nanoparticles
Transcription
nanoparticles
Presentation of the equipment for processing and characterization of nanoparticles, of the magnetometer, and of their possible applications Darko Makovec Department for Materials Synthesis Jožef Stefan Institute 50 nm Monodisperse nanoparticles of maghemite Equipment Laboratory for the processing and characterization of nanoparticles equipped with fume hoods and with basic laboratory equipment. • Autoclave (Parr 4641, volume 1 L ) for hydrothermal synthesis of nanoparticles. • Dynamic light-scattering granulometer (Fritsch ANALYSETTE 12 DynaSizer) for measurements of the particle size in suspensions. Vibrating-sample magnetometer (LakeShore 7404VSM) for magnetic measurements at room temperature. The equipment of the Nanocenter supplements the equipment available in the laboratory for the processing and characterization of nanoparticles at the Department for Materials Synthesis, Jožef Stefan Institute. Autoclave (Parr 4641) Autoclave used for hydrothermal/sovothermal synthesis under high pH. Autoclave vessel (volume 1 L) • used with bench-top furnace available at K8. • Inconel 600 alloy resistant against high pH (not for chlorides!). • max. pressure 131 barr at 350 oC. • equipped with manometer, two safety valves, and set of valves for flushing the vessel with (inert) gas. Hydrothermal synthesis Hydrothermal: chemical reactions occur in aqueous solutions above 100 oC under increased pressure, usually equilibrium water pressure. Supercritical: at temperatures above critical point (374 oC, 218 barr) Ravnotežni tlak vodne pare [barr] Equilibrium water pressure (barr) 3000 200 2500 150 2000 1500 100 1000 50 500 0 0 100 150 200 250 300 o Temerature (oC) Temperatura [ C] 350 400 Ravnotežni tlak vodne pare [psi] Equilibrium water pressure (psi) 3500 250 Max. pressure 131 barr Max. temperature ≈ 330 oC Dynamic light-scattering granulometer (ANALYSETTE 12 DynaSizer) Measurements of particle size (hydrodinamic) in suspensions. Equipped with peristatic pump for sampling (on-line measurements). Dynamic light-scattering From Wikipedia, the free encyclopedia Dynamic light scattering can be used to determine the size distribution profile of small particles in suspensions. Brownian motion is probed with scattering of monchromatic, cohetent laser light. Brownian motion causes a time-dependent fluctuation in the scattering intensity, because the distance between the scatterers in the suspension is constantly changing with time. The scattered light undergoes either constructive or destructive interference by the surrounding particles and within this intensity fluctuation. Information is contained about the time scale of movement of the scatterers. The dynamic information of the particles is derived from an autocorrelation of the recorded intensity trace during the experiment. Hypothetical Dynamic light scattering of two samples: Larger particles vs. smaller particles. Dynamic light-scattering granulometer (ANALYSETTE 12 DynaSizer) Measurement Range: Principle of Operation: 1 nm to 6000 nm Dynamic Light Scattering in backward direction (135 o). Measurement of diluted, concentrated, dark or black suspensions with monodisperse or polydisperse suspension Dynamic light-scattering granulometer (ANALYSETTE 12 DynaSizer) Concentration Range Laser source: 0,001 to 40 wt% Single Mode Laser with optical fibre (wavelength 658 nm, Adjustment of Laser power from 1mW up to 75mW) Optical Cell cuvette). Small volume: Sample temperature Integrated into the instrument (no consumables like less then 50 μl controlled by pettier element: 15°C up to 70°C Patented design for concentrated or opaque/dark samples. High concentration sample are measured using a very thin layer. Multi diffusion and absorption of the laser beam intensity (local warm up effect of the sample – gradient index) are eliminated. Using a ticker sample layer allows the