WO2013192065A1 - Refining process for producing low alpha tin - Google Patents

Refining process for producing low alpha tin Download PDF

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Publication number
WO2013192065A1
WO2013192065A1 PCT/US2013/046064 US2013046064W WO2013192065A1 WO 2013192065 A1 WO2013192065 A1 WO 2013192065A1 US 2013046064 W US2013046064 W US 2013046064W WO 2013192065 A1 WO2013192065 A1 WO 2013192065A1
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Prior art keywords
tin
alpha particle
alpha
electrolytic solution
ion exchange
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PCT/US2013/046064
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English (en)
French (fr)
Inventor
Paul P. SILINGER
Mark B. Fery
Brett M. Clark
Derek E. GROVE
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Honeywell International Inc.
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Publication of WO2013192065A1 publication Critical patent/WO2013192065A1/en

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    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25CPROCESSES FOR THE ELECTROLYTIC PRODUCTION, RECOVERY OR REFINING OF METALS; APPARATUS THEREFOR
    • C25C1/00Electrolytic production, recovery or refining of metals by electrolysis of solutions
    • C25C1/14Electrolytic production, recovery or refining of metals by electrolysis of solutions of tin

Definitions

  • the present invention relates to high purity tin with reduced alpha particle emissions for the manufacture of semiconductor equipment or the like and manufacturing methods for producing such high purity tin.
  • solders are commonly utilized in semiconductor device packaging and many other electronic applications. While conventional solders have been
  • solders manufactured primarily from lead, more recent lead-free solders utilize tin and other metals as principal components.
  • alpha particle emitting isotopes also referred to as alpha particle emitters
  • Alpha particle emissions can cause damage to packaged electronic devices, and more particularly, can cause soft error upsets and even device failure in certain cases. This concern is compounded as device sizes are reduced and alpha emitting solder materials are closer to sensitive locations.
  • Uranium and thorium are well known as principal radioactive elements often present in metallic containing solders, such as tin solders, which may radioactively decay according to known decay chains to form alpha particle emitting isotopes.
  • metallic containing solders such as tin solders
  • tin solders which may radioactively decay according to known decay chains to form alpha particle emitting isotopes.
  • polonium-210 210 Po
  • Lead-210 ( 210 Pb) is a decay daughter of uranium-238 ( 238 U), has a half-life of 22.3 years, and ⁇ -decays to bismuth-210 ( 210 Bi).
  • 210 Bi due to the very short 5.01 day half-life of 210 Bi, such isotope is essentially a transient intermediary which rapidly decays to 210 Po.
  • the 210 Po has a 138.4 day half-life and decays to the stable lead-206 ( 206 Pb) by emission of a 5.304 MeV alpha particle. It is the latter step of the 210 Pb decay chain, namely, the decay of 210 Po to 206 Pb with release of an alpha particle that is of most concern in metallic materials used in electronic device applications.
  • 210 Po and/or 210 Pb may be at least in part removed by melting and/or refining techniques, such isotopes may remain as impurities in a tin material even after melting or refining. Removal of 210 Po from a tin material results in a temporary decrease in alpha particle emissions from the material. However, it has been observed that alpha particle emissions, though initially lowered, will typically increase over time to potentially unacceptable levels as the secular equilibrium of the 210 Pb decay profile is gradually restored based on any 210 Pb remaining in the metallic material.
  • a method for purifying tin includes exposing an electrolytic solution comprising tin to an ion exchange resin and depositing electrorefined tin from the electrolytic solution.
  • the electrorefined tin can have alpha particle emissions of less than about 0.01 counts/hour/cm 2 or less than about 0.002 counts/hour/cm 2 .
  • the ion exchange resin may include sulfonated, phosphomethylated, amino methyl phosphonic acid, and poly(4-vinyl-pyridine) functional groups and combinations of these functional groups.
  • the electrolytic solution may have a pH of less than about 6 or about 1 or less.
  • the method for purifying tin may further include assessing the alpha particle emission potential of the electrorefined tin, including detecting alpha particle emissions from a sample of the deposited electrorefined tin, determining a concentration of a target parent isotope in the sample from the alpha particle emissions detected in the detecting step and a time which has elapsed between the detecting step and the exposing and detecting steps, and determining a possible alpha emission of a target decay isotope of the target parent isotope from the determined concentration of the target parent isotope and the half-life of the target parent isotope.
  • Figure 1 is a block diagram of an electrorefining system.
  • Figure 2 is a plot of alpha particle emissions over time for
  • tin may be electrorefined to produce refined tin having reduced alpha particle emissions or alpha flux when measured after the electrorefining process.
