Non-Precious Cathode Electrocatalytic Materials for Zinc-Air Battery

Kim, Baejung

13 December 2013

In the past decade, rechargeable batteries attracted the attention from the researchers in search for renewable and sustainable energy sources. Up to date, lithium-ion battery is the most commercialized and has been supplying power to electronic devices and hybrid and electric vehicles. Lithium-ion battery, however, does not satisfy the expectations of ever-increasing energy and power density, which of their limits owes to its intercalation chemistry and the safety.1-2 Therefore, metal-air battery drew much attention as an alternative for its high energy density and a simple cell configuration.1 There are several different types of metal-air batteries that convey different viable reaction mechanisms depending on the anode metals; such as Li, Al, Ca, Cd, and Zn. Redox reactions take place in a metal-air cell regardless of the anode metal; oxidation reaction at the anode and reduction reaction at the air electrode. Between the two reaction, the oxygen reduction reaction (ORR) at the air electrode is the relatively the limiting factor within the overall cell reactions. The sluggish ORR kinetics greatly affects the performance of the battery system in terms of power output, efficiency, and durability. Therefore, researchers have put tremendous efforts in developing highly efficient metal air batteries and fuel cells, especially for high capacity applications such as electric vehicles. Currently, the catalyst with platinum nanoparticles supported on carbon material (Pt-C) is considered to exhibit the best ORR activities. Despite of the admirable electrocatalytic performance, Pt-C suffers from its lack of practicality in commercialization due to their prohibitively high cost and scarcity as of being a precious metal. Thus, there is increasing demand for replacing Pt with more abundant metals due economic feasibility and sustainability of this noble metal.3-5 Two different attitudes are taken for solution. The first approach is by optimizing the platinum loading in the formulation, or the alternatively the platinum can be replaced with non-precious materials. The purpose of this work is to discover and synthesize alternative catalysts for metal-air battery applications through optimized method without addition of precious metals. Different non-precious metals are investigated as the replacement of the precious metal including transition metal alloys, transition metal or mixed metal oxides, and chalcogenides. These types of metals, alone, still exhibits unsatisfying, yet worse, kinetics in comparison to the precious metals. Nitrogen-doped carbon material is a recently well studied carbon based material that exhibits great potential towards the cathodic reaction.6 Nitrogen-doped carbon materials are found to exhibit higher catalytic activity compared to the mentioned types of metals for its improved conductivity. Benefits of the carbon based materials are in its abundance and minimal environmental footprints. However, the degradation of these materials has demonstrated loss of catalytic activity through destruction of active sites containing the transition metal centre, ultimately causing infeasible stability. To compensate for these drawbacks and other limits of the nitrogen-doped carbon based catalysts, nitrogen-doped carbon nanotubes (NCNT) are also investigated in the series of study. The first investigation focuses on a development of a simple method to thermally synthesize a non-precious metal based nitrogen-doped graphene (NG) electrocatalyst using exfoliated graphene (Ex-G) and urea with varying amounts of iron (Fe) precursor. The morphology and structural features of the synthesized electrocatalyst (Fe-NG) were characterized by SEM and TEM, revealing the existence of graphitic nanoshells that potentially contribute to the ORR activity by providing a higher degree of edge plane exposure. The surface elemental composition of the catalyst was analyzed through XPS, which showed high content of a total N species (~8 at.%) indicative of the effective N-doping, present mostly in the form of pyridinic nitrogen groups. The oxygen reduction reaction (ORR) performance of the catalyst was evaluated by rotating disk electrode voltammetry in alkaline electrolyte and in a zinc-air battery cell. Fe-NG demonstrated high onset and half-wave potentials of -0.023 V (vs. SCE) and -0.110 V (vs. SCE), respectively. This excellent ORR activity is translated into practical zinc-air battery performance capabilities approaching that of commercial platinum based catalyst. Another approach was made in the carbon materials to further improve the cost of the electrode. Popular carbon allotropes, CNT and graphene, are combined as a composite (GC) and heteroatoms, nitrogen and sulfur, are introduced in order to improve the charge distribution of the graphitic network. Dopants were doped through two step processes; nitrogen dopant was introduced into the graphitic framework followed by the sulfur dopant. The coexistence of the two heteroatoms as dopants demonstrated outstanding ORR performance to those of reported as metal free catalysts. Furthermore, effects of temperature were investigated through comparing ORR performances of the catalysts synthesized in two different temperatures (500 ??? and 900 ???) during the N-doping process (consistent temperature was used for S-doping). Through XPS analysis of the surface chemistry of catalysts produced with high temperature during the N-doping step showed absence of N-species after the subsequent S-doping process (GC-NHS). Thus, the synergetic effects of the two heteroatoms were not revealed during the half-cell testing. Meanwhile, the two heteroatoms were verified in the catalyst synthesized though using low temperature during the N-doping process followed by the S-doping step (GC-NLS). Consequently, ORR activity of the resulting material demonstrated promising onset and half-wave potentials of -0.117 V (vs. SCE) and -0.193 V (vs. SCE). In combination of these investigations, this document introduces thorough study of novel materials and their performance in its application as ORR catalyst in metal air batteries. Moreover, this report provides detailed fundamental insights of carbon allotropes, and their properties as potential elecrocatalysts and essential concepts in electrochemistry that lies behind zinc-air batteries. The outstanding performances of carbon based electrocatalyst are reviewed and used as the guides for further direction in the development of metal-air batteries as a promising sustainable energy resource in the future.

