Trace metal stable isotope biogeochemistry

Trace metal stable isotope biogeochemistry is the study of the distribution and relative abundances of trace metal isotopes in order to better understand the biological, geological, and chemical processes occurring in an environment. Trace metals are elements such as iron, magnesium, copper, and zinc that occur at low levels in the environment. Trace metals are critically important in biology and are involved in many processes that allow organisms to grow and generate energy. In addition, trace metals are constituents of numerous rocks and minerals, thus serving as an important component of the geosphere. Both stable and radioactive isotopes of trace metals exist, but this article focuses on those that are stable. Isotopic variations of trace metals in samples are used as isotopic fingerprints to elucidate the processes occurring in an environment and answer questions relating to biology, geochemistry, and medicine.

Isotope notation edit

In order to study trace metal stable isotope biogeochemistry, it is necessary to compare the relative abundances of isotopes of trace metals in a given biological, geological, or chemical pool to a standard (discussed individually for each isotope system below) and monitor how those relative abundances change as a result of various biogeochemical processes. Conventional notations used to mathematically describe isotope abundances, as exemplified here for ⁵⁶Fe, include the isotope ratio (⁵⁶R), fractional abundance (⁵⁶F) and delta notation (δ⁵⁶Fe). Furthermore, as different biogeochemical processes vary the relative abundances of the isotopes of a given trace metal, different reaction pools or substances will become enriched or depleted in specific isotopes. This partial separation of isotopes between different pools is termed isotope fractionation, and is mathematically described by fractionation factors α or ε (which express the difference in isotope ratio between two pools), or by "cap delta" (Δ; the difference between two δ values). For a more complete description of these notations, see the isotope notation section in Hydrogen isotope biogeochemistry.

Naturally occurring trace metal isotope variations and fractionations edit

In nature, variations in isotopic ratios of trace metals on the order of a few tenths to several ‰ are observed within and across diverse environments spanning the geosphere, hydrosphere and biosphere. A complete understanding of all processes that fractionate trace metal isotopes is presently lacking, but in general, isotopes of trace metals are fractionated during various chemical and biological processes due to kinetic and equilibrium isotope effects.

Geochemical fractionations edit

Certain isotopes of trace metals are preferentially oxidized or reduced; thus, transitions between redox species of the metal ions (e.g., Fe²⁺ → Fe³⁺) are fractionating, resulting in different isotopic compositions between the different redox pools in the environment.^[1] Additionally, at high temperatures, metals ions can evaporate (and subsequently condense upon cooling), and the relative differences in isotope masses of a given heavy metal leads to fractionation during these evaporation and condensation processes.^[2] Diffusion of isotopes through a solution or material can also result in fractionations, as the lighter mass isotopes are able to diffuse at a faster rate.^[3] Additionally, isotopes can have slight variations in their solubility and other chemical and physical properties, which can also drive fractionation.

Biological fractionations edit

In sediments, oceans, and rivers, distinct trace metal isotope ratios exist due to biological processes such as metal ion uptake and abiotic processes such as adsorption to particulate matter that preferentially remove certain isotopes.^[4] The trace metal isotopic composition of a given organism results from a combination of the isotopic compositions of source material (i.e., food and water) and any fractionations imparted during metal ion uptake, translocation and processing inside cells.

Applications of trace metal isotope ratios edit

Stable isotope ratios of trace metals can be used to answer a variety of questions spanning diverse fields, including oceanography, geochemistry, biology, medicine, anthropology and astronomy. In addition to their modern applications, trace metal isotopic compositions can provide insight into ancient biogeochemical processes operated on Earth.^[5] These signatures arise because the processes that form and modify samples are recorded in the trace metal isotopic compositions of the samples. By analyzing and understanding trace metal isotopic compositions in biological, chemical or geological materials, one can answer questions such as the sources of nutrients for phytoplankton in the ocean, processes that drove the formation of geologic structures, the diets of modern or ancient organisms, and accretionary processes that took place in the early Solar System.^[6]^[7]^[8] Trace metal stable isotope biogeochemistry is still an emerging field, yet each trace metal isotope system has clear, powerful applications to diverse and important questions. Important heavy metal isotope systems are discussed (in order of increasing atomic mass) in the proceeding sections.

