The present invention relates to nanoscience, nanoparticles and, more specifically, to a highly uniform, table, and tailorable core-void-shell morphology.
Stainless metal interfaces resist bulk oxidation and consist of FeCr alloys. This stainless characteristic is the result of an oxidation process in which a passivating layer of Cr2O3 forms which limits further molecular oxygen transport. Like bulk materials, the oxidation of nanomaterials is a critically important phenomenon the extent of which determines the materials function. This is especially true for first row transition metals. While the synthesis of oxide nanomaterials is well established, approaches to resist oxidation are varied, and recent studies have in turn welcomed oxidation as a synthetic tool to manipulate nanoparticle morphology and microstructure.
Oxidation in iron based nanostructures lead to Kirkendall diffusion, which can form an assortment of hollow nanostructures, ranging from nanowires on a solid support, to nanocubes, and nanospheres. The experimental implementation of Kirkendall diffusion using Co nanoparticles (NPs), upon sulfidation of solid Co NPs, showed well defined hollow morphologies that resulted in an assortment of CoxSy phases. It was further shown that the sulfidation of Pt/Co core/shell NPs resulted in novel core-void-shell morphologies, due in large part to the resistance of the Pt core to oxidation.
These examples of ‘vacancy coalescence’ have since prepared a number of hollow nanostructures, like Fe, Fe3O4, Co, Ni and Cd NPs. Vacancy coalescence can be considered an extension of the Kirkendall effect, when diffusion is confined to a three dimensional nanomaterial, and is the result of the nonreciprocal diffusion of materials within the NP, electrical contact between the core and shell, as well as defect concentration. Parameters that can tune this phenomena include the diffusivity of the atoms involved, the oxidation products, NP morphology, and the size of the starting material. To date little work has been described that uses alloy interfaces, or stainless materials, to control Kirkendall kinetics and void formation.
The present invention employs a core/alloy NP synthesis route, inspired by work developed by the present inventors for Au/AuxAg1-x/Ag, Au/AuxAg1-x, Au/AuxPd1-x, and Au/AuxAg1-xAgNPs, to deposit sub-nanometer thin Cr shells at crystalline α-Fe NP cores, which upon annealing, results in α-Fe/FexCr1-x Core/Alloy NPs. The oxidation of these core/alloy NPs results in a core-void-shell morphology, in which the interior core remains crystalline and highly magnetic, while the FeCr oxide shell passivates further oxidation at modest temperatures up to ˜200° C. The void formation is tunable based on the thickness of the Cr shell, with thicker shells resisting both bulk oxidation and void coalescence. The particles of the present invention show a unique morphological transformation that is induced by surface oxidation, oxide passivation, and vacancy coalescence. This Kirkendall diffusion results in a tailorable oxide layer thickness, Fe-core size, as well as void size and symmetry. Much like the interface of bulk stainless steel, the interfacial FeCr oxide passivates oxidation, resulting in self-limited diffusion. Because of this, a highly uniform and stable core-void-shell morphology is provided.
The present invention will be more fully understood and appreciated by reading the following Detailed Description in conjunction with the accompanying drawings, in which:
Referring now to the drawings, wherein like reference numerals refer to like parts throughout, there is seen in
The propensity of the Fe/FeCr NPs to oxidize was studied and followed via TEM, XRD, XPS, and magnetic measurements.
where a as-synthesized core, b after Cr shell deposition and annealing, and c after oxidation.
Up to this point in the synthesis, care was paid to limit oxidation of the surface, however the Cr-shelled sample was found to be much more readily oxidized than the α-Fe core. This is best shown by the reflections that appear in the XRD that are consistent with a thin shell of Fe3O4 oxide (
After purification via both magnetic separation as well as non-solvent precipitation, the HDA/HDACl-capped Fe/FexCr1-x NPs were oxidized by opening the colloidal NP solutions to air at T=100° C. in ODE. Upon oxidation, an interesting phenomenon emerged. First, the NPs lost some magnetic propensity, as first monitored qualitatively via a rare earth magnet. Second, upon TEM analysis a morphological change from a solid NP to one with a distinct core, surrounded by an area of decreased contrast, and then a thin shell of increased contrast, was observed. This core-void-shell morphology is shown in
The presence of Cr within the final core-void-shell structure was probed by high resolution TEM (HRTEM) with compositional analysis by scanning TEM (STEM) and selective area EDX.
In order to further study the oxidation process and void formation, the solution containing the oxidizing NPs was sampled over the course of oxidation.
where a oxidation time at 100° C., b diameter of new core+void+shell (dC′+V+S), c diameter of new core+void (dC′+V), and d diameter of new core (dC′).