oxygen reduction reaction

graphene nanosheet

carbon nanotube

zinc-air battery

composite

activity

dual-doped graphene

exfoliated graphene

iron

nano-shells

nitrogen-doped graphene

sulfur-doped graphene

Synthesis and characterization of nitrogen-doped titanium oxide nanoparticles for visible-light photocatalytic wastewater treatment

Pelaschi, Mohammad Ali

05 October 2018

TiO2 nanoparticles are one of the most suitable materials for photocatalysis, specifically for water and air treatment and removal of a wide variety of organic pollutants such as dyes, aromatic compounds, and chlorinated aromatic compounds. Methods of synthesis of TiO2 are generally categorized in two main classes of wet chemical, and dry methods. Wet chemical methods generally provide a better control over size, size distribution, and shape; all of which significantly affect photocatalytic performance of the produced nanoparticles. Despite its advantages over other semiconductor photocatalysts, wide band-gap of titania restrains its photocatalytic activity to only UV light, which only makes up to 5% of the light reaching surface of the earth. To induce visible-light activity, titania has been doped by different dopants, including transition metal-dopants such as Fe, and Co and non-metal dopants such as N, and C. Nitrogen has been shown to be a better dopant, providing a suitably placed energy state within the band-gap of TiO2, and not suffering from issues related to transition-metal dopants such as low thermal and physical stability and high electron-hole recombination rates. To dope titania with nitrogen, one could add the nitrogen source together with other precursors during synthesis, referred to as wet chemical doping methods, or anneal the synthesized titania nanoparticles under a flow of ammonia at high temperatures, referred to as dry doping methods. While different doping methods have been studied individually, the author maintains that there has been an absence of research comparing the effectiveness of these methods, on photocatalytic performance of N-doped TiO2 within a consistent experiment. In this research TiO2 nanoparticles were synthesized by a facile, inexpensive sol-gel method, and doping was done by wet chemical methods, dry methods, and a combination of both these methods. Visible-light photocatalytic activity of these nanoparticles was evaluated by their efficiency in degradation of methyl orange. The results show wet doping methods increase the efficiency of titania nanoparticles more than dry doping, or combination of both. Further investigation showed that the main reason for higher activity of wet chemically doped nanoparticles is due to their higher available surface area of 131.7 m2.g-1. After normalizing the available surface area, measured by the BET method, it was shown that a combination of wet chemical doping, and dry doping at 600 °C result in the most active nanoparticles, but high temperature dry doping severely decreases the surface area, lowering the overall efficiency of the product. Additionally, N-doped TiO2 nanoparticles were synthesized using a simple hydrothermal method, in which the nitrogen source was used not only to dope, but also to control shape, size, size distribution, and morphology of the titania nanoparticles, and to induce aqueous colloidal stability. It was shown that addition of triethylamine during the synthesis, results in ultra-small, colloidally stable, cubic TiO2 nanoparticles, while using triethanolamine results in formation of TiO2 pallets, assembled into spherical, rose-like structures. The synthesized nanoparticles show impressive efficiency in visible-light removal of phenol, 4-chlorophenol, and pentachlorophenol, achieving 100% degradation of a 100-ppm phenol solution in 90 min, more than 98% degradation of a 20-ppm 4-chlorophenol solution in 90 min, and 97% degradation of a 10-ppm pentachlorophenol in 180 min with 500 ppm loading of the catalyst in all cases. Moreover, synthesized nanoparticles showed no sign of deactivation after 5 consecutive runs, removing 4-chlorophenol, showing their reusability. / Graduate

