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ILIAS, Jaca , Spain 5 of December 2006. Se-82 purification: distillation and rectification procedures Kornoukhov Vasily INR RAS (Moscow) for IChHPS (Nizhny Novgorod) and IRE (Moscow). LAL, Orsay , Spain 1 – 2 of June 2006 SuperNEMO: radiopurity requirements.
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ILIAS, Jaca , Spain 5 of December 2006 Se-82 purification: distillation and rectification procedures Kornoukhov Vasily INR RAS (Moscow) for IChHPS (Nizhny Novgorod) and IRE (Moscow)
LAL, Orsay , Spain 1 – 2 of June 2006SuperNEMO: radiopurity requirements Tl-208 (232Th chain) <= 2 mBq/kg (<= 1.5 ppt of Th-232) Bi-214 (238U chain) <= 10 mBq/kg (< = 10 ppt of U-238)
232Th 1,41·1010 y 228Th 1,91 y 228Ac 6,15 hours 228Ra 5,75 y 224Ra 3,64 d 220Rn 55,3 sec T1/2 ~ 1010 y T1/2 ~ years 216Po 0,158 sec T1/2 ~ days 212Bi 60,5 min T1/2 ~< hours 36,2 % 212Pb 10,64 h 208Tl 3,10 min
ILIAS, Jaca , Spain 5 of December 2006 SuperNEMO: dangerous isotopes from 232Th chain Th-232, Ra-228, Th-228 We must remove Th and Ra How to check the procedure: Th: 232Th (MS), 228Th (HPGe: 208Tl g- line) Ra: 228Ra (HPGe: 228Ac g-line)
238U 4,51·109 y 234U 2,47·105 y 234mPa 1,18 min 234Th 24 d 230Th 8,0 ·104 y 226Ra 1602 y T1/2 ~ 103 - 109 y T1/2 ~ days 222Rn 3,824 d T1/2 ~ minutes 218Po 3,05 min 214Bi 19,7 min 214Pb 26,8 min
ILIAS, Jaca , Spain 5 of December 2006 SuperNEMO: dangerous isotopesfrom 238U chain Ra-226 We must remove Ra How to check the procedure: Ra: 226Ra (Champagne method, HPGe: 214Bi g-line)
ILIAS, Jaca , Spain 5 of December 2006 SuperNEMO: dangerous isotopes and elements • 238U chain: Ra-226 • 232Th cain: Th-232, Ra-228, Th-228 Conclusion: we must remove Ra and Th
ILIAS, Jaca , Spain 5 of December 2006 Industrial scaleproduction of 82Se At present the only technology for industrial scale production of 82Se is centrifugation method and only site for ~ 100 kg-scale production is Svetlana (the ECP, Siberia)
ILIAS, Jaca , Spain 5 of December 2006 82Se transformation at Svetlana (the ECP)(V.Kornoukhov for ILIAS meeting, Orsay, April 2005) Patent #… is “valid” in Russia only natSe natSeF6centrifugation 82SeF6 82SeF6 (glow discharge) 82Se + … 82Se washing with H2O (to remove F-ions) Distillation of 82Se in vacuum “Chemical features” of impurities (chemical forms): fluorine compounds (!)
ILIAS, Jaca , Spain 5 of December 2006 General remarks concerning the problem: (+) • Se is material for semi-conductive industry: there are many methods for its purification; (-) • 82Se is a result of chemical transformation through SeF6 compound, and behavior of U-, Th-, Ra-impurities presented in such product (fluorine compounds) could be quite different of impurities in selenium produced accordingly to standard technology.
ILIAS, Jaca , Spain 5 of December 2006 Chemical forms of U, Th, Ra impurities in isotopically enriched Se There is no exact information on chemical forms of U, Th, Ra impurities at their low concentration in selenium. There are no data on solubility of U, Th, Ra compounds with oxygen, selenium, fluorine in liquid Se. No data on adsorption ability of U, Th, Ra impurities on heterogeneous particles of submicron size.
ILIAS, Jaca , Spain 5 of December 2006 Some properties of elementary selenium Molecular composition of Se: Vapor (at 700 – 1300 K): Se2 – Se8 Melt (at 494.3 – 958.4 K): mixture of cyclo-Se8, katenapoly-Sen (n = 102 – 103), and polycyclo-Sen in chemical equilibrium. Solid: Seα, Seβ – Se8, Sehex. - Sen Melting Point, K. Se - 443; Se - 453; Sehex – 494,3 Boiling point, K – 958.4 Density, g/cm3: Seα – 4.46; Seβ - 4.50; Se hex. – 4.717; Seliq (550 K) – 3.918 Industrial sources of Se of technical grade (99.0 – 99.7 %): Production of sulfuric acid and non-ferrous metals
ILIAS, Jaca , Spain 5 of December 2006 Distillation procedure & NEMO detector Group from INR RAS (in 1997): 116Cd distillation for NEMO-3 detector (two portions, 0.15 kg + 0.15 kg): good result!
ILIAS, Jaca , Spain 5 of December 2006Physical methods of Se purification Distillation methods: 1. One – Stage (Simple) distillation 2. Multi-Stage distillation methods: a. Repeated simple distillation of purified product from previous stages. b. Rectification – multi-stage counter – current method, realized in one apparatus and in one process.
