Understanding the Nanotube Growth Mechanism: A Strategy to Control Nanotube Chirality during Chemical Vapor Deposition Synthesis

Gomez Gualdron, Diego Armando 1983-

14 March 2013

For two decades, single-wall carbon nanotubes (SWCNTs) have captured the attention of the research community, and become one of the flagships of nanotechnology. Due to their remarkable electronic and optical properties, SWCNTs are prime candidates for the creation of novel and revolutionary electronic, medical, and energy technologies. However, a major stumbling block in the exploitation of nanotube-based technologies is the lack of control of nanotube structure (chirality) during synthesis, which is intimately related to the metallic or semiconductor character of the nanotube. Incomplete understanding of the nanotube growth mechanism hinders a rationale and cost-efficient search of experimental conditions that give way to structural (chiral) control. Thus, computational techniques such as density functional theory (DFT), and reactive molecular dynamics (RMD) are valuable tools that provide the necessary theoretical framework to guide the design of experiments. The nanotube chirality is determined by the helicity of the nanotube and its diameter. DFT calculations show that once a small nanotube 'seed' is nucleated, growth proceeds faster if the seed corresponds to a high chiral angle nanotube. Thus, a strategy to gain control of the nanotube structure during chemical vapor deposition synthesis must focus on controlling the structure of the nucleated nanotube seeds. DFT and RMD simulations demonstrate the viability of using the structures of catalyst particles over which nanotube growth proceeds as templates guiding nanotube growth toward desired chiralities. This effect occurs through epitaxial effects between the nanocatalyst and the nanotube growing on it. The effectiveness of such effects has a non-monotonic relationship with the size of the nanocatalyst, and its interaction with the support, and requires fine-tuning reaction conditions for its exploitation. RMD simulations also demonstrate that carbon bulk-diffusion and nanoparticle supersaturation are not needed to promote nanotube growth, hence reaction conditions that increase nanoparticle stability, but reduce carbon solubility, may be explored to achieve nanotube templated growth of desired chiralities. The effect of carbon dissolution was further demonstrated through analyses of calculated diffusion coefficients. The metallic nanocatalyst was determined to be in viscous solid state throughout growth, but with a less solid character during the induction/nucleation stage.

Nanoparticle

Growth Mechanism

Catalysis

CVD

Molecular Simulation

Carbon Nanotube

Study of stability of ZnO nanoparticles and growth mechanisms of colloidal ZnO nanorods

Lee, Kwang Jik

30 October 2006

After hydrolyzing zinc acetate in methanol solution, spherical ZnO nanoparticles in the size range from about 2.5 to 5 nm were synthesized by maintaining a ZnO concentration of 0.02M. Compared to ZnO nanoparticles prepared via other methods, the particles prepared using our novel colloidal chemistry exhibit narrow size distribution and a high sensitivity to the surrounding environment. The structure and composition of the white powders precipitated from the colloidal solution can vary, depending on how the powder samples are prepared. Factors such as desorption and adsorption of methanol, binding of water and exposure to humid air have been studied to correlate to the structure and composition observed from the precipitated powder. Methanol desorption rate and excess KOH on the particle surface have played an important role in the structural changes. Furthermore, upon annealing, the white precipitate is recovered to wurtize ZnO. XRD and TEM are used to study the structural transformation of ZnO nanoparticles.