Iron edit

Stable isotopes and natural abundances edit

Naturally occurring iron has four stable isotopes, ⁵⁴Fe, ⁵⁶Fe, ⁵⁷Fe, and ⁵⁸Fe.

Stable isotopes of iron
Isotope	Abundance (%)
⁵⁴Fe	5.845
⁵⁶Fe	91.754
⁵⁷Fe	2.1191
⁵⁸Fe	0.2819

Stable iron isotopes are described as the relative abundance of each of the stable isotopes with respect to ⁵⁴Fe. The standard for iron is elemental iron, IRMM-014, and it is distributed by the Institute for Reference Materials and Measurement. The delta value is compared to this standard, and is defined as:

$\delta ^{56/54}Fe={\frac {(^{56}Fe/^{54}Fe)_{sample}}{(^{56}Fe/^{54}Fe)_{IRMM014}}}-1$

Delta values are often reported as per mil values (‰), or part-per-thousand differences from the standard. Iron isotopic fractionation is also commonly described in units of per mil per atomic mass unit.

In many cases, the δ⁵⁶Fe value can be related to the δ⁵⁷Fe and δ⁵⁸Fe values through mass-dependent fractionation:^[9]

$\delta ^{57}Fe=1.5\times \delta ^{56}Fe$

$\delta ^{58}Fe=2\times \delta ^{56}Fe$

Chemistry edit

One of the most prevalent features of iron chemistry is its redox chemistry. Iron has three oxidation states: metallic iron (Fe⁰), ferrous iron (Fe²⁺), and ferric iron (Fe³⁺). Ferrous iron is the reduced form of iron, and ferric iron is the oxidized form of iron. In the presence of oxygen, ferrous iron is oxidized to ferric iron, thus ferric iron is the dominant redox state of iron at Earth's surface conditions. However, ferrous iron is the dominant redox state below the surface at depth. Because of this redox chemistry, iron can act as either an electron donor or receptor, making it a metabolically useful species.

Each form of iron has a specific distribution of electrons (i.e., electron configuration), tabulated below:

Electron configurations of Fe
Fe form	Electron configuration
Fe⁰	[Ar]3d⁶4s²
Fe²⁺	[Ar]3d⁶
Fe³⁺	[Ar]3d⁵

Equilibrium Isotope Fractionation edit

Variations in iron isotopes are caused by a number of chemical processes which result in the preferential incorporation of certain isotopes of iron into certain phases. Many of the chemical processes which fractionate iron are not well understood and are still being studied. The most well-documented chemical processes which fractionate iron isotopes relate to its redox chemistry, the evaporation and condensation of iron, and the diffusion of dissolved iron through systems. These processes are described in more detail below.

Fractionation as a result of redox chemistry edit

To first order, reduced iron favors isotopically light iron and oxidized iron favors isotopically heavy iron. This effect has been studied in regards to the abiotic oxidation of Fe²⁺ to Fe³⁺, which results in fractionation. The mineral ferrihydrite, which forms in acidic aquatic conditions, is precipitated via the oxidation of aqueous Fe²⁺ to Fe³⁺.^[10] Precipitated ferrihydrite has been found to be enriched in the heavy isotopes by 0.45‰ per atomic mass unit with respect to the starting material.^[10] This indicates that heavier iron isotopes are preferentially precipitated as a result of oxidizing processes.^[10]

Theoretical calculations in combination with experimental data have also aimed to quantify the fractionation between Fe(III)_aq and Fe(II)_aq in HCl.^[1] Based on modeling, the fractionation factor between the two species is temperature dependent:^[1]

$10^{3}\times \ln {\alpha _{Fe(III)-Fe(II)}}={\frac {0.334\pm 0.032\times 10^{6}}{T^{2}}}-0.66\pm 0.38$

Fractionation as a result of evaporation and condensation edit

Evaporation and condensation can give rise to both kinetic and equilibrium isotope effects. While equilibrium mass fractionation is present evaporation and condensation, it is negligible compared to kinetic effects.^[1] During condensation, the condensate is enriched in the light isotope, whereas in evaporation, the gas phase is enriched in the light isotope. Using the kinetic theory of gases, for ⁵⁶Fe/⁵⁴Fe, a fractionation factor of α = 1.01835 for the evaporation of a pool containing equimolar amounts of ⁵⁶Fe and ⁵⁴Fe.^[1] In evaporation experiments, the evaporation of FeO at 1,823 K gave a fractionation factor of α = 1.01877.^[2] Presently, there have been no experimental attempts to determine the ⁵⁶Fe/⁵⁴Fe fractionation factor of condensation.^[1]