Visible light photocatalysis

photocatalysis

doped TiO2

N-doped TiO2

nitrogen-doped TiO2

pentachlorophenol

wastewater treatment

visible light wastewater treatment

photocatalytic wastewater treatment

Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas

Acauan, Luiz Henrique

January 2015

Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property.

Nanotubos de carbono

Nanoparticulas

Óxido de titânio

Fotocatálise

Carbon nanotubes

Nitrogen doped carbon nanotubes

Plasma-treated carbon nanotubes

TiO2

ALD

3D carbon structures

Photocatalyst

Supercapacitance

Field emission

Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas

Acauan, Luiz Henrique

January 2015

Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property.

Nanotubos de carbono

Nanoparticulas

Óxido de titânio

Fotocatálise

Carbon nanotubes

Nitrogen doped carbon nanotubes

Plasma-treated carbon nanotubes

TiO2

ALD

3D carbon structures

Photocatalyst

Supercapacitance

Field emission

An interfacial engineering approach towards two-dimensional porous carbon hybrids for high performance energy storage and conversion

Lu, Chenbao, Liu, Shaohua, Zhang, Fan, Su, Yuezeng, Zou, Xiaoxin, Shi, Zhan, Li, Guodong, Zhuang, Xiaodong

17 July 2017

In order to improve the performance and fundamental understanding of conducting polymers, development of new nanotechnologies for engineering aggregated states and morphologies is one of the central focuses for conducting polymers. In this work, we demonstrated an interfacial engineering method for the rational synthesis of a two-dimensional (2D) polyaniline (PANI) nano-array and its corresponding nitrogen-doped porous carbon nanosheets. Not only was it easy to produce a sandwich-like 2D morphology, but also the thickness, anchored ions and produced various metal phosphides were easily and rationally engineered by controlling the composition of the aqueous layer. The novel structural features of these hybrids enabled outstanding electrochemical capacitor performance. The specific capacitance of the as-produced diiron phosphide embedded nitrogen-doped porous carbon nanosheets was calculated to be as high as 1098 F g−1 at 1 A g−1 and an extremely high specific capacitance of 611 F g−1 at 10 A g−1, outperforming state-of-the-art performance among porous carbon and metal-phosphide-based supercapacitors. We believe that this interfacial approach can be extended to the controllable synthesis of various 2D material coupled sandwich-like hybrid materials with potential applications in a wide range of areas.