This particular batch of NPs had a slightly more polydisperse α-Fe core (dC=15.8±2.6 nm), and thus the final core-void-shell NPs adopt similar dispersity. Interestingly, these results indicate that the oxidation process has seemingly reached completion after only a few hours (˜2.5). Similar conclusions were made by XRD analysis of each aliquot (see
The observed structural transformation of these α-Fe/FexCr1-x NPs to ones with a core-void-shell morphology with a considerable amount of open space is best explained using a modified vacancy coalescence mechanism, which is influenced by both chemical and morphological factors. For instance, the α-Fe cores prepared here are highly crystalline, with a non-closed packed bcc crystal structure, which inherently has a 68% packing density. Moreover, as the FexCr1-x alloys phase diagram suggests, an α-structure is expected at x=0.1-1.0 (see
It has also been shown that when a Pt/Co core/shell NP is used, that the Co shell will undergo oxidation, whereas the Pt cannot, resulting in what is referred to as a core-yolk-shell NP, a particular morphology that is the closest in the literature to the nanostructures shown here. In that case, it is easy to understand that oxidation will stop at the Pt interface, due to its resistance to oxidation. However, it is less clear as to why the oxidation stops in the system of the present invention, as evidenced by the crystalline α-Fe core shown in XRD and TEM. Clearly, it is related to the contribution of the Cr-rich interface's oxidation, its thickness, and the temperature and the time of oxidation. In bulk stainless steel (≈Fe84Cr16) for instance, the addition of Cr acts as a passivating layer, which upon oxidation, limits further O2− transport, due to the stability of the Cr2O3 oxide and its lattice constant (a=2.88 Å) being similar to α-Fe and α-Cr. However, in the current system, the shell adopts a M3O4 crystal structure (M=Fe, Cr), and no Cr2O3 (or Fe2O3) was detected. A CrFe2O4 structure has precedent in the literature, and its likely that this form arises due to the known stability of the M3O4 structure at the nanoscale, particularly for low temperature oxidation, and the alloying of the interface, which is high in Fe content (i.e. thin Cr shell). A main difference of the present invention compared to say, bulk stainless steel, is that oxidation is not driven by electrochemical or acid means, and this may further limit the accessibility of the Cr2O3 lattice. A second factor is the relative thickness of the Cr-shell, as this influences Fe transport, oxide thickness, and the resulting electron tunneling behavior. A close inspection of the core-void-shell morphologies (see
To support this, control studies with thinner Cr shells (n=8,
Additional versions of this approach include the use of multiple alloy or metallic layers which have different propensity for oxidation, which will lead to multiple layers and domains of voids as well as asymmetric nanoparticles in which noble metals are deposited in specific locations of the NP, thus influencing oxidation and void growth, as seen in
In addition, the voids of these materials could be filled with a new element. Using the Fe/FexCr1-x, core-void-shell particles, copper ions could be inserted into the voids which, when followed by reduction and oxidation, leads to a new core-void-shell nanostructure.
Taken together, these results demonstrate a novel synthetic pathway to tailor the internal microstructure of nanomaterials. The methodology used here that results in core-void-shell morphologies may be translated to other systems in which the interface composition and thickness is used as a synthetic tool to alter Kirkendall effects and as a result, final internal morphology. Given the recent utility of these classes of nanomaterials in an array of applications, such as in gas storage and heterogeneous catalysis, as well as lithium ion batteries, more work is needed to achieve the full synthetic control and potential.
Chemicals
Iron(0)pentacarbonyl (Fe(CO)5, 99.5%), Chromium(0)hexacarbonyl (Cr(CO)6, 98%), Oleylamine (OAm, 70%), 1-Octadecene (ODE, 90%), Tetrahydrofuran (THF, anhydrous, 99.9%, inhibitor-free), Hexadecylamine (HDA, 98%), HCl (1.0 M in diethylether), HAuCl4.xH2O (99.999% trace metals basis), 1,2-hexadecanediol (technical grade, 90%), Cu(acac)2 (≥99.99% trace metals basis), HAuCl4.xH2O (99.999% trace metals basis), 1,2-hexadecanediol (technical grade, 90%), Cu(acac)2 (≥99.99% trace metals basis) were purchased from Sigma-Aldrich and used as received.
Synthesis
HDA.HCl Ligand: The HDA.HCl ligand was synthesized by adding an excess amount HCl in diethylether (12 mL, 1.0 M) was added into a solution of 10 mmol of hexadecylamine (HDA) (2.44 g) in 100 mL of hexanes that was pre-cooled in an ice bath. The white precipitate was formed and the reaction mixture was warmed up to room temperature and was stirred for 2 h before the solution was decanted and the precipitate was washed for 3 times with hexanes. After evaporation of hexanes, 1.8 g (66% yield) of HDA.HCl was obtained.