ZnO Nanocrystals

Stability

Nanorods

Growth Mechanism

Wet-Chemistry

Formation and growth mechanisms of single-walled metal oxide nanotubes

Yucelen, Gulfem Ipek

04 June 2012

Single-walled metal oxide nanotubes have emerged as an important class of 'building block' materials for molecular recognition-based applications in catalysis, separations, sensing, and molecular encapsulation due to their vast range of potentially accessible compositions and structures, and their unique properties such as well-defined wall structure and porosity, tunable dimensions, and chemically modifiable interior and exterior surfaces. However, their widespread application will depend on the development of synthesis processes that can yield structurally and compositionally well-controlled nanotubes. Moreover, such processes should be amenable to scale-up and preferably operate via benign chemistries under mild conditions. There is currently very little knowledge on the molecular-level 'design rules' underlying the engineering of such materials. The capability to engineer single-walled tubular materials would lead to a range of structures, with novel properties relevant to diverse applications. In this thesis, main objectives are to discover the first molecular-level mechanistic framework governing the formation and growth of single-walled metal-oxide nanotubes, apply this framework to demonstrate the engineering of nanotubular materials of controlled dimensions, and to progress towards a quantitative multiscale understanding of nanotube formation. The class of aluminosilicate (AlSiOH)/germanate (AlGeOH) nanotubes are of particular interest to us, and serve as the exemplar materials for single-walled metal oxide nanotubes. They can be synthesized in pure form from inexpensive and easily accessible reactants at low temperatures (95 ˚C) from aqueous solutions. The synthesis of nanotubes occurs on a time-scale of hours to days, making them an ideal model system to study the nanotube formation mechanism. In Chapter 2, the identification and elucidation of the mechanistic role of molecular precursors and nanoscale (1-3 nm) intermediates with intrinsic curvature, in the formation of single-walled aluminosilicate nanotubes is reported. The structural and compositional evolution of molecular and nanoscale species over a length scale of 0.1-100 nm, are characterized by electrospray ionization (ESI) mass spectrometry, and nuclear magnetic resonance (NMR) spectroscopy. DFT calculations revealed the intrinsic curvature of nanoscale intermediates with bonding environments similar to the structure of the final nanotube product. It is shown that curved nano-intermediates form in aqueous synthesis solutions immediately after initial hydrolysis of reactants at 25 ˚C, disappear from the solution upon heating to 95 ˚C due to condensation, and finally rearrange to form ordered single-walled aluminosilicate nanotubes. Integration of all results leads to the construction of the first molecular-level mechanism of single-walled metal oxide nanotube formation, incorporating the role of monomeric and polymeric aluminosilicate species as well as larger nanoparticles. Then, in Chapter 3, new molecular-level concepts for constructing nanoscopic metal oxide objects are demonstrated. The diameters of metal oxide nanotubes are shaped with Ångstrom-level precision by controlling the shape of nanometer-scale precursors. The subtle relationships between precursor shape and structure and final nanotube curvature are measured (at the molecular level). Anionic ligands (both organic and inorganic) are used to exert fine control over precursor shapes, allowing assembly into nanotubes whose diameters relate directly to the curvatures of shaped precursors. Having obtained considerable insight into aluminosilicate nanotube formation, in Chapter 4 the complex aqueous chemistry of nanotube-forming aluminogermanate solutions are examined. The aluminogermanate system is particularly interesting since it forms ultra-short nanotubes of lengths as small as ~20 nm. Insights into the underlying important mechanistic differences between aluminogermanate and aluminosilicate nanotube growth as well as structural differences in the final nanotube dimensions are provided. Furthermore, an experimental example of control over nanotube length is shown, using the understanding of the mechanistic differences, along with further suggestions for possible ways of controlling nanotube lengths. Ultimately, it is desired to produce the single-walled aluminosilicate nanotubes on a larger scale (e.g., kilogram or ton scales) for technological application. However, a quantitative multiscale understanding of nanotube growth via a detailed growth model, is critical to be able to predict and control key properties such as the length distribution and concentration of the nanotubes. Such a model can then be used to design liquid-phase reactors for scale-up of nanotube synthesis. In Chapter 5, a generalized kinetic model is formulated to describe the reactions leading to formation and growth of single-walled metal oxide nanotubes. This model is capable of explaining and predicting the evolution of nanotube populations as a function of kinetic parameters. It also allows considerable insight into meso/microscale nanotube growth processes. For example, it shows that two different mechanisms operate during nanotube growth: (1) growth by precursor addition, and (2) by oriented attachment of nanotubes to each other. In Chapter 6, a study of the structure of the nanotube walls is presented. It has usually been assumed in the literature that the nanotube wall is free of defects. A combination of 1H-29Si and 1H-27Al FSLG-HETCOR, 1H CRAMPS, and 1H-29Si CP/MAS NMR experiments were employed to evaluate the proton environments around Al and Si atoms during nanotube synthesis and in the final structure. The HETCOR experiments allowed to track the evolving Si and Al environments during the formation of the nanotubes from precursor species, and relate them to the Si and Al coordination environments found in the final nanotube structure. The 1H CRAMPS spectra of dehydrated aluminosilicate nanotubes revealed the proton environments in great detail. Integration of all the NMR results allows the structural assignment of all the chemical shifts and the identification of various types of defect structures in the aluminosilicate nanotube wall. In particular, five main types of defect structures are identified arising from specific atomic vacancies in the nanotube structure. It is estimated that ~16% of Si atoms in the nanotube inner wall are involved in a defect structure. The characterization of the detailed structure of the nanotube wall is expected to have significant implications for its chemical properties and applications. Chapter 7 contains concluding remarks, as well as suggestions for future directions in the engineering of single-walled nanotube materials.