Leitende Polymere

neue Nanotechnologien

kontrollierbare Synthese

conducting polymers

new nanotechnologies

controllable synthesis

ddc:540

rvk:VA 1120

Sulfur Based Electrode Materials For Secondary Batteries

Hao, Yong

25 May 2016

Developing next generation secondary batteries has attracted much attention in recent years due to the increasing demand of high energy and high power density energy storage for portable electronics, electric vehicles and renewable sources of energy. This dissertation investigates sulfur based advanced electrode materials in Lithium/Sodium batteries. The electrochemical performances of the electrode materials have been enhanced due to their unique nano structures as well as the formation of novel composites. First, a nitrogen-doped graphene nanosheets/sulfur (NGNSs/S) composite was synthesized via a facile chemical reaction deposition. In this composite, NGNSs were employed as a conductive host to entrap S/polysulfides in the cathode part. The NGNSs/S composite delivered an initial discharge capacity of 856.7 mAh g-1 and a reversible capacity of 319.3 mAh g-1 at 0.1C with good recoverable rate capability. Second, NGNS/S nanocomposites, synthesized using chemical reaction-deposition method and low temperature heat treatment, were further studied as active cathode materials for room temperature Na-S batteries. Both high loading composite with 86% gamma-S8 and low loading composite with 25% gamma-S8 have been electrochemically evaluated and compared with both NGNS and S control electrodes. It was found that low loading NGNS/S composite exhibited better electrochemical performance with specific capacity of 110 and 48 mAh g-1 at 0.1C at the 1st and 300th cycle, respectively. The Coulombic efficiency of 100% was obtained at the 300th cycle. Third, high purity rock-salt (RS), zinc-blende (ZB) and wurtzite (WZ) MnS nanocrystals with different morphologies were successfully synthesized via a facile solvothermal method. RS-, ZB- and WZ-MnS electrodes showed the capacities of 232.5 mAh g-1, 287.9 mAh g-1 and 79.8 mAh g-1 at the 600th cycle, respectively. ZB-MnS displayed the best performance in terms of specific capacity and cyclability. Interestingly, MnS electrodes exhibited an unusual phenomenon of capacity increase upon cycling which was ascribed to the decreased cell resistance and enhanced interfacial charge storage. In summary, this dissertation provides investigation of sulfur based electrode materials with sulfur/N-doped graphene composites and MnS nanocrystals. Their electrochemical performances have been evaluated and discussed. The understanding of their reaction mechanisms and electrochemical enhancement could make progress on development of secondary batteries.

Sulfur

Polysulfides

Nitrogen-doped graphene

Manganese sulfide

Lithium-sulfur batteries

Room-temperature sodium-sulfur batteries

Cathode

Anode

Nanocomposites

Other Materials Science and Engineering

Structural, Electronic And Vibrational Properties Of n-layer Graphene With And Without Doping : A Theoretical Study