  • the alpha particle emissions do not necessarily remain stable after the material has been subjected to an electrorefining process, and the alpha particle emissions may increase or decrease over time.
  • the refined tin may also have reduced alpha particle emissions when measured a period of time following the electrorefining process, such as 90 days after the electrorefining process.
  • a method for determining the alpha particle emission potential, such as the maximum alpha particle emissions, for a refined tin is also described herein.
  • Tin may be electrorefined by depositing tin ions from an electrolytic solution onto a cathode by applying a current to the system.
  • An electrolytic solution containing tin or stannous ions may be formed by dissolving or leaching tin in an acid electrolyte.
  • tin sulfate can be formed by an electrolytic dissolution of a 99.99% purity tin anode in an electrolyte including 1 % to 10% sulfuric acid by volume mixed with deionized water.
  • Suitable concentrations of soluble stannous ion in the electrolytic solution include but are not limited to from about 10 g/L to about 200 g/L.
  • suitable concentrations of soluble stannous ion in the electrolytic solution may be as low as 10, 20, 30, 40, 50, 60 g/L or as great as 80, 100, 120, 140, 160, 180 or 200 g/L or may be within any range delimited by any pair of the foregoing values.
  • tin concentrations such as 40, 30, 20 g/L or less, the alpha particle emissions of the deposited material may be more sensitive to the current density of the electrorefining process than at higher tin concentrations
  • the electrolytic solution may be formed by adding a commercially available tin, such as commercially available tin having a purity level of 99.0% to 99.999% (2N to 5N), to the acidic electrolyte.
  • a commercially available tin such as commercially available tin having a purity level of 99.0% to 99.999% (2N to 5N)
  • the tin may have initial, pre-refining alpha particle emissions above about 0.001 counts/hour/cm 2 .
  • the tin may have initial, pre-refining alpha particle emissions above about 0.002 counts/hour/cm 2 , above about 0.005 counts/hour/cm 2 , or above about 0.01 counts/hour/cm 2 .
  • the electrolytic solution may include one or more acids. Suitable acids for use in the acidic electrolytic solution include but are not limited to hydrochloric acid, sulfuric acid, fluoroboric acid, acetic acid, methane sulfonic acid, and sulfamic acid.
  • the acid may be mixed with water, such as diionized water.
  • the acid(s) of the electrolytic solution can be selected to control the pH of the electrolytic solution.
  • the electrolytic solution may have a low, or acidic, pH.
  • an electrolytic solution having an acidic pH may have a pH of less than 7.
  • the electrolytic solution may have a pH of less than about 6.
  • the electrolytic solution may have a pH of less than about 5.
  • the electrolytic solution may have a pH of less than about 4, less than about 3, less than about 2 or less than about 1 .
  • the pH of the electrolytic solution may be adjusted to optimize the effectiveness of the ion exchange resin and the electrorefining process.
  • the electrolytic solution may optionally include one or more additives.
  • an "additive" refers to a component of the electrolytic solution other than the target metal to be refined (e.g., tin), other metallic impurity components, and the acid/water solution.
  • the additive may be helpful for controlling one or more properties of the electrolytic solution, the deposition process and/or the deposited product.
  • Each additive may be present in amount from several parts-per-million (ppm) to several percent by weight. For example, each additive may be present in an amount of at least about 0.05% by volume of the electrolytic solution, at least about 0.5% by volume of the electrolytic solution, or at least about 1 .0% by volume of the electrolytic solution.
  • Suitable additives include antioxidants and grain refiners.
  • an antioxidant may be added to the electrolytic solution to prevent spontaneous Sn 2+ to Sn 4+ oxidation during electrolysis.
  • Suitable antioxidants include, but are not limited to, phenol sulfonic acid and hydroquinone.
  • Suitable commercially available antioxidants include Technistan Antioxidant, Techni Antioxidant Number 8 available from Technic, and Solderon BP Antioxidant available from Dow Chemical.
  • Suitable concentrations of an antioxidant include from about 0.05% to about 10%, from about 0.5% to about 5%, or from about 1 % to about 3% by volume of the electrolytic solution.
  • An organic grain refiner may optionally be added to the electrolytic solution to limit dendritic deposition at the cathode.
  • Suitable organic grain refiners include, but are not limited to, polyethylene glycol.
  • Suitable commercially available organic grain refiners include Technistan TP-5000 Additive, Techni Matte 89-TI available from Technic, and Solderon BP Primary available from Dow Chemical.
  • Suitable concentrations of a grain refiner include from about 0.5% to about 20%, from about 1 .0% to about 15%, or from about 3% to about 10% by volume of the electrolytic solution.