Synthesis of Au/Fe core, Fe/Cr/Au & Fe/Cr/Au oxide: Oleic acid (2 mmol), oleylamine (2 mmol), 70 mg of HDA HCl 1,2-hexadecandiol (5 mmol) and 10 ml 1-octadecene (ODE) were mixed and stirred under a gentle flow of nitrogen at 120° C. for 20 min. Then under a blanket of nitrogen, the degassed gold precursor solution consisting of 17 mg HAuCl4 (0.05 mmol), 0.25 ml oleylamine (0.75 mmol) and 2.5 ml ODE was injected into the solution. After 2 min, 0.15 ml Fe(CO)5 (1 mmol) was injected into the solution. The solution turned to dark red instantly after the injection, indicating the formation of gold nanoparticles. The mixture was heated to reflux (˜310° C.) for 45 min, cooled down to room temperature. Cr shell was deposited using the same fashion using THF as the solvent for 1 hr, and then the Fe/Cr/Au NP was subjected to the same oxidation condition for 5 hrs. The particles were precipitated out with iso-propanol (˜40 ml) addition followed by centrifugation. The precipitate was re-dispersed into hexane in the presence of ˜0.05 ml oleylamine and centrifuged again to remove any undispersed materials. The dumbbell nanoparticles were precipitated out by adding ethanol and re-dispersed in hexane in the presence of ˜0.05 ml oleylamine, giving a dark red brown dispersion. A little extra of oleylamine was necessary to ensure long term stability of the dispersion.
Synthesis of Cu/Fe/Cr oxide Nanoparticles: 28.3 mg of as synthesized Fe/FexCr1-x core-void-shell structure was re-dispersed in 10 ml Oam, 0.25 mmol of (65 mg) Cu(acac)2 was added as Cu precursor with 1 mmol (258.44 mg) of 1,2-hexadecanediol (HHD) as a reducing agent, the solution was heated up to 160° C. and stayed for 2 h before cooled down to room temperature, the NP was processed using ethanol and hexane washing cycle.
α-Iron Nanoparticle core (α-Fe): The crystalline α-Fe nanoparticles were prepared via the thermal decomposition of Fe(CO)5 in the presence of oleylamine (OAm), and hexadecylammonium chloride (HDA.HCl). In a typical experiment, 20 mL of octadecene (ODE) with 139 mg of HDA.HCl, and 0.15 mL of Oleylamine (OAm) was heated to 120° C. and degassed for 0.5 h, then the solution was heated to 180° C., and 0.35 mL of Fe(CO)5 was injected to the solution under an Ar blanket. The color of the solution changed from yellow to brown then black within 20 min, which is slower than the decomposition of Fe(CO)5 without the existence of HDA.HCl. The resulting α-Fe NPs showed high magnetism, and because of this the final synthesis proceeded without a stir bar to avoid precipitation, but was bubbled with Ar to ensure mixing. After 30 min of annealing at 180° C., a 10 mL aliquot was collected and stored at under Ar, while the rest was used as the cores for shell deposition. After 30 min, a 10 mL of the Fe NP solution with concentration of 1.28 mM was added with ethanol to precipitate the product. After centrifugation (10 min, 4400 RPM), the NPs were re-dispersed in hexane and precipitated by ethanol, this same procedure was repeated one more time and the final product was dispersed in hexane and stored in Ar.
Chromium Shell Deposition and Annealing at Fe Cores (α-Fe/FeCr): In a typical synthesis, 650 mg Cr(CO)6 was dissolved in 20 mL of hot ODE (100° C.) and added into a solution of α-Fe NPs cores under Ar at 180° C. in a layer-by-layer fashion. For instance, a 1 mL aliquot was injected at each layer (n) to achieve minimum Cr shell coating with theoretical 0.25 nm shell thickness growth provided complete dissolution of the Cr precursor, then annealed for 15 min before adding additional shells (up to n=8 or n=16 in this study). Similar to above, during shell growth no stir bar was added to avoid any inference from the magnetic field produced. The total annealing time for a typical shell deposition is ˜4 hrs. Ethanol was added to precipitate the product. After centrifugation (10 min, 4400 RPM), the product was re-dispersed in hexane and precipitated by ethanol, this same procedure was repeated one more time and the final product was dispersed in hexane and stored in Ar. Alternatively, the Cr(CO)6 was first dissolved in THF and used as the shell precursor. This method improved control of shell growth. Briefly, in a typical synthesis, 650 mg Cr(CO)6 was dissolved in 20 mL of warm THF (35° C.) and added into a solution of α-Fe NPs cores under Ar at 180° C. in a layer-by-layer fashion. Shell deposition was then carried out similarly to that described above.