Saha, Srijan Kumar

04 1900

Graphene – a two-dimensional honeycomb lattice of sp2-bonded carbon atoms – has been attracting a great deal of research interest since its first experimental realization in 2004, due to its various novel properties and its potential for applications in futuristic nanodevices. Being the fundamental building block for carbon allotropes of other dimensionality, it can be stacked to form 3d graphite or rolled into 1d nanotube. Graphene is the thinnest known material in the universe, and one of the strongest materials ever measured in terms of its in-plane Young modulus and elastic stiffness. The charge carriers in graphene exhibit giant mobility as high as 20 m2/Vs, have almost zero effective mass, and can travel for micrometers without scattering even at ambient conditions. Graphene can sustain current densities six orders of magnitude higher than that of copper, shows record thermal conductivity and stiffness, is impermeable to gases, and renders easy accessibility to optical probes. Electron transport in graphene is described by a Dirac-type equation, which allows the investigation of “relativistic” quantum phenomena in a benchtop experiment. This results in the observation of a number of very peculiar electronic properties from an anomalous quantum Hall effect to Kien paradox and the absence of localization. All these enticing features make this material an excellent candidate for application in various electronic, photonic and optoelectronic devices. For instance, its ballistic ambipolar transport and high carrier mobility are the most useful traits for making ultrafast and low-power electronic devices. Its high surface area shouldmake it handy in manufacturing tough composite materials. The extreme thinness of graphene could also lead to more efficient field emitters that release electrons in the presence of strong electric fields. Its robustness and light weight are useful for micromechnical resonators. The tunability of its properties could make it possible to build so-called spin-valve transistors, as well as ultra-sensitive chemical detectors. Many of such applications of graphene require tuning of its properties, which can be achieved by varying the number of layers or/and by doping. There are several ways to dope graphene: (i)electrochemically gated doping, (ii)molecular charge-transfer doping, and (iii) substitutional doping by atoms like Boron or Nitrogen.Moreover, for graphene, a zero band gap semiconductor in its pristine form, to become a versatile electronic device material it is mandatory to find means to open up a band gap and tune the size of the band gap. Several strategies have been adopted to engineer such a band gap in graphene in a controlled way. Some of these are based on the ability to control the geometry of graphene layers, some use graphene-substrate interactions, while others are based on chemical reactions of atoms or molecules with the graphene layer. Motivated by these considerations, in this thesis we present a systematic and thorough study of the structural, electronic and vibrational properties of graphene and their dependence on the number of layers, and on doping achieved electrochemically, molecularly and substitutionally, using first principles density functional theory (DFT). In Chapter 1, we give an introduction to the hitherto beguiling world of graphene. Here, we briefly discuss the structure, novel properties and potential applications of graphene, and the motivation for this thesis. In Chapter 2, an overview of the DFT formalism adopted here is given. We clearly state the theorems of the formalism and the approximations used when performing calculations. We succinctly explain how the various quantities like total energies, forces, stresses etcetera are calculated within this formalism. We also discuss how phonon frequencies, eigenvectors, electron-phonon couplings are obtained by using density functional perturbation theory (DFPT), which calculates the full dynamical matrices through the linear response of electrons to static perturbations induced by ionic displacements. Calculations are done first using a fully ab-initio approach within the standard Born-Oppenheimer approximation, and then time-dependent perturbation theory is used to explore the effects of dynamic response. In Chapter 3, using such first-principles density-functional theory calculations, we determine the vibrational properties of ultra-thin n(1,2,...,7)-layer graphene films and present a detailed analysis of their zone-center phonons. We present the results (including structural relaxations, phonons, mode symmetries, optical activities) for bulk Graphite, single-layer graphene and ultrathin n-layer graphene films. and discuss the underlying physics of our main results together with a pictorial representation of the phonon modes. We demonstrate that a low-frequency (∼ 112 cm−1 ) optical phonon with out-of-plane displacements exhibits a particularly large sensitivity to the number of layers, although no discernible change in the interlayer spacing is found as n varies. Frequency shifts of the optical phonons in bilayer graphene are also calculated as a function of its interlayer separation and interpreted in terms of the inter-planar interaction. The surface vibrational properties of n-layer graphene films are presented in Chapter 4, which renders a detailed and thorough analysis of all the surface phonon modes by determining, classifying and identifying them accurately. The response of surface modes to the presence of adsorbed hydrogen molecules is determined. As an illustrative adsorbate, hydrogen is chosen here mainly because of its huge importance in fuel cell technology and as a molecular sensor. We demonstrate that a doubly degenerate surface phonon mode with low-frequency (~ 35cm−1)exhibits a particularly large sensitivity to the adsorption of hydrogen molecules, as compared to other surface modes. Futhermore, we show that a low-frequency (108.8 cm−1)bulk-like phonon with out-of-plane displacements is also very sensitive and gets upshifted by as much as 21 cm−1 due to this adsorption. In Chapter 5, we determine the adiabatic frequency shift of the and phonons in a monolayer graphene as a function of both electron and hole doping. The doping is simulated here to correspond to electrochemically gated graphene. Compared to the results for the E2g -Γ phonon (Raman G band), the results for the phonon are dramatically different, while those for the phonon are not so different. Furthermore, we calculate the frequency shifts, as a function of the charge doping, of the (K + ΔK) phonons responsible for the Raman 2D band –a key finger print of graphene, where [ΔK] is determined by the double resonance Raman process. Doping graphene with electron donating or accepting molecules is an interesting approach to introduce carriers into it, analogous to electrochemical doping accomplished in graphene when used in a field-effect transistor. In Chapter 6, we use first-principles density-functional theory to determine changes in the electronic structure and vibrational properties of graphene that arise from the adsorption of aromatic molecules such as aniline and nitrobenzene. Identifying the roles of various mechanisms of chemical interaction between graphene and the adsorbed molecules, we bring out the contrast between electrochemical and molecular doping of graphene. Our estimates of various contributions to shifts in the Raman active modes of graphene with molecular doping are fundamental to the possible use of Raman spectroscopy in (a)characterization of the nature and concentration of carriers in graphene arising from molecular doping, and (b) graphene-based chemical sensors. Graphene doped electrochemically or through charge-transfer with electron-donor and acceptor molecules, shows marked changes in electronic structure, with characteristic signatures in the Raman spectra. Substitutional doping, universally used in tuning properties of semiconductors, could also be a powerful tool to control the electronic properties of graphene. In Chapter 7, we present the structure and properties of boron and nitrogen doped graphenes, again using first-principles density functional theory. We demonstrate systematic changes in the carrier-concentration and electronic structure of graphenes with B/N-doping, accompanied by a stiffening of the G-band and change of the defect related D-band in the Raman spectra. Such n/p -type graphenes obtained without external fields or chemical agents should find device applications.