Nanotubes

Inorganic nanotubes

Imogolite

Growth mechanism

Nanotubes Synthesis

Metallic oxides

IMPLEMENTATION OF NOVEL RECEPTOR-TRANSDUCTION CONCEPTS AND MATERIAL MORPHOLOGIES IN GAS SENSORICS

Strelcov, Evgheni

01 August 2011

Low dimensional nanostructures have defined the frontier of the research in material science for the last two decades. Presented here are the results of experimental research on growth, device fabrication and application of quasi-one dimensional phthalocyanines and metal oxides to gas-sensing. The possibility of rational tuning of the growth conditions, in order to control composition, morphology, size, orientation and alignment of the grown low-dimensional nanostructures was investigated. Employing custom designed heating stages coupled with optical microscope the in situ approach of monitoring the growth of nanostructures has been realized. Using this method, the growth of VO2 nanowires and nanoplatelets have been investigated and two novel growth mechanisms were discovered and explained. A variety of phthalocyanine and metal-oxide nanowire-based chemical sensors have been proposed, fabricated and tested. The focus of our research was on the development of new sensing principles and the improvement of existing ones. In particular, nanowires of tin and titanium dioxide were proposed to be used as self-heated chemiresistors capable of operating in the absence of an external heater, thus paving the way for ultra-low power consumption sensors. For the first time VO2 nanowires were used to create a nano-Pirani gauge and a gas sensor employing a sharp temperature-driven metal-insulator transition in this material. The sensor is sensitive to both chemically active and inert gases. Its performance is modeled and optimization parameters are presented.

gas sensors

growth mechanism

nanostructures

phthalocyanines

self-heating

vanadium oxides

Theoretical investigation of the growth mechanism of gold thiolate nanoparticles

Barngrover, Brian Michael

January 1900

Doctor of Philosophy / Department of Chemistry / Christine M. Aikens / This body of work describes a theoretical study of the growth mechanism of gold thiolate nanoparticles from Au(III) as synthesized in the Brust-Schiffrin method. The Au(III) salt can be reduced to form Au(I) by two thiols or a hydride. Depending on the polarity of the solvent, the Au(I) species will either yield rings and anionic chains, remain in isolation, or create an ionic complex with the phase transfer agent. No matter what form the Au(I) species takes, a second reduction must occur to yield Au(0). If the solvent is polar, such as methanol or water, and the Au(I) species is a ring or anionic chain, then a hydride can reduce the structure and create a gold-gold bond and dissociate a thiol from the structure. The gold atoms involved in the gold-gold bond would have a formal Au(0) oxidation state. However if the Au(I) species can be kept from forming rings or chains in the polar solvent or if the system is in a nonpolar solvent, then two Au(I) species in close proximity in the presence of hydride can react to yield a non-radical Au(0) species. The oxidation of bare gold nanoclusters by thiol will also be examined, such as in the case of SMAD-produced gold nanoparticles. In this process, the gold nanoclusters are initially in the Au(0) oxidation state. However the SR-Au-SR “staple” motifs that are known to passivate gold nanoparticles contain Au(I) species. The adsorption of thiol on various sizes of gold clusters in several charge states will be calculated and the mechanism for the oxidation of Au3 and three-dimensional Au12 will be modeled. The rate-limiting step is found to be the thiol hydrogen dissociation onto the gold cluster. Once this dissociation occurs, the hydrogen can move freely around the surface. Finally, Au25(SH)18- will be investigated as a catalyst for selective hydrogenation of α,β-unsaturated aldehyde. The dependence of the energetics of hydrogen gas dissociation on Au25(SH)18- on the functional and Grimme dispersion correction employed will also be examined.