  • Ion exchange resins are organic compounds which include functional groups configured to selectively capture another material by exchanging ions with the captured material.
  • ion exchange resins may include functional groups bonded to a polymer matrix.
  • the ion exchange resin captures and removes alpha emitting impurities from the electrolytic solution, such as metallic impurities and, in particular, metallic impurities which are either themselves capable of decay with concurrent release of an alpha particle, such as 210 Po, or metallic impurities which produce decay products with the decay products capable to decay with concurrent release of an alpha particle, such as U and/or Th.
  • the ion exchange resin may be placed in a column and the electrolytic solution may be circulated through the column.
  • the electrolytic solution may be circulated from a tank, through the ion exchange resin column and returned to the tank by a pump.
  • the electrolytic solution may be circulated through the column of ion exchange resin concurrently with application of current to the electrolytic bath, or alternatively, the circulation of the electrolytic solution through the ion exchange resin may occur prior to, or after, application of current according to a desired quantify and/or duration.
  • circulation of the electrolytic solution through the ion exchange resin and application of current may be alternated as desired.
  • the flow rate through the column may be adjusted to achieve a desired contact time between the electrolytic solution and the ion exchange resin.
  • the resin may be added directly to the tank holding the electrolytic solution; a separate column is not used.
  • Suitable ion exchange resins may include at least functionalized carboxylic acid from the phosphonic acids group, such as amino methyl phosphonic acid functional groups. Further suitable ion exchange resins may include at least one functional group selected from sulfonated, phosphomethylated, amino methyl phosphonic acid, and poly(4-vinyl-pyridine) functional groups and mixtures thereof.
  • suitable ion exchange resins may include at least one functional group selected from sulfonated, phosphomethylated, amino methyl phosphonic acid, poly(4-vinyl-pyridine), sulfonic acid, chloromethyl, tributylamine, di-vinyl benzene, quaternary amine, divinylbenzene, diphosphonic acid, and iminodiacetate functional groups.
  • suitable ion exchange resins are presented in Table 1 , where "DVB” is divinylbenzene, "SB” is strong base, “SA” is strong acid, “WA” is weak acid, and “Dow” is Dow Chemical Company.
  • An ion exchange resin may be used alone or in combination with other ion exchange resins.
  • a mixed bed resin may be used, where a mixed bed resin refers to a resin composition that includes two or more specific resins that may have the same or different functional groups, exchange mechanisms and/or matrices.
  • Tin from the electrolytic solution is plated onto a cathode during the electrorefining process.
  • exposing the electrolytic solution to the ion exchange resin and electrodeposition of the tin onto the cathode may occur at least partially concurrently.
  • the electrorefined tin may have reduced alpha particle emissions or alpha flux.
  • FIG. 1 is a block diagram illustrating an exemplary continuous tin electrorefining system 100 including tank 1 10, cathode 1 12, first tin anode 1 14A and second tin anode 1 14B (collectively referred to as tin anodes 1 14), media column 1 16, pump 1 18, filter 120, pump 122, and rectifier 124, which is capable of generating the required current density.
  • tin anodes 1 14 One or more cathodes 1 12 and one or more tin anodes 1 14 are positioned in tank 1 10. As shown in Figure 1 , tin anodes 1 14 may be placed on either side of cathode 1 12.
  • Tank 1 10 also contains an electrolytic solution containing tin, which has been described above.
  • System 100 may also include filter 120.
  • the electrolytic solution from tank 1 10 may be pumped through filter 120 by pump 122 and returned back to tank 1 10.
  • Filter 120 may filter particulate matter from the solution. For example, filter 120 may remove material have a size greater than about 5 microns.
  • Rectifier 124 is connected to cathode 1 12 and anodes 1 14 and provides the required current density for dissolution of tin anodes 1 14 and
  • a suitable current density at the cathode may be as low as 10, 15, 20, 25, 30, 35, 40 amps per square foot (ASF) or as great as 25, 30, 35, 40, 45, 50, 55, 60, 65 or 70 ASF or may be within any range delimited by any pair of the foregoing values.
  • the current density at the cathode may be as low as 70, 80, 90, 100, 125 or 150 ASF or as great as 175, 200, 225, 250, 275 or 300 ASF or may be within any range delimited by any pair of the foregoing values.
  • the current density was regulated at about 22 milliamps per square centimeter (mA/cm 2 ) (20 ASF) at cathode 1 12 and about 8-1 1 mA/cm 2 (7-10 ASF) at anodes 1 14.
