Nanoparticles

Nanoparticles Lecture 2 郭修伯

Top-down Approaches • milling or attrition • thermal cycles • 10 ~ 1000 nm; broad size distribution • varied particle shape or geometry • impurities • for nanocomposites and nanograined bulk materials (lower sintering temperature)

Bottom-up Approaches • Two approaches • thermodynamic equilibrium approach • generation of supersaturation • nucleation • subsequent growth • kinetic approach • limiting the amount of precursors for the growth • confining in a limited space

Homogeneous nucleation • Liquid, vapor or solid • supersaturation • temperature reduction • metal quantum dots in glass matrix by annealing • in situ chemical reactions (converting highly soluble chemicals into less soluble chemicals)

Homogeneous nucleation • Driving force Fig 3.1

Homogeneous nucleation Surface energy • Energy barrier Gibss free energy change

Nuclei • formation favor: • high initial concentration or supersaturation • low viscosity • low critical energy barrier • uniform nanoparticle size: • same time formation • abruptly high supersaturation -> quickly brought below the minimum nucleation concentration

Nuclei growth • Steps • growth species generation • diffusion from bulk to the growth surface • adsorption • surface growth • size distribution • A diffusion-limited growth VS. a growth-limited processes

Diffusion-limited growth • monosized nanoparticles • how? • Low/controlled supply growth species concentration • increase the solution viscosity • introduction a diffusion barrier

Metallic nanoparticles • Reduction of metal complexes in dilute solution • Diffusion-limited process maintaining • Example: nano-gold particles • chlorauric acid (2.5 x 10-4 M) 20 ml boiling solution+ sodium citrate (0.5%) 1 ml • 100°C till color change + water to maintain volume • uniform and stable 20 nm particles

Table 3.1

Other cases

Reduction reagents • Affect the size and size distribution • weak reduction reaction • larger particles • wider or narrower distribution (depends on “diffusion limited”) • Affect the morphology • type, concentration, pH value

Fig 3.10

Fig 3.12

Polymer stabilizer • To prevent agglomeration • surface interaction: • surface chemistry of solid, the polymer, solvent and temperature • Strong adsorbed stabilizers occupy the growth sites and reduce the growth rate • A. Henglein, Chem. Mater. 10, 444 (1998). • polyethyleneimine, sodium polyphosphate, sodium polyacrylate and poly(vinylpyrrolidone)

stabilizer concentration

temperature

Semiconductor nanoparticles • Pyrolysis (熱裂解)of organometallic precursor(s) dissolved in anhydrate solvents at elevated temperatures in an airless environment in the presence of polymer stabilizer (i.e., capping material) • Coordinating solvent • Solvent + capping material • phosphine + phosphine oxide (good candidate) • controlling growth process, stabilizing the colloidal dispersion, electronically passivating the surface

Process • discrete nucleation by rapid increase in the reagent concentration -> Ostwald ripening (熟成)during aging at increased temperature (large particle grow)-> size selective precipitation • Ostwald ripening • A dissolution-growth processes • large particles grow at the expense of small particles • produce highly monodispersed colloidal dispersions

Semiconductor nanocrystallites • C.B. Murray (CdE, E=S, Se, Te), 1993 • Dimethylcadmium (Me2Cd) + bis(trimethylsilyl) sulfide ((TMS)2S) or trioctylphosphine selenide (TOPSe) or Trioctylphosphine telluride (TOPTe) + solvent (Tri-n-octylphosphine, TOP) + capping material (tri-n-octylphosphine oxide, TOPO) • before aging (440 ~ 460nm), after aging at 230-260°C (1.5~11.5 nm) • Size-selective precipitation

Oxide nanoparticles • Several methods • principles: burst of homogeneous nucleation + diffusion controlled growth • most commonly: sol-gel processing • most studied: silica colloids

Sol-gel process • Synthesis • inorganic and organic-inorganic hybrid materials colloidal dispersions • powders, fibers, thin film and monolith(整塊) • low temperature and molecular level homogeneity • Ref • Sol-Gel Science by Brinker and Scherer; Introduction to Sol-Gel Processing by Pierre; Sol-Gel Materials by Wright and Sommerdijk

Sol-gel process • Hydrolysis • e.g. • Condensation of precursors • e.g. • typical precursors: metal alkoxides or inorganic and organic salts

Multicomponents materials • Sol-gel route • ensure hetero-condensation reactions between different constituent precursors • reactivity, electronegativity, coordination number, ionic radius • precursor modification: attaching different organic ligands (e.g. reactivity: Si(OC2H5)4 < Si(OCH3)4) ) • chemically modify the coordination state of the alkoxides • multiple step sol-gel