DFT

Gold thiolate

Growth mechanism

Catalysis

Chemistry (0485)

Nanoscience (0565)

Physical Chemistry (0494)

Estudo sobre a conversão, formação e desenvolvimento de nanopartículas de prata pelo método de Turkevich modificado. / Study about conversion, formation and development of silver nanoparticles by a modified method of Turkevich.

Oliveira, Roberto Angelo de

21 June 2013

Pretendeu-se, com este trabalho, estudar a síntese e o desenvolvimento de nanopartículas de prata, utilizando o método de Turkevich com algumas modificações. Dada a importância dessas nanopartículas no atual desenvolvimento científico, é de grande valia o melhor entendimento dos mecanismos que regem a síntese e desenvolvimento das nanopartículas de prata. Neste método, nitrato de prata sofre redução pelo citrato de sódio, numa mistura aquecida e bem agitada, para formar as nanopartículas. Amostras dessa mistura foram coletadas em vários intervalos de tempo, e reservadas para análises de concentração de prata por ICPAES, absorbância UV-Vis, imagens de MEV e distribuição de tamanhos por DLS. Com essas análises, foi possível estabelecer uma relação direta entre os valores de absorbância e os de conversão de prata. Também foi possível propor uma rota de desenvolvimento das nanopartículas, mostrando que, durante esse desenvolvimento, as partículas apresentam diferentes morfologias, tamanhos e tendência a formar aglomerados. Dependendo da aplicação das nanopartículas de prata, é possível interromper a reação quando elas apresentarem as características mais favoráveis. / It was intended, with this work, to study the synthesis and development of silver nanoparticles using the Turkevich method with some modifications. Given the importance of these nanoparticles in the current scientific development, it is of great value the better understanding of the mechanisms governing the synthesis and growth of silver nanoparticles. In this method, silver nitrate is reduced by sodium citrate, in a well-stirred and heated mixture to form nanoparticles. Samples of this mixture were taken at various time intervals, and reserved for analysis of silver concentration by ICP-AES, UV-Vis absorbance, SEM images and size distribution by DLS. With these analyzes, it was possible to establish a direct relationship between the absorbance values and the conversion of silver. It was also possible to propose a synthesis and growth pathway of the silver nanoparticles, showing that during this development, the particles have different morphologies, sizes and tendencies to form agglomerates. Depending on the application of silver nanoparticles, it is possible to stop the reaction when they have the most favorable characteristics.

Conversão

Conversion

Growth mechanism

Mecanismo de crescimento

Nanopartícula de prata

Silver nanoparticle

Síntese

Synthesis

Drowning-out crystallisation of benzoic acid : Influence of processing conditions and solvent composition on crystal size and shape

Holmbäck, Xiomara

January 2002

The aim of the present investigation is to increase theunderstanding of the role played by the solvent in inhibitingor enhancing crystal growth. Drowning-out crystallizationexperiments has been performed by the controlled addition ofwater or ethanol water mixtures to a saturated solution ofbenzoic acid in ethanol-water mixtures. Crystal habitcontrolling factors have been identified.Seededcrystallization experiments have been carried out to evaluatethe effect of solvent composition on crystal habit at constantsupersaturation. The solubility of benzoic acid inethanol-water mixtures at the working temperatures has beendetermined. Electro-zone sensing determinations and microscopicmeasurements are used to characterize the final crystallineproduct. It has been found that the shape of the benzoic acidcrystals grown from ethanol-water solutions ranges from needlesto platelets. Platy particles possess a predominant basal plane(001), bound by (010) and (100) faces, while needles aredeveloped along the b-axis. Long needle-shaped particles havebeen produced at low initial bulk concentration and highethanol concentration in the feed. Small platelets are obtainedat high initial bulk concentrations and high waterconcentration in the feed. The effect of solvent composition on the growth rate hasbeen evaluated at constant supersaturation. Seed crystals arecharacterized by image analysis measurement both before andafter each experiment. Length and width dimensions have beenmeasured on the particle silhouette. The growth rate, thesolid-liquid interfacial energy and the surface entropy factorfor the (010) faces (length dimension) and (100) faces (widthdimension) have been estimated. The interfacial energy andsurface entropy factor decreases in the direction of increasingethanol concentration due to increasing solubility. The results suggest that at low ethanol concentration(xEtOH&lt;60%) growth proceeds by screw dislocation mechanism,and adsorption of ethanol molecules may reduce the growth rate.As the ethanol concentration increases above a critical value(xEtOH ≥60%), the growth mechanism shifts to surfacenucleation and the growth rate increases with increasingethanol concentration. It has been suggested that the observedeffect of the solvent composition on crystal habit is theresult of two conflicting effects here referred as the kineticand interfacial energy effects. High interactions of the pairethanol-benzoic acid seem to be responsible of the growthretardation (kinetic effect) exerted by the solvent. On theother hand, increased ethanol concentration leads to reduceinterfacial energy and increasing surface nucleation whichmight contribute to enhance growth kinetics. <b>Keywords:</b>drowning-out crystallisation, solventcomposition, benzoic acid, solubility, crystal growth,interfacial energy, surface entropy factor, growth mechanism,crystal shape distribution.