Fractionation as a result of diffusion edit

Kinetic fractionation of dissolved iron occurs as a result of diffusion. When isotopes diffuse, the lower mass isotopes diffuse more quickly than the heavier isotopes, resulting in fractionation. This difference in diffusion rates has been approximated as:^[3]

${\frac {D_{1}}{D_{2}}}=\left({\frac {m_{1}}{m_{2}}}\right)^{\beta }$

In this equation, D₁ and D₂ are the diffusivities of the isotopes, m₁ and m₂ are the masses of the isotopes, and β, which can vary between 0 and 0.5, depending on the system.^[9] More work is required to fully understand fractionation as a result of diffusion, studies of diffusion of iron on metal have consistently given β values of approximately 0.25.^[11] Iron diffusion between silicate melts and basaltic/rhyolitic melts have given lower β values (~0.030).^[12] In aqueous environments, a β value of 0.0025 has been obtained.^[13]

Fractionation as a result of phase partitioning edit

There may be equilibrium fractionation between coexisting minerals. This would be particularly relevant when considering the formation of planetary bodies early in the solar system. Experiments have aimed to simulate the formation of the Earth at high temperatures using a platinum-iron alloy and an analog for the silicate earth at 1,500 °C.^[14] However, the observed fractionation was very small, less than 0.2‰ per atomic mass unit.^[14] More experimental work is needed to fully understand this effect.

Biology edit

In biology, iron plays a number of roles. Iron is widespread in most living organisms and is essential for their function. In microbes, iron redox chemistry is utilized as an electron donor or receptor in microbial metabolism, allowing microbes to generate energy. In the oceans, iron is essential for the growth and survival of phytoplankton, which use iron to fix nitrogen. Iron is also important in plants, given that they need iron to transfer electrons during photosynthesis. Finally, in animals, iron plays many roles, however, its most essential function is to transport oxygen in the bloodstream throughout the body. Thus, iron undergoes many biological processes, each of which have variations in which isotopes of iron they preferentially use. While iron isotopic fractionations are observed in many organisms, they are still not well understood. Improvements in the understanding the iron isotope fractionations observed in biology will enable the development of a more complete knowledge of the enzymatic, metabolic, and other biologic pathways in different organisms. Below, the known iron isotopic variations for different classes of organisms are described.

Iron reducing bacteria edit

Iron reducing bacteria reduce ferric iron to ferrous iron under anaerobic conditions. One of the first studies that studied iron fractionation in iron-reducing bacteria studied the bacterium Shewanella algae.^[15] S. algae was grown on a ferrihydrite substrate, and was then allowed to reduce iron.^[15] The study found that S. algae preferentially reduced ⁵⁴Fe over ⁵⁶Fe, with a δ^56/54Fe value of -1.3‰.^[15]

More recent experiments have studied the bacterium Shewanella putrefaciens and its reduction of Fe(III) in goethite. These studies have found δ^56/54Fe values of -1.2‰ relative to the goethite.^[16] The kinetics of this fractionation were also studied in this experiment, and it was suggested that the iron isotope fractionation is likely related to the kinetics of the electron transfer step.^[16]

Most studies of other iron reducing bacteria have found δ^56/54Fe values of approximately -1.3‰.^[17]^[18] At high Fe(III) reduction rates, δ^56/54Fe values of -2 – -3‰ relative to the substrate have been observed.^[19] The study of iron isotopes in iron reducing bacteria enable the development of an improved understanding regarding the metabolic processes operating in these organisms.

