Coprecipitation

Last updated December 22, 2023

In chemistry, coprecipitation (CPT) or co-precipitation is the carrying down by a precipitate of substances normally soluble under the conditions employed.^[1] Analogously, in medicine, coprecipitation (referred to as immunoprecipitation) is specifically "an assay designed to purify a single antigen from a complex mixture using a specific antibody attached to a beaded support".^[2]

Coprecipitation is an important topic in chemical analysis, where it can be undesirable, but can also be usefully exploited. In gravimetric analysis, which consists on precipitating the analyte and measuring its mass to determine its concentration or purity, coprecipitation is a problem because undesired impurities often coprecipitate with the analyte, resulting in excess mass. This problem can often be mitigated by "digestion" (waiting for the precipitate to equilibrate and form larger and purer particles) or by redissolving the sample and precipitating it again.^[3]

Typical co-precipitation method for micro and nano particle synthesis Co-precipitation.png — Typical co-precipitation method for micro and nano particle synthesis

On the other hand, in the analysis of trace elements, as is often the case in radiochemistry, coprecipitation is often the only way of separating an element. Since the trace element is too dilute (sometimes less than a part per trillion) to precipitate by conventional means, it is typically coprecipitated with a carrier, a substance that has a similar crystalline structure that can incorporate the desired element. An example is the separation of francium from other radioactive elements by coprecipitating it with caesium salts such as caesium perchlorate. Otto Hahn is credited for promoting the use of coprecipitation in radiochemistry.

There are three main mechanisms of coprecipitation: inclusion, occlusion, and adsorption.^[3] An inclusion (incorporation in the crystal lattice) occurs when the impurity occupies a lattice site in the crystal structure of the carrier, resulting in a crystallographic defect; this can happen when the ionic radius and charge of the impurity are similar to those of the carrier. An adsorbate is an impurity that is weakly, or strongly, bound (adsorbed) to the surface of the precipitate. An occlusion occurs when an adsorbed impurity gets physically trapped inside the crystal as it grows.

Besides its applications in chemical analysis and in radiochemistry, coprecipitation is also important to many environmental issues related to water resources, including acid mine drainage, radionuclide migration around waste repositories, toxic heavy metal transport at industrial and defense sites, metal concentrations in aquatic systems, and wastewater treatment technology.^[4]

Coprecipitation is also used as a method of magnetic nanoparticle synthesis.^[5]

Distribution between precipitate and solution

There are two models describing of the distribution of the tracer compound between the two phases (the precipitate and the solution):^[6]^[7]

Doerner-Hoskins law (logarithmic):

\ln {a \over {a-x}}=\lambda \ln {b \over {b-y}}

Berthelot-Nernst law:

{x \over {a-x}}=D{y \over {b-y}}

where:

a and b are the initial concentrations of the tracer and carrier, respectively;

a − x and b − y are the concentrations of tracer and carrier after separation;

x and y are the amounts of the tracer and carrier on the precipitate;

D and λ are the distribution coefficients.

For D and λ greater than 1, the precipitate is enriched in the tracer.

Depending on the co-precipitation system and conditions either λ or D may be constant.

The derivation of the Doerner-Hoskins law assumes that there in no mass exchange between the interior of the precipitating crystals and the solution. When this assumption is fulfilled, then the content of the tracer in the crystal is non-uniform (the crystals are said to be heterogeneous). When the Berthelot-Nernst law applies, then the concentration of the tracer in the interior of the crystal is uniform (and the crystals are said to be homogeneous). This is the case when diffusion in the interior is possible (like in the liquids) or when the initial small crystals are allowed to recrystallize. Kinetic effects (like speed of crystallization and presence of mixing) play a role.

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In a chemical reaction, chemical equilibrium is the state in which both the reactants and products are present in concentrations which have no further tendency to change with time, so that there is no observable change in the properties of the system. This state results when the forward reaction proceeds at the same rate as the reverse reaction. The reaction rates of the forward and backward reactions are generally not zero, but they are equal. Thus, there are no net changes in the concentrations of the reactants and products. Such a state is known as dynamic equilibrium.

Francium is a chemical element; it has symbol Fr and atomic number 87. It is extremely radioactive; its most stable isotope, francium-223, has a half-life of only 22 minutes. It is the second-most electropositive element, behind only caesium, and is the second rarest naturally occurring element. Francium's isotopes decay quickly into astatine, radium, and radon. The electronic structure of a francium atom is [Rn] 7s¹; thus, the element is classed as an alkali metal.

Half-life is the time required for a quantity to reduce to half of its initial value. The term is commonly used in nuclear physics to describe how quickly unstable atoms undergo radioactive decay or how long stable atoms survive. The term is also used more generally to characterize any type of exponential decay. For example, the medical sciences refer to the biological half-life of drugs and other chemicals in the human body. The converse of half-life is doubling time.

Solubility equilibrium is a type of dynamic equilibrium that exists when a chemical compound in the solid state is in chemical equilibrium with a solution of that compound. The solid may dissolve unchanged, with dissociation, or with chemical reaction with another constituent of the solution, such as acid or alkali. Each solubility equilibrium is characterized by a temperature-dependent solubility product which functions like an equilibrium constant. Solubility equilibria are important in pharmaceutical, environmental and many other scenarios.

In electrochemistry, the Nernst equation is a chemical thermodynamical relationship that permits the calculation of the reduction potential of a reaction from the standard electrode potential, absolute temperature, the number of electrons involved in the redox reaction, and activities of the chemical species undergoing reduction and oxidation respectively. It was named after Walther Nernst, a German physical chemist who formulated the equation.