solvent effect

drowning-out

crystallization

benzoic acid

solubility

crystal habit

crystal growth

interfacial energy

growth mechanism

Synthesis, Characterization, and Growth Mechanism of Single-Walled Metal Oxide Nanotubes

Mukherjee, Sanjoy

03 July 2007

Nanotubes have numerous potential applications in areas such as biotechnology, electronics, photonics, catalysis and separations. There are several challenges to be overcome in order to realize their potential, such as: (1) Synthesis of monodisperse (in diameter and in length) single-walled nanotubes; (2) Quantitative understanding of the mechanism of formation and growth of nanotubes; (3) Capability to engineer the nanotube size; (4) Low temperature synthesis process; and (5) Synthesis of impurity free nanotubes. Our investigation focuses on a class of metal oxide (aluminosilicate/germanate) nanotubes, which are; single walled nanotubes with monodisperse inner and outer diameters, can be synthesized in the laboratory by a low temperature (95ºC) process in mildly acidic aqueous solutions, and their formation timescales is hours, which makes it convenient as a model system to study the mechanisms of nanotube formation. This work is focused on obtaining a qualitative and quantitative understanding of the mechanism of formation of aluminosilicate and aluminogermanate nanotubes. In order to achieve this overall objective, this thesis consists of the following aspects: (1) A systematic phenomenological study of the growth and structural properties of aluminosilicate and aluminogermanate nanotubes. The constant size and increasing nanotube concentration over the synthesis time strongly suggest that these nanotubular are assembled through self-assembly process. (II) Investigation of the mechanism of formation of single-walled aluminogermanate nanotubes provided the central phenomena underlying the formation of these nanostructures: (1) the generation (via pH control) of a precursor solution containing chemically bonded precursors, (2) the formation of amorphous nanoscale (~ 6 nm) condensates via temperature control, and (3) the self-assembly of short nanotubes from the amorphous nanoscale condensates. (III) Synthesis of mixed metal oxide (aluminosilicogermanate) nanotubes with precise control of elemental composition, diameter and length of the product nanotubes. (IV) Preliminary work towards generalization of the kinetic model developed for aluminogermanate nanotubes to a larger class of metal oxide nanotubes. It was found that the size of nanotubes is dependent on the amount of precursors that can be packed in a single ANP and in turn depends on the size of the ANP.

Imogolite

Aluminosilicate

Growth mechanism

Metal oxide

Self-assembly

Kinetic model

Nanotubes

Nanotubes Synthesis

Metallic oxides

Drowning-out crystallisation of benzoic acid : Influence of processing conditions and solvent composition on crystal size and shape