Isotope fractionations resulting from iron reducing bacteria
Species	δ^54/56Fe (‰)	Reference
Fe(II)_aq - FeCO₃	0.0	^[19]
Fe(II)_aq - Ca_0.15Fe_0.85CO₃	+0.9	^[19]
Fe(II)_aq - Fe₃O₄	-1.3	^[19]
Fe(II)_aq - Ferric oxide/hydroxide	-1.3	^[15]
Fe(II)_aq - Fe(II)_s	0.0	^[19]
Fe₃O₄ - FeCO₃	+1.3	^[19]
Fe₃O₄ - Ca_0.15Fe_0.85CO₃	+2.2	^[19]

Iron oxidizing bacteria edit

While most iron is oxidized as a result of interaction with atmospheric oxygen or oxygenated waters, oxidation by bacteria is an active process in anoxic environments and in oxygenated, low pH (<3) environments. Studies of the acidophilic Fe(II)-oxidizing bacterium, Acidthiobacillus ferrooxidans, have been used to determine the fractionation as a result of iron-oxidizing bacteria. In most cases, δ^56/54Fe values between 2 and 3‰ were measured.^[20] However, a Rayleigh trend with a fractionation factor of α_{Fe(III)aq-Fe(II)aq} ~ 1.0022 was observed, which is smaller than the fractionation factor in the abiotic control experiments (α_{Fe(III)aq-Fe(II)aq} ~ 1.0034), which has been inferred to reflect a biological isotope effect.^[20] Using iron isotopes, an improvement in the understanding of the metabolic processes controlling iron oxidation and energy production in these organisms can be developed.

Photoautrophic bacteria, which oxidize Fe(II) under anaerobic conditions, have also been studied. The Thiodictyon bacteria precipitate poorly crystalline hydrous ferric oxide when they oxidize iron.^[21] The precipitate was enriched in the ⁵⁶Fe relative to Fe(II)_aq, with a δ^56/54Fe value of +1.5 ± 0.2‰.^[21]

Magnetotactic bacteria edit

Magnetotactic bacteria are bacteria with magnetosomes that contain magnetic crystals, usually magnetite or greigite, which allow them to orient themselves with the Earth’s magnetic field lines. These bacteria mineralize magnetite via the reduction of Fe(III), usually in microaerobic or anoxic environments. In the magnetotactic bacteria that have been studied, there was no significant iron isotope fractionation observed.^[22]

Phytoplankton edit

Iron is important for the growth of phytoplankton. In phytoplankton, iron is used for electron transfer reactions in photosynthesis in both photosystem I and photosystem II.^[23] Additionally, iron is an important component of the enzyme nitrogenase, which is used to fix nitrogen.^[23] In measurements at open ocean stations, phytoplankton are isotopically light, with the fractionation as a result of biological uptake measured between -0.25‰ and -0.13‰.^[24] Improvement in the understanding of this fractionation will enable the more precise understanding of phytoplankton photosynthetic processes.

Animals edit

Iron has many important roles in animal biology, specifically when considering oxygen transport in the bloodstream, oxygen storage in muscles, and enzymes. Known isotope variations are shown in the figure below.^[25] Iron isotopes could be useful tracers of the iron biochemical pathways in animals, and also be indicative of trophic levels in a food chain.^[7]

Iron isotope variations in humans reflects a number of processes. Specifically, iron in the blood stream reflects dietary iron, which is isotopically lighter than iron in the geosphere.^[26] Iron isotopes are distributed heterogeneously throughout the body, primarily to red blood cells, the liver, muscle, skin, enzymes, nails, and hair. Iron losses in the body (intestinal bleeding, bile, sweat, etc.) favor the loss of isotopically heavy iron, with mean losses averaging a δ⁵⁶Fe of +10‰.^[26] Iron absorption in the intestine favors lighter iron isotopes.^[26] This is largely due to the fact that iron is carried by transport proteins and transferrin, both of which are kinetic processes, resulting in the preferential uptake of isotopically light iron.^[26]

The observed iron isotopic variations in humans and animals are particularly important as tracers. Iron isotopic signatures are utilized to determine the geographic origin of food. Additionally, anthropologists and paleontologists use iron isotope data in order to track the transfer of iron between the geosphere and the biosphere, specifically between plant foods and animals. This allows for the reconstruction of ancient dietary habits based on the variations in iron isotopes in food.

Variations in the iron isotope composition of humans and their food sources.