Zone melting is a group of similar methods of purifying crystals, in which a narrow region of a crystal is melted, and this molten zone is moved along the crystal. The molten region melts impure solid at its forward edge and leaves a wake of purer material solidified behind it as it moves through the ingot. The impurities concentrate in the melt, and are moved to one end of the ingot. Zone refining was invented by John Desmond Bernal and further developed by William G. Pfann in Bell Labs as a method to prepare high-purity materials, mainly semiconductors, for manufacturing transistors. Its first commercial use was in germanium, refined to one atom of impurity per ten billion, but the process can be extended to virtually any solute–solvent system having an appreciable concentration difference between solid and liquid phases at equilibrium. This process is also known as the float zone process, particularly in semiconductor materials processing.

<span class="mw-page-title-main">Czochralski method</span> Method of crystal growth

The Czochralski method, also Czochralski technique or Czochralski process, is a method of crystal growth used to obtain single crystals of semiconductors, metals, salts and synthetic gemstones. The method is named after Polish scientist Jan Czochralski, who invented the method in 1915 while investigating the crystallization rates of metals. He made this discovery by accident: instead of dipping his pen into his inkwell, he dipped it in molten tin, and drew a tin filament, which later proved to be a single crystal. The method is still used in over 90 percent of all electronics in the world that use semiconductors.

The third law of thermodynamics states that the entropy of a closed system at thermodynamic equilibrium approaches a constant value when its temperature approaches absolute zero. This constant value cannot depend on any other parameters characterizing the system, such as pressure or applied magnetic field. At absolute zero the system must be in a state with the minimum possible energy.

Nuclear chemistry is the sub-field of chemistry dealing with radioactivity, nuclear processes, and transformations in the nuclei of atoms, such as nuclear transmutation and nuclear properties.

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Gravimetric analysis describes a set of methods used in analytical chemistry for the quantitative determination of an analyte based on its mass. The principle of this type of analysis is that once an ion's mass has been determined as a unique compound, that known measurement can then be used to determine the same analyte's mass in a mixture, as long as the relative quantities of the other constituents are known.

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The Langmuir adsorption model explains adsorption by assuming an adsorbate behaves as an ideal gas at isothermal conditions. According to the model, adsorption and desorption are reversible processes. This model even explains the effect of pressure i.e. at these conditions the adsorbate's partial pressure, $, is related to the volume of it, V, adsorbed onto a solid adsorbent. The adsorbent, as indicated in the figure, is assumed to be an ideal solid surface composed of a series of distinct sites capable of binding the adsorbate. The adsorbate binding is treated as a chemical reaction between the adsorbate gaseous molecule and an empty sorption site, S . This reaction yields an adsorbed species with an associated equilibrium constant :$

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<span class="mw-page-title-main">Vitaly Khlopin</span> Russian chemist (1890–1950)

Vitaly Grigorievich Khlopin was a Russian and Soviet scientist- radiochemist, professor, academician of the USSR Academy of Sciences (1939), Hero of Socialist Labour (1949), and director of the Radium Institute of the USSR Academy of Sciences (1939-1950). He was one of the founders of Soviet radiochemistry and radium industry, received the first domestic radium preparations (1921), one of the founders of the Radium Institute and leading participants in the atomic project and founder of the school of Soviet radiochemists.

References

↑ Patnaik, P. (2004). Dean's Analytical Chemistry Handbook, 2nd ed. McGraw-Hill.
↑ "Immunoprecipitation (IP) technical guide and protocols" (PDF). Thermo Scientific. Retrieved 21 December 2023.
1 2 Harvey, D. (2000). Modern Analytical Chemistry. McGraw-Hill.
↑ "Cosis.net" (PDF). www.cosis.net. Retrieved May 10, 2007.
↑ Lu, A.-H., Salabas, E. L. and Schüth, F. (2007). Angew. Chem. Int. Ed., 46,1222–1244.
↑ Otto Hahn, "Applied Radiochemistry", Cornell University Press, Ithaca, New York, USA, 1936.
↑ ALAN TOWNSHEND and EWALD JACKWERTH, "PRECIPITATION OF MAJOR CONSTITUENTS FOR TRACE PRECONCENTRATION : POTENTIAL AND PROBLEMS", Pure & App. Chem., Vol.61, No.9, pp. 1643-1656, 1989., (pdf)

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[1] Patnaik, P. (2004). Dean's Analytical Chemistry Handbook, 2nd ed. McGraw-Hill.

[2] "Immunoprecipitation (IP) technical guide and protocols" (PDF). Thermo Scientific. Retrieved 21 December 2023.

[harvey-3] 1 2 Harvey, D. (2000). Modern Analytical Chemistry. McGraw-Hill.

[4] "Cosis.net" (PDF). www.cosis.net. Retrieved May 10, 2007.

[Angew.chem.2007-5] Lu, A.-H., Salabas, E. L. and Schüth, F. (2007). Angew. Chem. Int. Ed., 46,1222–1244.

[6] Otto Hahn, "Applied Radiochemistry", Cornell University Press, Ithaca, New York, USA, 1936.

[7] ALAN TOWNSHEND and EWALD JACKWERTH, "PRECIPITATION OF MAJOR CONSTITUENTS FOR TRACE PRECONCENTRATION : POTENTIAL AND PROBLEMS", Pure & App. Chem., Vol.61, No.9, pp. 1643-1656, 1989., (pdf)

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Coprecipitation

Contents

Distribution between precipitate and solution

See also

Related Research Articles

References