  • the tin may be refined in a continuous process as described above. For example, the steps of exposing the electrolytic solution to an ion exchange resin and depositing the tin from the electrolytic solution onto a cathode may occur at least partially concurrently.
  • the tin may be refined in a step or batch process.
  • an electrolytic solution may be formed by electrolytic dissolution of tin anodes and a permeable membrane may be used to prevent tin from depositing on the cathode.
  • the dissolution may then be stopped, and the electrolytic solution may be exposed to an ion exchange resin for a period of time.
  • the electrolytic solution may be passed through a column containing the ion exchange resin or the ion exchange resin may be added to the electrolytic solution tank. After exposure to the ion exchange resin, the electrolytic solution may be electrodeposited onto a cathode.
  • the eletrorefining system may include two or more electrodeposition processes.
  • Each electrodeposition process may include the same or different electrolytic solution compositions.
  • the electrolytic solutions may include the same or different acids and/or additive(s) and/or have the same or different pH.
  • One or more of the electrodeposition processes may including an ion exchange resin as described herein, and if present in two or more of the processes, the ion exchange resin may be the same or different.
  • two or more electrodeposition processes may be conducted in series or in succession such that tin ions are electrodeposited two or more times.
  • the electrorefining system may include electrodepositing tin ions from an electrolytic solution containing hydrochloric acid onto a cathode, electrolytic dissolution of the deposited tin into a second electrolytic solution containing sulfuric acid, and electrodepositing tin ions from the second electrolytic solution onto a second cathode.
  • Impurities and/or contaminant components may be removed in each successive electrodeposition process. Further, different impurities and/or contaminant components may be removed based on the electrolytic solution composition and/or the ion exchange resin of the electrodeposition process.
  • the electrorefined tin may not experience a significant reduction in lead content compared to that of the tin prior to the electrorefining process (e.g., the input or pre-refined tin).
  • the lead content may not be reduced by more than about 1 % and particularly not by more than about 0.1 % by the electrorefining process.
  • a suitable lead content of the tin prior to the electrorefining process may be at least 1 ppm and more particularly at least about 2 ppm.
  • a suitable lead content of the electrorefined tin may be at least about 1 ppm and more particularly at least about 2 ppm.
  • the lead content of the electrorefined tin may be as low as 0.01 , 0.05 or 1 .0 ppm or as great as 2.0, 5.0 or 10.0 ppm or may be within any range delimited by any pair of the foregoing values.
  • electrodeposited tin which is produced by exposing the electrolytic solution to at least one ion exchange resin during electrorefining has reduced alpha particle emissions or alpha flux.
  • tin material having less than 1 ppm thorium will not necessarily have a sufficient low alpha particle emissions or alpha flux to satisfy certain industry requirements.
  • electrorefined tin may be tested for alpha particle emissions after refining using, for example, a gas flow proportional counter such as an Alpha Sciences 1950 in the manner described in JEDEC standard JESD221 .
  • the overall reduction in alpha particle emissions will vary depending on many factors including, but not limited to, the alpha particle emissions of the input or pre-refined tin material, the contact time of the electrolytic solution with the ion exchange resin, and the number of passes of the electrolytic solution through the ion exchange resin.
  • the alpha particle emissions of the refined tin material is reduced by at least 50%, more particularly at least 75%, and even more particularly at least 85%, 90% or 95% compared to the alpha particle emissions of the same material prior to deposition of the electrorefined tin.
  • electrorefining is carried out under conditions suitable to reduce the alpha particle emissions of the refined tin material to less than about 0.01 counts/hour/cm 2 , more particularly less than about 0.002 counts/ hour/cm 2 , and even more particularly less than about 0.001 counts/hour/cm 2 .
  • alpha particle emissions of tin does not necessarily remain stable after the material has been refined.
  • alpha particle emissions or alpha flux of the refined tin may increase or decrease over time due to the residual presence and radioactive decay of various elements such as 210 Pb.
  • the increase or decrease of alpha particle emissions over time may be referred to as alpha drift.
  • the electrorefining process including an ion exchange resin reduce the alpha particle emissions of the electrorefined tin immediately after the electrorefining process but it also results in reduced alpha drift and reduces the alpha particle emissions at a period of time after the electrorefining process.
  • the alpha particle emissions of the refined tin 90 days after the electrorefining process is at least 50%, more particularly at least 75%, and even more particularly at least 85%, 90% or 95% less than the alpha particle emissions of the same material prior to electrorefining.
  • the electrorefining is carried out under conditions suitable to reduce the alpha particle emissions of the electrorefined tin to less than about 0.01 counts/hour/cm 2 , more particularly less than about 0.002 counts/hour/cm 2 and even more particularly less than about 0.001 counts/hour/cm 2 , when measured 90 days after the electrorefining process.