Oxidation and formation of core-void-shell Morphology: The oxidation of the α-Fe/FeCr experiment was conducted using the NPs in the mother liquor that had been opened up to air under heating at 100° C. in a silicon oil bath. During oxidation, aliquots were collected for TEM, XPS, and magnetic measurements. After oxidation, the NPs were purified as described above.
Synthesis of Au—Fe/FeCr heterostructures & asymmetric voids: Oleic acid (2 mmol), oleylamine (2 mmol), 70 mg of HDA HCl, 1,2-hexadecandiol (5 mmol) and 10 ml 1-octadecene (ODE) were mixed and stirred under a gentle flow of nitrogen at 120° C. for 20 min. Then under a blanket of nitrogen, the degassed gold precursor solution consisting of 17 mg HAuCl4 (0.05 mmol), 0.25 ml oleylamine (0.75 mmol) and 2.5 ml ODE was injected into the solution. After 2 min, 0.15 ml Fe(CO)5 (1 mmol) was injected into the solution. The solution turned to dark red instantly after the injection, indicating the formation of gold nanoparticles. The mixture was heated to reflux (˜310° C.) for 45 min, cooled down to room temperature. Cr shell was deposited using the same fashion using THF as the solvent for 1 hr, and then the Fe/Cr/Au NP was subjected to the same oxidation condition for 5 hrs. The particles were precipitated out with iso-propanol (˜40 ml) addition followed by centrifugation. The precipitate was re-dispersed into hexane in the presence of ˜0.05 ml oleylamine and centrifuged again to remove any undispersed materials. The dumbbell nanoparticles were precipitated out by adding ethanol and re-dispersed in hexane in the presence of ˜0.05 ml oleylamine, giving a dark red brown dispersion. A little extra of oleylamine was necessary to ensure long term stability of the dispersion.
Backfilling voids with copper and oxidation: 28.3 mg of as synthesized Fe/FexCr1-x core-void-shell structure was re-dispersed in 10 ml OAm, 0.25 mmol of (65 mg) Cu(acac)2 was added as Cu precursor with 1 mmol (258.44 mg) of 1,2-hexadecanediol (HHD) as a reducing agent, the solution was heated up to 160° C. and stayed for 2 h before cooled down to room temperature, the NP was processed using ethanol and hexane washing cycle.
Instrumentation
UV-Vis spectrophotometry (UV-Vis): The UV-Vis measurements were collected on a Varian Cary100 Bio UV-Vis spectrophotometer between 200 and 900 nm. The instrument is equipped with an 8-cell automated holder with high precision Peltier heating controller.
Transmission electron microscopy (TEM): TEM measurements were performed on a JEOL 2000EX instrument operated at 100 kV with a tungsten filament (SUNY-ESF, N.C. Brown Center for Ultrastructure Studies). HRTEM measurements were performed on either a FEI T12 Twin TEM operated at 120 kV with a LaB6 filament and Gatan Orius dual-scan CCD camera or a FEI T12 Spirit TEM STEM operated at 120 kV equipped with a EDAX Genisis X-ray detector (Cornell Center for Materials Research). Particle size and aspect ratio were analyzed manually with statistical analysis performed using ImageJ software on populations of at least 100 counts.
Powder X-ray diffraction (XRD): Powder XRD patterns were taken on a Bruker D8 Advance powder diffractometer using Cu Kα radiation (k=1.5406 Å). The diffraction (Bragg) angles 2θ were scanned at a step of 0.04° with a scan speed of 40 s/step. Samples were deposited as dry powder on glass slides.
X-ray Photoelectron Spectroscopy (XPS): XPS also known as electron spectroscopy for chemical analysis (ESCA) measurements were performed on Surface Science Instruments (SSI) model SSX-100 that utilizes monochromated Aluminum K-α x-rays (1486.6 eV) to strike the sample surface (Cornell Center for Materials Research). The analysis depth was ˜5 nm at an emission angle of 55°. The data was processed using CasaXPS software. The NP powders were dispersed on freshly cleaved HOPG substrates for analysis.
Magnetization Measurement: The magnetic measurement was conducted on Quantum Design Physical Property Measurement System (PPMS) in Cornell Center of Materials Research, PPMS consists of a 9 Tesla superconducting magnet in a helium dewar with sample temperature range of 1.9-400K.
This application is a continuation of U.S. application Ser. No. 14/207,872, filed on Mar. 13, 2014, which claimed priority to U.S. Provisional Application No. 61/779,464, filed on Mar. 13, 2013.
Number | Name | Date | Kind |
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20100258759 | Archer | Oct 2010 | A1 |
20130078510 | Reynolds | Mar 2013 | A1 |
Number | Date | Country | |
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20170165749 A1 | Jun 2017 | US |
Number | Date | Country | |
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61779464 | Mar 2013 | US |
Number | Date | Country | |
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Parent | 14207872 | Mar 2014 | US |
Child | 15432452 | US |