Geochemistry edit

By mass, iron is the most common element on Earth, and it is the fourth most abundant element in the Earth's crust. Thus, iron is widespread throughout the geosphere, and is also common on other planetary bodies. Natural variations in the iron in the geosphere are relatively small. Currently, the values of δ^56/54Fe measured in rocks and minerals range from -2.5‰ to +1.5‰. Iron isotope composition is homogeneous in igneous rocks to ±0.05‰, indicating that much of the geologic isotopic variability is a result of the formation of rocks and minerals at low temperature.^[17] This homogeneity is particularly useful when tracing processes which result in fractionation through the system. While fractionation of igneous rocks is relatively constant, there are larger variations in the iron isotopic composition of chemical sediments.^[27] Thus, iron isotopes are used to determine the origin of the protolith of heavily metamorphosed rocks of a sedimentary origin.^[27] Improvements of the understanding regarding the way in which iron isotopes fractionate in the geosphere can help to better understand geologic processes of formation.

Natural iron isotopic variations edit

To date, iron is one of the most widely studied trace metals, and iron isotope compositions are relatively well-documented. Based on measurements, iron isotopes exhibit minimal variation (±3‰) in the terrestrial environment. A list of iron isotopic values of different materials from different environments is presented below.

Observed variations in the iron isotope composition in the geosphere. Data obtained from references in the text.

In terrestrial environments edit

There is an extreme constancy of the isotopic composition of igneous rocks. The mean value of δ⁵⁶Fe of terrestrial rocks is 0.00 ± 0.05‰.^[17] More precise isotopic measurements indicate that the small deviations from 0.00‰ may reflect a slight mass-dependent fractionation.^[17] This mass fractionation has been proposed to be F_Fe = 0.039 ± 0.008‰ per atomic mass unit relative to IRMM-014.^[28] There may also be slight isotopic variations in igneous rocks depending on their composition and process of formation. The average value of δ⁵⁶Fe for ultramafic igneous rocks is -0.06‰, whereas the average value of δ⁵⁶Fe for mid-ocean ridge basalts (MORB) is +0.03‰.^[17] Sedimentary rocks exhibit slightly larger variations in δ⁵⁶Fe, with values between -1.6‰ and +0.9‰ relative to IRMM-014.^[28] Banded iron formations δ⁵⁶Fe span the entire range observed on Earth, from -2.5‰ to +1‰.^[5]

In the oceans edit

There are slight iron isotopic variations in the oceans relative to IRMM-014, which likely reflect variations in the biogeochemical cycling of iron within a given ocean basin. In the southeastern Atlantic, δ⁵⁶Fe values between -0.13 and +0.21‰ have been measured.^[29] In the north Atlantic, δ⁵⁶Fe values between -1.35 and +0.80‰ have been measured.^[30]^[31] In the equatorial Pacific δ⁵⁶Fe values between -0.03 and +0.58‰ have been measured.^[32]^[33] The supply of aerosol iron particles to the ocean have an isotopic composition of approximately 0‰.^[1] Dissolved iron riverine input to the ocean is isotopically light relative to igneous rocks, with δ⁵⁶Fe values between -1 and 0‰.^[1]

Most modern marine sediments have δ⁵⁶Fe values similar to those of igneous δ⁵⁶Fe values.^[1] Marine ferromanganese nodules have δ⁵⁶Fe values between -0.8 and 0‰.

In hydrothermal systems edit

Hot (> 300 °C) hydrothermal fluids from mid ocean ridges are isotopically light, with δ⁵⁶Fe between -0.2 and -0.8‰.^[1] Particles in hydrothermal plumes are isotopically heavy relative to the hydrothermal fluids, with δ⁵⁶Fe between 0.1 and 1.1‰.^[1] Hydrothermal deposits have average δ⁵⁶Fe between -1.6 and 0.3‰.^[1] The sulfide minerals within these deposits have δ⁵⁶Fe between -2.0 and 1.1‰.^[1]

In extraterrestrial objects edit

Variations in iron isotopic composition have been observed in meteorite samples from other planetary bodies. The Moon has variations in iron isotopes of 0.4‰ per atomic mass unit.^[34] Mars has very small isotope fractionation of 0.001 ± 0.006‰ per atomic mass unit.^[8] Vesta has iron fractionations of 0.010 ± 0.010‰ per atomic mass unit.^[8] The chondritic reservoir exhibits fractionations of 0.069 ± 0.010‰ per atomic mass unit.^[8] Isotopic variations observed on planetary bodies can help to constrain and better understand their formation and processes occurring in the early Solar System.