  • a method for determining the alpha particle emission potential of the electrorefined tin, such as the maximum alpha particle emissions from the tin, is described herein.
  • the described method for example, can be used to predict or forecast the maximum alpha particle emissions from the tin.
  • target parent isotope refers to an isotope of interest which is present in a metallic material and is able to decay to a daughter isotope, wherein the daughter isotope may subsequently alpha-decay, i.e., may decay to a further isotope with concomitant emission of an alpha particle.
  • target decay isotope refers to an isotope of interest which is a daughter isotope of the target parent isotope and itself may subsequently alpha- decay, i.e., may decay to a further isotope with concomitant emission of an alpha particle.
  • the target decay isotope may or may not be itself a direct decay product of the target parent isotope.
  • 210 Pb is a target parent isotope
  • 210 Po may be a target decay isotope even though 210 Pb decays to 210 Bi with subsequent decay
  • the metallic material e.g., tin
  • a secular equilibrium disruption process refers to a process to which the metallic material is subjected which at least partially disrupts the secular equilibrium of the decay profile of at least one target parent isotope within the metallic material. In most instances, the secular equilibrium disruption process disrupts the secular equilibrium of the decay profile of a target parent isotope by reducing the secular equilibrium disruption process.
  • the electrorefining process described herein is an exemplary secular equilibrium disruption process.
  • Other exemplary secular equilibrium disruption processes include melting, casting, smelting, refining (such as electro-chemical refining, chemical refining, zone refining, and vacuum distillation).
  • a secular equilibrium disruption process may also include any combination of two or more of the foregoing processes.
  • both the target parent isotopes and the target decay isotopes are at least partially removed as impurities by physical and/or chemical separation from the bulk metallic material.
  • the secular equilibrium disruption process may remove substantially all of a given target decay isotope and thereby effectively "reset" the secular equilibrium of the corresponding target parent isotope.
  • the secular equilibrium disruption process may substantially completely remove all of the 210 Po target decay isotope in the material, such that the secular equilibrium of 210 Pb is effectively reset, wherein substantially all 210 Po that is present in the material following the secular equilibrium disruption process is generated by decay of 210 Pb after the said disruption process.
  • the present process may also be practiced using secular equilibrium disruption processes that remove only a portion of the target parent isotope and/or target decay isotope, and the present process is not limited to secular equilibrium disruption processes that remove substantially all of a given target decay isotope.
  • the secular equilibrium disruption process may be completed in a relatively short amount of time and, in other embodiments, the secular equilibrium disruption processes may require a relatively greater amount of time for completion, depending on the nature of the process and the number of processes that together may constitute the secular equilibrium disruption process. Therefore, the elapsed time discussed below, between the secular equilibrium disruption process and the measurement of alpha particle emissions of the metallic material, may be an elapsed time between the completion of the secular equilibrium disruption process (or processes) and the measurement of alpha particle emissions of the metallic material. [0040] After the metallic material (e.g., tin) is subjected to the secular equilibrium disruption process, the alpha particle emission of the metallic material is detected, i.e., an alpha particle emission measurement is obtained. Although it is within the scope of the present disclosure to obtain an alpha particle emission of the entire metallic material in bulk form, typically a sample of the bulk metallic material will be obtained for purposes of alpha particle emission analysis.
  • the metallic material e.g., tin
  • a relatively thin portion of the bulk metallic material may be obtained as a sample by a suitable method such as rolling the bulk metallic material to provide a thin sheet of sample material, or by any other another suitable method.
  • the sample is treated by heat in order to promote diffusion of target decay isotopes in the sample material until such point that the concentration of atoms of the target decay isotopes in the sample is uniform throughout the sample volume. In many samples, there may be a larger
  • concentration of atoms of target decay isotopes toward the center of the sample for example, or otherwise in other areas of the sample such that a concentration mismatch or gradient is present.
  • the heat treatment removes any such
  • concentration mismatches or gradients by promoting diffusion of atoms of target decay isotopes within the sample from areas of relatively higher concentration toward areas of relatively lower concentration such that a uniform concentration of target decay isotopes is obtained within the sample.
  • the number of atoms of target decay isotopes within a detection limit depth of the alpha particle detection process will be representative of and, more particularly will correlate directly to, the uniform concentration of atoms of target decay isotopes in the entirety of the sample.
  • Such uniform concentration is achieved when the chemical potential gradient of the target decay isotopes is substantially zero and the concentration of the target decay isotopes is substantially uniform throughout the sample.
