornium-25215.1060.0×109906×1092004[lower-alpha 10]CRC Handbook (ORNL)[lower-alpha 14]
99EsEinsteinium8.840Not traded.Only microgram quantities have ever been produced.[44] Most stable known isotope has half-life of 471.7 days.
100FmFermium(9.7)0Not traded.Only tracer amounts have ever been produced.[44][69]:13.2.6. Most stable known isotope has half-life of 100.5 days.
101MdMendelevium(10.3)0Not traded.Only around 106 atoms have been produced in experiments.[69]:13.3.6. Most stable known isotope has half-life of 51 days.
102NoNobelium(9.9)0Not traded.Only around 105 atoms have been produced in experiments.[69]:13.4.6. Most stable known isotope has half-life of 58 minutes.
103LrLawrencium(15.6)0Not traded.Only around 1000 atoms have been produced in experiments.[69]:13.5.6. Most stable known isotope has half-life of 11 hours.
104RfRutherfordium(23.2)0Not traded.Only a few thousand atoms have been produced in experiments.[44] Most stable known isotope has half-life of 2.5 hours.
105DbDubnium(29.3)0Not traded.Atoms of dubnium have been prepared experimentally at a rate of at most one per minute.[70] Most stable known isotope has half-life of 29 hours.
106SgSeaborgium(35.0)0Not traded.Only tens of atoms have been produced in experiments.[71] The most stable known isotope has half-life of 14 minutes.
107BhBohrium(37.1)0Not traded.Only tens of atoms have been produced in experiments.[72] Most stable known isotope has half-life of 1 minute.
108HsHassium(40.7)0Not traded.Only tens of atoms have been produced in experiments.[72] Most stable known isotope has half-life of 16 seconds.
109MtMeitnerium(37.4)0Not traded.Only produced in experiments on a per-atom basis.[73] Most stable known isotope has half-life of 8 seconds.
110DsDarmstadtium(34.8)0Not traded.Only produced in experiments on a per-atom basis.[73] Most stable known isotope has half-life of 9.6 seconds.
111RgRoentgenium(28.7)0Not traded.Only produced in experiments on a per-atom basis.[73] Most stable known isotope has half-life of 2.1 minutes.
112CnCopernicium(14.0)0Not traded.Only tens of atoms have been produced in experiments.[72] Most stable known isotope has half-life of 29 seconds.
113NhNihonium(16)0Not traded.As of 2015, less than 100 atoms have been produced in experiments.[74] Most stable known isotope has half-life of 8 seconds.
114FlFlerovium(9.928)0Not traded.As of 2015, less than 100 atoms have been produced in experiments.[74] Most stable known isotope has half-life of 1.9 seconds.
115McMoscovium(13.5)0Not traded.As of 2015, less than 100 atoms have been produced in experiments.[74] Most stable known isotope has half-life of 0.65 seconds.
116LvLivermorium(12.9)0Not traded.As of 2015, less than 100 atoms have been produced in experiments.[74] Most stable known isotope has half-life of 53 ms.
117TsTennessine(7.2)0Not traded.As of 2015, less than 100 atoms have been produced in experiments.[74] Most stable known isotope has half-life of 51 ms.
118OgOganesson(7)0Not traded.As of 2015, less than ten atoms have been produced in experiments.[74] Most stable known isotope has half-life of 0.7 ms.

See also

Notes

  1. Density for 0 °C, 101.325 kPa.[3] For individual isotopes except deuterium, density of base element is used. Values in parentheses are theoretical predictions.
  2. Unless otherwise indicated, elements are primordial – they occur naturally, and not through decay.
  3. Price per volume for 0 °C, 101.325 kPa, pure element. For individual isotopes except deuterium, density of base element is used.
  4. Spot market price range on 3 February 2020.
  5. Market price on 5 February 2020
  6. Average price in November 2019. Data from China Petroleum and Chemical Industry Federation.
  7. Price average for entire year 2019.
  8. Market price on 4 February 2020
  9. This element is transient – it occurs only through decay (and in the case of plutonium, also in traces deposited from supernovae onto Earth).
  10. or earlier
  11. The values reported are present in 85th edition of CRC Handbook of Chemistry and Physics[44] (and possibly earlier) and remain unchanged to at least 97th edition.[45]
  12. Source lists prices of other rare earth elements (some of which are significantly different than the ones presented in table above):
    • lanthanum – 25 USD/kg
    • cerium – 30 USD/kg
    • praseodymium – 70 USD/kg
    • neodymium – 30 USD/kg
    • samarium – 80 USD/kg
    • europium – 1600 USD/kg
    • gadolinium – 78 USD/kg
    • terbium – 630 USD/kg
    • dysprosium – 120 USD/kg
    • holmium – 350 USD/kg
    • erbium – 180 USD/kg
    • thulium – 3000 USD/kg
    • ytterbium – 484 USD/kg
    • lutetium – 4000 USD/kg
    • yttrium – 96 USD/kg
  13. Fastmarkets Price[56] and Chart[57] Creator. Mid-market price from price table. Year of latest price data (2016) read from chart. Archived: table, chart (5, 7, 50, 1200 data points)
  14. Available from Oak Ridge National Laboratory as reported in CRC Handbook of Chemistry and Physics. Price does not include packing costs. The values reported are present in Handbook's 85th edition[44] (and possibly earlier) and remain unchanged to at least 97th edition.[45]
  15. This source also lists price of Americium-243 as 180 USD/mg, which is much higher than reported in CRC Handbook of Chemistry and Physics and used in this table.

References

  1. Aleklett, K.; Morrissey, D.; Loveland, W.; McGaughey, P.; Seaborg, G. (1981). "Energy dependence of 209Bi fragmentation in relativistic nuclear collisions". Physical Review C. 23 (3): 1044. Bibcode:1981PhRvC..23.1044A. doi:10.1103/PhysRevC.23.1044.
  2. Matthews, Robert (2 December 2001). "The Philosopher's Stone". The Daily Telegraph. Retrieved 2020-09-22.
  3. See: Densities of the elements (data page)
  4. Antweiler, Werner. "Foreign Currency Units per 1 European Euro, 1999-2018" (PDF). PACIFIC Exchange Rate Service. University of British Columbia. Archived (PDF) from the original on 2020-03-28.
  5. Antweiler, Werner. "Database Retrieval System". PACIFIC Exchange Rate Service. University of British Columbia. Archived from the original on 2020-07-26.
  6. "USD / RMB". price.metal.com. Shanghai Metals Market. 3 February 2020. Archived from the original on 2020-02-03.
  7. Values used for currency conversion:
    • Euro: 1999 – 1.0654 USD/EUR[4]
    • Renminbi: September 2013 – 0.16340 USD/CNY,[5] December 2017 – 0.15159 USD/CNY,[5] November 2019 – 0.14241 USD/CNY,[5] 3 February 2019 – 0.14273 USD/CNY[6]
  8. Dillich, Sara; Ramsden, Todd; Melaina, Marc (19 September 2012). Satyapal, Sunita (ed.). DOE Hydrogen and Fuel Cells Program Record #12024: Hydrogen Production Cost Using Low-Cost Natural Gas (PDF) (Report). United States Department of Energy. p. 5. Archived (PDF) from the original on 2017-02-15.
  9. "DOE Hydrogen and Fuel Cells Program: DOE H2A Production Analysis". Hydrogen & Fuel Cells Program. United States Department of Energy. Archived from the original on 2012-03-06.
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