Measurement edit

High precision iron isotope measurements are obtained either via thermal ionization mass spectrometry (TIMS) or multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS).

Applications of iron isotopes edit

Iron isotopes have many applications in the geosciences, biology, medicine, and other fields. Their ability to act as isotopic tracers allows for their use to determine information regarding the formation of geologic units and as a potential proxy for life on Earth and other planets. Iron isotopes also have applications in anthropology and paleontology, as they are used to study the diets of ancient civilizations and animals. The widespread uses of iron in biology make its isotopes a promising frontier in biomedical research, specifically their use to prevent and treat blood conditions and other pathological blood diseases. Some of the more prevalent applications of iron isotopes are described below.

Banded iron formations edit

Banded iron formations (BIFs) are particularly important when considering the surface environments of the early Earth, which were significantly different from the surface environments observed today. This is manifested in the mineralogy of these formations, which are indicative of different redox conditions.^[35] Additionally, BIFs are interesting in that they were deposited while major changes were occurring in the atmosphere and in the biosphere 2.8 to 1.8 billion years ago.^[35] Iron isotopic studies can reveal the details of the formation of BIFs, which allows for the reconstruction of redox and climatic conditions at the time of deposition.

BIFs formed as a result of the oxidation of iron by oxygen, which was likely generated by the evolution of cyanobacteria.^[36] This was followed by the subsequent precipitation of iron particles in the ocean.^[36] Observed variations in the iron isotopic composition of BIFs span the entire range observed on Earth, with δ^56/54Fe values between -2.5 and +1‰.^[5] The cause of these variations are hypothesized to occur for three reasons. The first relates to the varying mineralogy of the BIFs. Within the BIFs, minerals such as hematite, magnetite, siderite, and pyrite are observed.^[5] These minerals each having varying isotopic fractionation, likely as a result of their structures and the kinetics of their growth.^[5] The isotopic composition of the BIFs is indicative of the fluids from which they precipitated, which has applications when reconstructing environmental conditions of the ancient Earth.^[5] It has also been suggested that BIFs may be biologic in origin. The range of their δ^56/54Fe values fall within the range of those observed to occur as a result of biologic processes relating to bacterial metabolic processes, such as those of anoxygenic phototrophic iron-oxidizing bacteria.^[36] Ultimately, the improved understanding of BIFs using iron isotope fractionations would allow for the reconstruction of past environments and the constraint of processes occurring on the ancient Earth. However, given that the values observed as a result of biogenic and abiogenic fractionation are relatively similar, the exact processes of BIFs are still unclear. Thus, the continued study and improved understanding of biologic and abiologic fractionation effects would be beneficial in providing better details regarding BIF formation.

Iron cycling in the ocean edit

Vertical Fe concentration profile in the Pacific Ocean.^[37]

Iron isotopes have become particularly useful in recent years for tracing biogeochemical cycling in the oceans. Iron is an important micronutrient for living species in the ocean, particularly for the growth of phytoplankton. Iron is estimated to limit phytoplankton growth in about one half of the ocean.^[38] As a result, the development of a better understanding of sources and cycling of iron in the modern oceans is important. Iron isotopes have been used to better constrain these pathways through data collected by the GEOTRACES program, which has collected iron isotopic data throughout the ocean. Based on the variations in iron isotopes, biogeochemical cycling and other processes controlling iron distribution in the ocean can be elucidated.

For example, the combination of iron concentration and iron isotope data can use to determine the sources of oceanic iron. In the South Atlantic and in the Southern Ocean, isotopically light iron is observed in intermediate waters (200 - 1,300 meters), whereas isotopically heavy iron is observed in surface waters and deep waters (> 1,300 meters).^[38] To first order, this demonstrates that there are different sources, sinks, and processes contributing to the iron cycle in varying water masses. The isotopically light iron in intermediate waters suggests that the dominant iron sources include remineralized organic matter.^[38] This organic matter is isotopically light because phytoplankton preferentially take up light iron.^[38] In the surface ocean, the isotopically heavy iron represents the external sources of iron, such as dust, which is isotopically heavy relative to IRMM-014, and the sink of light isotopes as a result of their preferential uptake by phytoplankton.^[38] The isotopically heavy iron in the deep ocean suggests that the iron cycle is dominated by the abiotic, non-reductive release of iron, via desorption or dissolution, from particles.^[38] Isotopic analyses similar to the one above are utilized throughout all of the world's oceans to better understand regional variability in the processes which control iron cycling.^[39]^[40] These analyses can then be synthesized to better model the global biogeochemical cycling of iron, which is particularly important when considering primary production in the ocean.