Purification of selenium by distillation method Essence of method: impurity content in equilibrium vapor and liquid is different. х ≠ y Elementary separation process: Influence on the system with initially uniform impurity distribution leading to appearance of spatially divided parts of system with different impurity content. The physical action leading to separation in distillation methods: -evaporation part of liquid -condensation part of vapor. Condition of separation: у α = ≠ 1 х Conditions of effective separation at distillation: у α = >> 1 for highly volatile impurities х у α = << 1 for non-volatile impurities х
Separation coefficient at the equilibrium “ liquid-vapour” for some impurities in Se at 684oC * ideal separation coefficient
100 1 • Particles diameter, • 1 - 130-140; • - 80-90. 80 a ef 60 40 2 20 0 0,1 1 10 100 6 3 -2 -1 V *10 , cm cm s eval Effective separation coefficient of heterogeneous particles in Se as function of evaporation rate Distribution on size of heterogeneous particles in selenium. Determination method – laser ultramicroscopy
ILIAS, Jaca , Spain 5 of December 2006 Distillation method:One – Stage (Simple) distillation
Multi-Stage methods 1. Repeated simple distillation of purified product from previous stages. 2. Rectification – multi-stage counter – current method, realized in one apparatus and in one process.
Impurity Content Impurity Content Na 3.00E-08 Al <6.00E-04 Fe <4.00E-04 Mg <3.00E-04 Mn <1.00E-04 P <1.00E-04 Sn <7.00E-05 Ni <7.00E-05 Te <6.00E-05 Bi <4.00E-05 Pb <4.00E-05 As <2.00E-05 Rb <6.00E-06 Sb <2.00E-06 W <3.00E-07 Ta <2.00E-07 Ir <2.00E-07 Au <4.00E-08 K <1.00E-08 Zn <5.00E-09 Cr <4.00E-09 Ag <2.00E-09 Co <8.00E-10 Cs <2.00E-10 Cd <2.00E-10 Hf <1.00E-10 Cu <1.00E-10 Sc <6.00E-11 Ga <4.00E-11 La <1.00E-11 U <9.00E-12 Impurity content, (at %), in Se, purified by rectification Determination method of impurity content – activation analysis 10-4 at% - 1 at. ppm 10-7 at% - 1 at. ppb 10-10 at% - 1 at. ppt
ILIAS, Jaca , Spain 5 of December 2006 Organizations/institutes could be involved in purification of 82Se Russia (distillation method): Svetlana (the ECP, Siberia) Kurchatov Institute (Moscow) The IChHPS (Nizhny Novgorod) The Institute of Rare Earths (Moscow) Mendeleev Institute (Moscow) USA (“wet” chemistry): INEEL (Idaho Falls) Coordinator (ILIAS/SuperNEMO): Dominique Lalanne
ILIAS, Jaca , Spain 5 of December 2006 The IChHPS & the IRE:goal and content of work Goal: Foundation and selection of technique for production of high-purity 82Se according to the requirements of SuperNEMO project; its technological realization for production of ~100 kg. Parameters of the product Elementary selenium enriched with 82Se isotope with the content of impurities of Th, Ra (U) 10-10 at.% ( 1 ppt). Requirements to technology -The yield of the product is 90-95% (to be specified during investigations) -Output of technological scheme and equipment is 5-10 kg/cycle -The process instrumentation should preclude the unrecovered losses of 82Se even in force majeur (destruction of equipment) -To exclude the isotopic dilution during purification procedures
ILIAS, Jaca , Spain 5 of December 2006 The IChHPS& the IRE:content of work 1. Thermodynamic and experimental evaluation of chemical and aggregate forms of the limiting impurities and of their relative volatility in selenium produced from SeF6. 2. Experimental verification of purity of Se with natural isotopic composition with respect to the limiting impurities purified by multi-stage vacuum distillation and rectification. Verification of abilities of these methods during production of kilograms amounts of Se extracted from SeF6. 3. Selection of technological process scheme with optimization by numerical methods of the degree of purity, output capacity and reliability. 4. Fabrication of equipment for the process with output capacity of 5-10 kg/cycle. 5. Production of pilot lots, characterization of the product, modifications of the selected scheme and technological modes.
ILIAS, Jaca , Spain 5 of December 2006 Basic stages at development of ultrapurification process 1. Characterization of initial substance (determination of content and nature of impurities). 2. Development of analytical method(s) to control limited impurities with necessary detection limit. 3. Choice of purification method; a priori calculation of apparatus and mode of operation. Fabrication of apparatus. 4. Preliminary experiments on purification. 5. Correction of apparatus construction and mode their operation. 6. Final experiments on ultrapurification. Characterization of high-purity products.
ILIAS, Jaca , Spain 5 of December 2006 Last stage of Se purification and Rn extraction
ILIAS, Jaca , Spain 5 of December 2006 Conclusion • At present the only technology for 82Se production is centrifugation method and only site for 100 kg- scale production is Svetlana (the ECP, Siberia) • “Chemical features” of impurities in such a product (chemical forms): fluorine compounds. • Multi-stages distillation and rectification methods of purification: the IChHPS and the IRE are ready to start purification of Se in the framework of ILIAS. • Quality control with “champagne” method could be easy organize at very last stage of the purification procedure