Organic-inorganic hybrids • Incorporating organic components into an oxide system by sol-gel processing • co-polymerization • co-condense • trap the desired organic (or bio) components inside the network • biocomponents-organic-inorganic hybrids

Sol-gel products • Monodispersed nanoparticles • temporal nucleation followed by diffusion-controlled growth • complex oxides, organic-inorganic hybrids, biomaterials • size = f(concentration, aging time) • colloid stabilization: not by polymer steric barrier, by electrostatic double layer

Sol-gel example: silica • Precursors: • silicone alkoxides with different alkyl ligand sizes • catalyst: • ammonia • solvent: • various alcohols Vigorous stirring water

Vapor phase reactions • Same mechanism as liquid phase reaction • Elevated temperatures + vacuum (low concentration of growth) • Collection on a down stream non-sticking substrate @ low temperature • example: 2~3 nm silver particles • may migrate and agglomerate

Vapor phase reactions • Agglomerates: • large size spherical particles • needle-like particle • Au on (100) NaCl and (111) CaF substrate • Ag on (100) NaCl substrate • change in temperature and precursor concentration did not affect the morphology • size affections • reaction and nucleation temperature

Solid state phase segregation • applications • metals and semiconductor particles in glass matrix • homogeneous nucleation in solids state • metal or semiconductor precursors introduced to and homogeneously distributed in the liquid glass melt at high temperature • glass quenching to room temperature • glass anneal above the Tg • solid-state diffusion and nanoparticles formed

Solid state phase segregation • Glass matrix (or via sol-gel, polymerization): • metallic ions • Reheating (or UV, X-ray, gamma-ray): • metallic atoms • Nuclei growth by solid-state diffusion (slow!)

Solid state phase segregation

Heterogeneous nucleation • A new phase forms on a surface of another material • thermal oxidation, sputtering and thermal oxidation, Ar plasma and ulterior thermal oxidation • associate with surface defects (or edges)

Heterogeneous nucleation

Kinetically confined synthesis • Spatially confine the growth • limited amount of source materials or available space is filled up • groups • liquid droplets in gas phase (aerosol & spray) • liquid droplets in liquid (micelle & microemulsion) • template-based • self-terminating

Micelles or microemulsion • micelles • surfactants or block polymers • two parts: one hydrophilic and one hydrophobic • self-assemble at air/aqueous solution or hydrocarbon/aqueous solution interfaces • microemulsion • dispersion of fine organic liquid droplets in an aqueous solution

Micelle • CdSe nanoparticles by Steigerwald et al. • surfactant AOT (33.3g) + heptane (1300ml)+ water (4.3ml) • stirred -> microemulsion • 1.0M Cd2+ (1.12 ml) + microemulsion • Se(TMS)2 (210μl) + heptane (50ml) + microemulsion (syringe, 注射) • formation of CdSe crystallites

Polymer nanoparticles • Water-soluble initiator + surfactant + water + monomer • monomer (large droplets, 0.5 ~ 10μm ) • initiator • polymerization • nanoparticles (50 ~ 200nm)

Aerosol synthesis • Characteristics • Regarded as top-down (maybe?) • can be polycrystalline • needs collection and redispersion • process • liquid precursor -> mistify -> liquid aerosol -> evaporation or reaction -> nanoparticles • polymer particle 1~20 μm (from monomer droplets)

Size control by termination • Termination by organic components or alien ion occupation

Spray pyrolysis • Solution process • metal (Cu, Ni …) and metal oxide powders • converting microsized liquid droplets of precursor or precursor mixture into solid particles through heating • droplets -> evaporation -> solute condensation -> decomposition & reaction -> sintering • e.g. silver particle: Ag2CO3, Ag2O and AgNO3 with NH4HCO3 @ 400°C

Template-based synthesis • Templates • cation exchange resins with micropores • zeolites • silicate glasses • ion exchange • gas deposition on shadow mask (template)

Core-shell nanoparticles • The growth condition control • no homogeneous nucleation occur and only grow on the surface • concentration control: not high enough for nucleation but high enough for growth • drop wise addition • temperature control

Semiconductor industry

Nanoparticles

Nanoparticles

Presentation Transcript

Nanoparticles

Nanoparticles

Nanoparticles

Silver Nanoparticles

Conducting nanoparticles

Ferromagnetic Nanoparticles

Nanoparticles

Bactericidal Nanoparticles

JRG Nanoparticles

Nanoparticles and Health

Magnetic nanoparticles

Detection of nanoparticles

Magnetite Nanoparticles

Magnetite Nanoparticles

Silver Nanoparticles

Nanoparticles

Silver Nanoparticles

nanoparticles

Silica Nanoparticles

sirna nanoparticles

Metal Nanoparticles