Vertical δ⁵⁶Fe profile in the Southern Ocean.^[38]

Constraining processes on extraterrestrial bodies edit

Iron isotopes have been applied for a number of purposes on planetary bodies. Their variations have been measured to more precisely determine the processes that occurred during planetary accretion. In the future, the comparison of observed biological fractionation of iron on Earth to fractionation on other planetary bodies may have astrobiological implications.

Planetary accretion edit

One of the primary challenges in the study of planetary accretion is the fact that many tracers of the processes occurring in the early Solar System have been eliminated as a result of subsequent geologic events. Because transition metals do not show large stable isotope fractionations as a result of these events and because iron is one of the most abundant elements in the terrestrial planets, its isotopic variability has been used as a tracer of early Solar System processes.^[41]^[8]

Iron isotope variations in planetary samples^[8]
Planetary body	δ^57/54Fe
Vesta	0.031
Mars	0.03
Moon	0.029
Mafic Earth	0.032

Variations in δ^57/54Fe between samples from Vesta, Mars, the Moon, and Earth have been observed, and these variations cannot be explained by any known petrological, geochemical, or planetary processes, thus, it has been inferred that the observed fractionations are a result of planetary accretion.^[8] It is interesting to note that the isotopic compositions of the Earth and the Moon are much heavier than that of Vesta and Mars. This provides strong support for the giant-impact hypothesis as an impact of this energy would generate large amounts of energy, which would melt and vaporize iron, leading to the preferential escape of the lighter iron isotopes to space.^[8] More of the heavier isotopes would remain, resulting in the heavier iron isotopic compositions observed for the Earth and the Moon. The samples from Vesta and Mars exhibit minimal fractionation, consistent with the theory of runaway growth for their formations, as this process would not yield significant fractionations.^[8] Further study of the stable isotope of iron in other planetary bodies and samples could provide further evidence and more precise constraints for planetary accretion and other processes that occurred in the early Solar System.

Astrobiology edit

The use of iron isotopes may also have applications when studying potential evidence for life on other planets. The ability of microbes to utilize iron in their metabolisms makes it possible for organisms to survive in anoxic, iron-rich environments, such as Mars. Thus, the continual improvement of knowledge regarding the biological fractionations of iron observed on Earth can have applications when studying extraterrestrial samples in the future.^[42] While this field of research is still developing, this could provide evidence regarding whether a sample was generated as a result of biologic or abiologic processes depending on the isotopic fractionation. For example, it has been hypothesized that magnetite crystals found in Martian meteorites may have formed biologically as a result of their striking similarity to magnetite crystals produced by magnetotactic bacteria on Earth.^[43] Iron isotopes could be used to study the origin of the proposed "magnetofossils" and other rock formations on Mars.^[43]

Biomedical research edit

Iron plays many roles in human biology, specifically in oxygen transport, short-term oxygen storage, and metabolism^[44] Iron also plays a role in the body's immune system.^[4] Current biomedical research aims to use iron isotopes to better understand the speciation of iron in the body, with hopes of eventually being able to reduce the availability of free iron, as this would help to defend against infection.^[4]

Iron isotopes can also be utilized to better understand iron absorption in humans.^[26] The iron isotopic composition of blood reflects an individual's long-term absorption of dietary iron.^[26] This allows for the study of genetic predisposition to blood conditions, such as anemia, which will ultimately enable the prevention, identification, and resolution of blood disorders.^[26] Iron isotopic data could also aid in identifying impairments of the iron absorption regulatory system in the body, which would help to prevent the development of pathological conditions related to issues with iron regulation.^[45]

Cobalt edit

Nickel edit

Copper edit