Holmbäck, Xiomara

January 2002

<p>The aim of the present investigation is to increase theunderstanding of the role played by the solvent in inhibitingor enhancing crystal growth. Drowning-out crystallizationexperiments has been performed by the controlled addition ofwater or ethanol water mixtures to a saturated solution ofbenzoic acid in ethanol-water mixtures. Crystal habitcontrolling factors have been identified.Seededcrystallization experiments have been carried out to evaluatethe effect of solvent composition on crystal habit at constantsupersaturation. The solubility of benzoic acid inethanol-water mixtures at the working temperatures has beendetermined.</p><p>Electro-zone sensing determinations and microscopicmeasurements are used to characterize the final crystallineproduct. It has been found that the shape of the benzoic acidcrystals grown from ethanol-water solutions ranges from needlesto platelets. Platy particles possess a predominant basal plane(001), bound by (010) and (100) faces, while needles aredeveloped along the b-axis. Long needle-shaped particles havebeen produced at low initial bulk concentration and highethanol concentration in the feed. Small platelets are obtainedat high initial bulk concentrations and high waterconcentration in the feed.</p><p>The effect of solvent composition on the growth rate hasbeen evaluated at constant supersaturation. Seed crystals arecharacterized by image analysis measurement both before andafter each experiment. Length and width dimensions have beenmeasured on the particle silhouette. The growth rate, thesolid-liquid interfacial energy and the surface entropy factorfor the (010) faces (length dimension) and (100) faces (widthdimension) have been estimated. The interfacial energy andsurface entropy factor decreases in the direction of increasingethanol concentration due to increasing solubility.</p><p>The results suggest that at low ethanol concentration(xEtOH<60%) growth proceeds by screw dislocation mechanism,and adsorption of ethanol molecules may reduce the growth rate.As the ethanol concentration increases above a critical value(xEtOH ≥60%), the growth mechanism shifts to surfacenucleation and the growth rate increases with increasingethanol concentration. It has been suggested that the observedeffect of the solvent composition on crystal habit is theresult of two conflicting effects here referred as the kineticand interfacial energy effects. High interactions of the pairethanol-benzoic acid seem to be responsible of the growthretardation (kinetic effect) exerted by the solvent. On theother hand, increased ethanol concentration leads to reduceinterfacial energy and increasing surface nucleation whichmight contribute to enhance growth kinetics.</p><p><b>Keywords:</b>drowning-out crystallisation, solventcomposition, benzoic acid, solubility, crystal growth,interfacial energy, surface entropy factor, growth mechanism,crystal shape distribution.</p>

solvent effect

drowning-out

crystallization

benzoic acid

solubility

crystal habit

crystal growth

interfacial energy

growth mechanism

Estudo sobre a conversão, formação e desenvolvimento de nanopartículas de prata pelo método de Turkevich modificado. / Study about conversion, formation and development of silver nanoparticles by a modified method of Turkevich.

Roberto Angelo de Oliveira

21 June 2013

Pretendeu-se, com este trabalho, estudar a síntese e o desenvolvimento de nanopartículas de prata, utilizando o método de Turkevich com algumas modificações. Dada a importância dessas nanopartículas no atual desenvolvimento científico, é de grande valia o melhor entendimento dos mecanismos que regem a síntese e desenvolvimento das nanopartículas de prata. Neste método, nitrato de prata sofre redução pelo citrato de sódio, numa mistura aquecida e bem agitada, para formar as nanopartículas. Amostras dessa mistura foram coletadas em vários intervalos de tempo, e reservadas para análises de concentração de prata por ICPAES, absorbância UV-Vis, imagens de MEV e distribuição de tamanhos por DLS. Com essas análises, foi possível estabelecer uma relação direta entre os valores de absorbância e os de conversão de prata. Também foi possível propor uma rota de desenvolvimento das nanopartículas, mostrando que, durante esse desenvolvimento, as partículas apresentam diferentes morfologias, tamanhos e tendência a formar aglomerados. Dependendo da aplicação das nanopartículas de prata, é possível interromper a reação quando elas apresentarem as características mais favoráveis. / It was intended, with this work, to study the synthesis and development of silver nanoparticles using the Turkevich method with some modifications. Given the importance of these nanoparticles in the current scientific development, it is of great value the better understanding of the mechanisms governing the synthesis and growth of silver nanoparticles. In this method, silver nitrate is reduced by sodium citrate, in a well-stirred and heated mixture to form nanoparticles. Samples of this mixture were taken at various time intervals, and reserved for analysis of silver concentration by ICP-AES, UV-Vis absorbance, SEM images and size distribution by DLS. With these analyzes, it was possible to establish a direct relationship between the absorbance values and the conversion of silver. It was also possible to propose a synthesis and growth pathway of the silver nanoparticles, showing that during this development, the particles have different morphologies, sizes and tendencies to form agglomerates. Depending on the application of silver nanoparticles, it is possible to stop the reaction when they have the most favorable characteristics.

Conversão

Mecanismo de crescimento

Nanopartícula de prata

Síntese

Conversion

Growth mechanism

Silver nanoparticle

Synthesis