measurement of low concentrations down to 0,001wt/% Dynamic light-scattering granulometer (ANALYSETTE 12 DynaSizer) Correlator: Software: Autocorrelation 1000 channels, 16 bits, 100ns pulse width correlation Different calculation algorithms included:CONTIN (Monomodal), CUMULANT (Monodisperse / avarage size – polydispersity index), PADÈ LAPLACE (unique proprietary algorithm developed for polydisperse suspensions / high resolution) Multi acquisition for statistical measurement possible . This yields the possibility to determine complete size distributions. Vibrating-sample magnetometer (LakeShore 7404 VSM) U ind = C ⋅ m C- cal. constant m- mag. moment moment M= , mass sample holders bulk liquid emu mass magnetization g thin-film holders side-mounted bottom-mounted Vibrating-sample magnetometer (LakeShore 7404 VSM) Moment range: 1x10-7 to 103 emu Applied field strength: Θ range: 00 to 3600 Field 16.2 mm air gap 2.17 T 3.6 mm sample access 23 mm air gap 10 mm sample access 29 mm air gap 16 mm sample access H 1.81 T N Θ 1.53 T air gap Equipment location: Department for Materials Synthesis, Jožef Stefan Institute (Ground floor K800) Equipment accessibility: In agreement with responsible person. Responsible persons: Laboratory: Prof. Darko Makovec (Darko.Makovec@ijs.si) Autoclave: Bernarda Anželak (Bernarda.Anzelak@ijs.si) DLS: Slavko Kralj (Slavko.Kralj@ijs.si) VSM magnetometer Dr. Sašo Gyergyek (Saso.Gyrgyek@ijs.si) Department for Materials Synthesis Magnetic materials: Semiconducting materials: Microwave materials: Magnetic nanoparticles: PTCR ceramics, photocatalytic nanoparticles: Absorbers, nonreciprocal devices (circulators) Ferrofluids, nanoparticles for biomedical applications Semiconducting, ferroelectric ceramics, photocatalytic nanoparticles Hexaferrites (BaFe12O19) Spinel ferrites (Fe3O4, CoFe2O4, …) TiO2, ZnO, BaTiO3, high Tc ferroelectrics, … Ceramics, thick films Nanoparticles, suspensions Nanoparticles, ceramics Multifunctional materials: (Nano)composite materials combining different (coupled) functional properties, magnetic photocatalysts, magnetodielectrics, multiferroics, etc. Aggregates of magnetic (Fe2O3) and photocatalitic (TiO2) nanoparticles, solid materials combining ferrites and ferroelectrics, ferrites and dielectrics, ... Aggregation of different nanoparticles into nanocomposite particles in suspensions, sintering into composite ceramics, dispersing nanoparticles into polymer, silica matrixes, … Superparamagnetic nanoparticles Syntheses of nanoparticles (spinel ferrites, hexaferrites, magnetic perovskites, alloys, …): Coprecipitation, coprecipitation in microemulsions, hydrothermal synthesis, sonochemical synthesis, sol-gel, ... Ferrofluids (stable suspensions of superpramagnetic nanoparticles in a carrier liquid): Nonpolar, polar (water) carrier liquids, different surfactantas Stability of ferrofluids, magnetoreology, magnetic properties,.... Nanoparticles for biomedical applications: Functionalization of magnetic nanoparticles (silika, silanes, polymers) Nanoparticles for hyperthermia (perovskites with tuned Currie temperature, composite nanoparticles spinel ferrite-hexaferrite ) Nanocomposites: Homogeneously dispersed nanoparticles in matrixes of silica or polymer, nanocomposite particles, multifunctional nanocomposites - magnetodielectrics, multiferroics, magnetic photocatalysts… Me H HO O O Si N Si H + HO O Me Si H O N O O HO Me H Si Department for Materials Synthesis (and Characterization) Synthesis of (magnetic) nanoparticles Coprecipitation from aqueous solutions Spinel ferrites (maghemite) Coprecipitation in microemulsions Spinel ferrites (maghemite) Thermal decomposition of organometallic complexes Spinel ferrites (CoFe2O4) Hydrothermal synthesis Hexaferrite BaFe12O19 Superparamagnetic nanoparticles of BaFe12O19 hexaferrite were synthesized for the first time Nanoparticles synthesis Synthesis of superparamagnetic nanoparticles of hexaferrites, preparation of ferrofluids. BaFe12O19 SrFe12O19 Suspensions Magnetic nanoparticles – ferrofluids … Magneto-rheology Application of magnetic nanoparticles in biomedicine Basic concept: • Selective bonding of bioactive molecules (therapeutic agents, targeting ligands, fluorescent dyes, ….) to the surface of magnetic nanoparticles (size approx. 