  • the test sample may have a chemical potential gradient, in that the concentration of target decay isotopes is higher on one side of the sample than another side of the sample, or at the centroid of the sample than at the outer surfaces of the sample. Heating of the sample adjusts the chemical potential gradient and, at a sufficient time and temperature exposure, the chemical potential gradient is substantially zero and the concentration of the target decay isotopes is substantially uniform throughout the sample.
  • detection limit depth refers to a distance within a given metallic material through which an emitted alpha particle may penetrate in order to reach a surface of the material and thereby be released from the material for analytical detection.
  • Detection limit depths for 210 Po in selected metallic materials are provided in Table 2 below, in microns, which is based on the penetration of the 5.304 MeV alpha particle released upon decay of 210 Po to 206 Pb:
  • the detection limit depth for alpha particles of differing energy such as alpha particles emitted upon radioactive decay of alpha particle-emitting isotopes other than 210 Po, will vary, with the detection limit depth generally proportional to the energy of the alpha particle.
  • emitted alpha particles may be detected by use of a gas flow counter such as an XIA 1800-UltraLo gas ionization chamber available from XIA L.L.C. of Hayward, CA according the method described by JEDEC standard JESD 221 .
  • Target decay isotopes such as 210 Po are known to diffuse or migrate within metallic materials and, in this respect, the heat treatment of the present method is used to promote diffusion of the target decay isotope within the material sample to eliminate concentration gradients.
  • target decay isotopes such as 210 Po, will have a diffusion rate J in a given metallic material, which can be expressed according to equation (1 ) below: ⁇ 1
  • ⁇ / ⁇ is the concentration gradient of the target decay isotope, such as 210 Po; and D is the diffusion coefficient.
  • the concentration gradient of the target decay isotope is determined by measuring the alpha particle emissions at the surface of a sample, removing a layer of material of x thickness, such as by chemical etching, and measuring the alpha particle emissions at the x depth.
  • concentration of the target decay isotope at the original surface and at depth x is directly proportional to the alpha particle emission at each surface, and concentration gradient of the target decay isotope is calculated as the difference between the concentration at one of the surfaces and the concentration at depth x over the distance x.
  • A is the alpha particle emission measured in counts/hr.
  • ⁇ 0 In2/138.4 days, based on the half-life of 210 Po.
  • the temperature heating profile to which the sample may be exposed in order to diffuse the target decay isotope within the sample sufficiently to eliminate any concentration gradients, such that detection of alpha particle emissions within the detection limit depth of the sample is representative, and directly correlates, to the concentration of the target decay isotope throughout the sample. For example, for a tin sample having a thickness of 1 millimeter, a heat treatment of 200 °C for 6 hours will ensure that any concentration gradients of 210 Po atoms within the sample are eliminated.
  • the application of heat may be selected and controlled by time and temperature exposure of the sample to ensure that atoms of a target decay isotope are diffused to a sufficient extent to eliminate concentration gradients. It has been found that, by the present method, in providing a suitable time and temperature profile for the heat treatment step, measurement of alpha particle emissions from a target decay isotope present within the detection limit depth directly corresponds to the concentration or number of target decay isotope atoms within the entirety of the sample.
  • the alpha particle emissions attributable to 210 Po is expressed as polonium alpha activity, A Po , at a time (t) following the secular equilibrium disruption process. From the A Po and elapsed time (t), the concentration of 210 Pb atoms in the sample can be calculated using equation (3):
  • ⁇ 0 In2/138.4 days, based on the half-life of 210 Po;
  • time (t) is the time which has elapsed between the secular equilibrium disruption process and the alpha particle emission measurement.
  • the 210 Pb concentration is substantially constant over the time (t), particularly when the time (t) is less than three years,. Also, when substantially all of the 210 Po is removed in the secular equilibrium disruption process (which may be the case when the secular equilibrium disruption process is a strenuous refining process, for example) the last term in equation (3) above is very near to zero because the initial 210 Po concentration will be very near to zero when the alpha particle emissions are measured relatively soon after the secular equilibrium disruption.
  • the concentration of the target parent isotope may be calculated by the above-equation (3) and, once the concentration of the target parent isotope is calculated, the known half-life of the target parent isotope may be used to provide an assessment or prediction of a maximum concentration of the target decay isotope within the material based on the re-establishment of the secular equilibrium profile of the target parent isotope.
  • the maximum 210 Po activity directly correlates to a maximum alpha particle emission of the material, and will occur at 828 days from the secular equilibrium disruption process.
  • the calculated maximum concentration of the target decay isotope and concomitant alpha particle emission will typically be a maximum future concentration of the target decay isotope and concomitant alpha particle emission that the metallic material will exhibit over a timeframe which corresponds to the half- life of the target parent isotope.