10 nm) via a functionalization layer. • Manipulation and detection from distance. Using external magnetic field, the nanoparticles can be concentrated in a desired part of human body, they can be tracked through their magnetic properties, they can be used to heat a tissue, … Functionalization molekule O Si Si O N O H Si Magnetic nanoparticle Therapeutic agent, marker, dye, … Applications of magnetic nanoparticles in diagnostics • Separation/detection of bioactive molecules (in vitro) • Magnetorelaxometry (in vitro) • Detection of nanoparticles marked with targeting ligands (e.g. antibodies) using measurements of magnetic properties (in vivo) • NMR contrast enhancement (in vivo) • …. Detection using magnetic probe: 100 μg of nanoparticles at the distance of 30 cm NMR image of magnetic nanoparticles in a targeted part of mice brains Endomagnetics Piotr Walczak and Jeff Bulte Department for Materials Synthesis Magnetic nanoparticles – application in therapy • • Magnetic hyperhermia Targeted drug delivery Nanoparticles Siemens AG, Pictures of the future 01/2007 Magnetic nanoparticles internalized into cells Functionalization Grafting functionalization molecules onto the nanoparticles’ surfaces to provide specific functional groups for further bonding of functional molecules. Functionalization molecules: Molecules with at least-two functional groups: - First functional group interacts with the nanoparticle’s surface, Second functional group provides reactive site for further surface reactions with “functional molecules needed in application”. Functional molecules: (Bio)molecules needed in application. Nanoparticle Functionalization molecule Me H HO O O Si N Si H + HO O Me Si H O N O O HO Me H Si Biocompatible layer Fuctional molecule, therapeutic agent, marker, dye, … Functionalized magnetic nanoparticles for biomedical applications Active sites for selective bonding of different (bio)molecules to the nanoparticle’s surface: • Biocompatible polymers (e.g. dextrane, PEG, to increase blood circulation times), • Therapeutic agents, drugs, • Targeting ligands (e.g. antibodies, for targeting tumour tissue), • Fluorescent dyes (for tracking using optical methods), • Permeation enhancers, • … Biocompatible layer Magnetic core Therapeutic agent Abtibody Coating magnetic nanoparticles with silica Thin layer of silica provides surface silanol OH- groups for further bonding of functionalization molecules. It also provides high negative surface charge and thus ensures colloidal stability. Hydrolysis and polycondensation of tetraethyl orthosilicate (TEOS) in stable aqueous suspension of magnetic nanoparticles in presence of alkaline catalyst (ammonia, KOH). Layer of silica Coating magnetic nanoparticles with silica Control of suspension stability and thickness of silica layer using DLS. Grafting of silane molecules onto magnetic nanoparticles Bonding amino- silane to surface OH groups of silica for amino functionalization. Control of the NH2 surface concentration: Aminopropyl triethoxy silane APS (aminoethylamino)propyl triethoxy silane APMS Grafting of silane molecules onto magnetic nanoparticles Agglomeration in the suspensions of APS-grafted maghemite nanoparticles. Aminopropyl triethoxy silane APS TEM size 13.7 ± 2.9 nm R&D cooperation with Nanotesla Institute Ljubljana Development of new methods for binding of bioactive molecules (chromophores, therapeutic agents, monoclonal antibodies) onto the functionalised nanoparticles. Magnetic properties of nanoparticles: Decrease in “saturation” magnetization Zero corcivity = superparamagneticity influence of large surface area size effect Coarse-grained maghemite powder Maghemite nanoparticles, ~ 13 nm in size Maghemite nanoparticles, ~ 3 nm in size Magnetic properties Magnetic nanoparticles are used in the form of stable colloidal suspensions. The (magnetic) agglomeration should be prevented. Superparamagnetic nanoparticles Paramagnetic Ferromagnetic Superparamagnetic Without the influence of external magnetic field, the superparamagnetic nanoparticles do not show any coercivity – no magnetic interactions. Magnetic separation Magnetic nanoparticles – magnetic separations, purifications, selection, … Magnetic nanoparticle Functionalization layer Functionalization molecule Magnetic separation Force acting on the magnetic particle in a mag. field gradient : Fm = μ0 Vp Mp H Δ Magnetic-field gradient Particle magnetization Particle volume ∝ d3 The force acting on the superparamagnetic nanoparticle is too weak for effective separation. Stable suspension of the superpramagnetic nanoparticles. Suspension of the clusters of the superpramagnetic nanoparticles. Controlled clustering Mixing the suspension of the nanoparticles coated with citric acid (0.005 %, pH = 9.0) in the suspension of the nanoparticles coated with APS (0.05 %, pH = 4.0) under agitation with ultrasound. pH after mixing = 5 – 7. Nanoparticles coated with APMS Nanoparticles coated with citric acid R&D cooperation with Cinkarna Celje Synthesis of superparamagnetic, photocatalytic particles for decomposition of organic pollutants in water. The immobilization of the photocatalysts on magnetic carriers, to allow elimination of the photocatalyst from the water suspension after cleaning using an external magnetic field Hetero-agglomeration of anatase nanoparticles and magnetic clusters in aqueous suspensions Direct precipitation of anatase nanoparticles onto the magnetic clusters R&D cooperation with Cinkarna Celje Magnetic properties of superparamagnetic, photocatalytic particles. Superparamagnetic polymer nanocomposites Preparation of composite containing high content of dispersed magnetic nanoparticles: Dispersing hydrophobised nanoparticles in decane, addition of methyl methacrylate monomer, precipitation polymerization. oleic acid 50 nm Dispersing hydrophobised nanoparticles directly in methyl methacrylate monomer, polymerization in miniemulsion. ricinoleic acid Bonding initiator onto the nanoparticles, triggering polymerisation at the nanoparticles. Cooperation with M. Huskić, National institute of chemistry Department for Materials Synthesis Asst. Prof. Darja Lisjak Magnetic materials for applications at very high frequencies Car collision-avoidance systems Circulators Absorbers Thermal coating of absorber layers Electrophoretic deposition Electrophoretic deposition of hexaferrite Electrophoretic deposition of thick films of hexaferrite (nano)particles from suspensions for applications in mm-wave nonreciprocal devices: Thick film Suspension of nanoparticles Magnetophoretic deposition of hexaferrite Deposition of structured layers of magnetic particles using magnetic field: M S. Kolev Electrophoretic deposition of hexaferrite Magnetic properties of oriented BaFe12O19 film measured in two directions Θ=00 Θ=900 Nanocenter Equipment at K8 Laboratory for the processing and characterization of nanoparticles equipped with fume hoods and with basic laboratory equipment. • Autoclave (Parr 4641, volume 1 L ) for hydrothermal synthesis of nanoparticles. • Dynamic light-scattering granulometer (Fritsch ANALYSETTE 12 for measurements of the particle size in suspensions. DynaSizer) Vibrating-sample magnetometer (LakeShore 7404VSM) for magnetic measurements at room temperature. Prof. Darko Makovec (Darko.Makovec@ijs.si) Bernarda Anželak (Bernarda.Anzelak@ijs.si) Slavko Kralj (Slavko.Kralj@ijs.si) Dr. Sašo Gyergyek (Saso.Gyrgyek@ijs.si)