  • the present method after a metallic material has been subjected to a secular equilibrium disruption process such as by refining the metallic material, a maximum alpha particle emission that the metallic material will reach during the useful life of the material may be accurately predicted.
  • the present method provides a valuable prediction of the maximum alpha particle emission for metallic materials, such as solders, that are incorporated into electronic devices.
  • Monophos resin an ion exchange resin having sulfonated and phosphomethylated functional groups and available from Eichrom.
  • Lewatit MonoPlus TP 260 an ion exchange resin having amino methyl phosphonic acid functional groups and available from Lanxess.
  • Reillex HPQ Polymer an ion exchange resin having poly(4-vinyl- pyridine) functional groups and available from Vertellus.
  • An electrolytic solution was added to a 30 liter (L) polypropylene tank equipped with a vertical pump for solution agitation and filtration.
  • a central titanium cathode and two 4N tin anodes (one on each side of the cathode) were positioned in the tank, and a DC power supply was connected to the cathode and anodes for generating the required current density.
  • the DC current passing between the cathode and anodes was regulated to 22 mA/cm 2 (20 ASF) at the cathode and 8-1 1 mA cm 2 (7-10 ASF) at each anode.
  • An ion exchange resin was prewashed with at least 10 bed volumes of deionized water and placed in a glass column.
  • the glass column had a diameter of approximately 1 inch and contained approximately 77.0 cubic centimeters (4.7 cubic inches) of the ion exchange resin.
  • the electrolytic solution was continuously circulated through the glass column by a magnetically coupled 1/250 HP Iwaki pump during the electrorefining process at a flow rate between 100 and 500 ml. per minute.
  • the tin was electrorefined for three days, and then harvested from the cathode. The harvested tin was rinsed for five minutes with deionized water having a purity of 5 megaohms per centimeter. The electrorefined tin was then dried for 15 minutes at 150°C, and cast at 300°C-350°C. Three crops were harvested for each example. A sample was taken from each crop, and analyzed by an Alpha Sciences 1950 alpha counter in the manner described in JEDEC standard JESD221 and a Varian Vista Pro inductive coupled plasma atomic emission spectroscopy (ICP-AES) for trace elements.
  • ICP-AES Varian Vista Pro inductive coupled plasma atomic emission spectroscopy
  • the Control did not include an ion exchange resin in the electrorefining process.
  • a sulfuric acid electrolyte was formed by mixing 3% sulfuric acid by volume with deionized water. Tin from the anodes was electrolytically dissolved from high purity tin anodes in the sulfuric acid electrolyte to form a 15 g/L solution.
  • Technistan Antioxidant an antioxidant
  • Technistan TP-5000 additive an organic grain refiner
  • Electrolysis was performed at 20°C using a cathode current density of 22 mA/cm 2 (20 ASF). The cathodes were harvested after 72 hours. The tin was cast. The casts were analyzed by the Alpha Sciences 1950 alpha counter (in the manner described in JEDEC standard JESD221 ) and the Varian Vista Pro ICP-AES. The mean alpha particle emissions (in counts/hour/cm 2 ) and standard deviation ("SD”) based on three samples are shown in Table 4 as measured immediately after casting ("refined alpha") and after storage for at least 90 days ("alpha after 90 days”).
  • Samples 1 -3 included an ion exchange resin in the electrorefining process.
  • An electrolytic solution containing sulfuric acid, deionized water, tin, Technistan Antioxidant and Technistan TP-5000 was prepared as described above for the Control.
  • Electrolysis was performed at 20°C using a cathodic current density of 22 mA/cm 2 (20 ASF). Electrolytic solution from the main tank was pumped through the glass column which contained the designated ion exchange resin at the designated flow rate.
  • the ion exchange resin and flow rates are presented in Table 5.
  • the cathodes were harvested after 72 hours from the start of the electrorefining process.
  • the electrorefined tin was cast, and the casts were analyzed by the Alpha Sciences 1950 alpha counter (in the manner described in JEDEC standard JESD221 ) and the Varian Vista Pro ICP-AES.
  • the mean alpha particle emissions (counts/hour/cm 2 ) and standard deviation ("SD") for three samples as measured immediately after casting ("refined alpha") and at least 90 days after casting (“alpha after 90 days”) are shown in Table 6.
  • the percent reduction (“% reduct.") of mean alpha particle emissions based on the starting alpha particle emissions is also shown.
  • Electrorefining did not significantly change the lead content in Samples 1 -3. Further, any measured change in lead content is within the experimental margin of error.
  • Samples 4-20 included an ion exchange resin in the electrorefining process.
  • An electrolytic solution containing sulfuric acid, deionized water, tin, Technistan antioxidant and Technistan TP-5000 was prepared as described above for the Control.
  • Electrolysis was performed at 20°C using a cathodic current density of 22 mA/cm 2 (20 ASF). Electrolytic solution from the main tank was pumped through the glass column which contained the designated ion exchange resin at the designated flow rate.
  • the ion exchange resin, flow rates (mL/min), alpha particle emissions (counts/hour/cm 2 ), including mean and standard deviation (“SD”) are presented in Table 8.
  • the lead content of the samples were analyzed before (e.g., pre- refining) and after (e.g., post-refining) electrorefining by the Varian Vista Pro ICP- AES. Three samples, or lots, were analyzed for each resin tested.
  • the lead content for Samples 4-20 are provided in Table 9.
  • Electrolytic solutions containing sulfuric acid, deionized water, tin, Technistan Antioxidant and Technistan TP-5000 were prepared as described above for the Control.
  • the electrolytic solution from the main tank was pumped through the glass column containing Lewatit MonoPlus TP 260 ion exchange resin.
  • the tin was deposited at 20°C and onto a cathode having an active area of 72 square inches.
  • the tin concentration of the electrolytic solution, the cathodic current in amps and the cathodic current density in ASF for each sample is provided in Table 10.
  • the input or pre-refined tin had alpha particle emissions of 0.048 counts/hour/cm 2 .
  • the post-refined alpha particle emissions and elapsed time between refining and the measurement of alpha particle emissions are shown below in Table 1 1 .
  • the alpha particle emissions were measured at multiple elapsed times for select samples.
  • Table 1 1 also includes percent reduction and the reduction factor of the measured alpha particle emissions as compared to the input or pre-refined alpha particle emissions. The percent reduction was calculated by the difference between the pre-refined and post-refined alpha particle emissions divided by the pre-refined alpha particle emissions. The reduction factor was calculated by the pre-refined alpha particle emissions divided by the post-refined alpha particle emissions. Table 1 1
  • Sample 21 which had the lowest tin concentration and the lowest current density, provided the least reduction in alpha particle emissions.
  • Sample 25 which had the highest tin concentration and the highest current density, provided the greatest reduction in alpha particle emissions.
  • a plot of the alpha particle emissions over time for each sample is provided in Figure 2.
  • a linear trend line was fit to each data set, and the equations are presented in Figure 2.
  • the linear trend line for Sample 22 had a slope of 0.0005, Sample 23 had a slope of 0.0008, Sample 24 had a slope of 0.0005 and Sample 25 had a slope of 0.0003.
  • a linear trend line could not be fit to the data for Sample 21 .
  • the present method was used to assess the maximum potential alpha emissions in eight refined tin samples.
  • the tin samples were refined according to the method described herein.
  • Test samples of the refined tin samples were obtained by cutting an approximately 1 kilogram sample from an ingot and rolling the sample to a thickness of 1 millimeter. The test samples were heated at 200°C for six hours, and the alpha particle emissions of the test samples were measured using an XIA 1800-UltraLo gas ionization chamber available from XIA L.L.C. of Hayward, CA.
  • the measured alpha particle emissions and elapsed times between refining and the measurement of alpha particle emissions are shown below in Table 12.
  • Tin samples were refined according to the method disclosed herein.
  • a test sample of the refined tin sample was obtained by cutting a sample from an ingot and rolling the sample to a thickness of 0.45 millimeter.
  • the test sample was heated at 200C for one hour, and the alpha particle emissions of the test samples were measured using an XIA 1800-UltraLo gas ionization chamber available from XIA L.L.C. of Hayward, CA.
  • Measurement of the alpha particle emissions required about 24 hours, after which the sample was heated for one hour at 200°C and then measured for alpha particle emissions. This process (e.g., heat for one hour followed by measurement of alpha particle emissions) was repeated for a total of five heat/measurement cycles.
  • the measured alpha particle emissions and the total hours the sample was heated at 200°C are shown below in Table 13.
  • the activity or alpha flux of the sample increased from 0.017 counts/hr/cm 2 to 0.025 counts/hr/cm 2 after one hour at 200C. That is, the activity or alpha flux of the tin sample increased more than 50% after one hour at 200°C. As further shown in Table 13, there was no significant change in the activity or alpha flux of the sample when heated for more than one hour at 200°C, suggesting that one hour at 200°C was sufficient to achieve a substantially uniform concentration of the target decay isotopes throughout the sample.

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