Graphene - Technology

Carbon - Nanotechnology

Density Functional Theory

Graphene - Vibrational Properties

Graphene - Doping

n-Layer Graphene

Graphene - Electronic Structure

Graphene - Phonons

Boron/Nitrogen Doped Graphene

Nanotechnology

Nitrogen-enriched, ordered mesoporous carbons for potential electrochemical energy storage

Zhu, Jinhui, Yang, Jun, Miao, Rongrong, Zhaoquan, Zhaoquan, Zhuang, Xiaodong, Feng, Xinliang

17 July 2017

Nitrogen-doped (N-doped) porous carbons have drawn increasing attention due to their high activity for electrochemical catalysis, and high capacity for lithium-ion (Li-ion) batteries and supercapacitors. So far, the controlled synthesis of N-enriched ordered mesoporous carbons (N-OMCs) for Li-ion batteries is rarely reported due to the lack of a reliable nitrogen-doping protocol that maintains the ordered mesoporous structure. In order to realize this, in this work, ordered mesoporous carbons with controllable N contents were successfully prepared by using melamine, F127 and phenolic resin as the N-source, template and carbon-source respectively via a solvent-free ball-milling method. The as-prepared N-OMCs which showed a high N content up to 31.7 wt% were used as anodes for Li-ion batteries. Remarkably, the N-OMCs with an N content of 24.4 wt% exhibit the highest reversible capacity (506 mA h g−1) even after 300 cycles at 300 mA g−1 and a capacity retention of 103.3%. N-OMCs were also used as electrode materials in supercapacitors and a capacity of 150 F g−1 at 0.2 A g−1 with stable cycling up to 2500 times at 1 A g−1 was achieved. These attractive results encourage the design and synthesis of high heteroatom content ordered porous carbons for applications in the field of energy storage and conversion.

info:eu-repo/classification/ddc/540

ddc:540

Catalizadores metálicos subnanométricos altamente eficientes en reacciones de formación de enlaces C-C

Escobar Bedia, Francisco Javier

02 September 2021

[ES] De forma general, el trabajo realizado durante la presente tesis doctoral se ha enfocado al diseño y optimización de catalizadores heterogéneos basados en Pd y Ru soportado sobre óxidos metálicos y materiales carbonosos. A fin de optimizar los catalizadores se han relacionado los ensayos catalíticos con las propiedades físico-químicas de los materiales mediante diferentes técnicas (XPS, HAADF-STEM, Fotoluminiscencia, IR, ¿) siguiendo un proceso iterativo de ensayo-caracterización-optimización. En concreto, la presente tesis doctoral se puede dividir en dos partes en función de las reacciones estudiadas: 1. Durante la primera parte, capítulo 3, se han preparado catalizadores basados en Au, Pd y Pd(OH)2 soportado sobre diferentes óxidos metálicos con objeto de realizar el homoacoplamiento oxidativo de benzoato de metilo en ausencia de disolvente y empleando oxígeno como único agente oxidante. Se ha conseguido identificar la especie activa como clústeres de Pd mediante el empleo de espectroscopia de infrarrojo de adsorción de CO y fotoluminiscencia. Con este conocimiento se ha podido diseñar un pre-tratamiento de activación específico para maximizar la actividad catalítica con el cual se ha logrado obtener un rendimiento catalítico similar al del catalizador homogéneo de Pd(OAc)2. 2. En la segunda parte de la tesis, se ha estudiado la hidroformilación de 1-hexeno empleando catalizadores alternativos basados en Ru. En particular, durante el capítulo 4 se han desarrollado catalizadores de Ru soportados sobre una matriz orgánica-inorgánica compuesta por un biopolímero natural, quitosán, y SiO2 detectándose un efecto sinérgico entre las especies lixiviadas de Ru (TON > 3000, TOF > 550 h-1) y los grupos funcionales del quitosán que ha sido estudiado mediante espectroscopia de absorción de rayos-X. Finalmente, el objetivo del capítulo 5 ha sido estabilizar las especies de Ru mediante un tratamiento térmico de pirólisis. Empleando un biopolímero natural se ha conseguido diseñar un catalizador estable, capaz de hidroformilar selectivamente el enlace terminal de olefinas de diferente tamaño de cadena con alta regioselectividad (S > 90%) que puede ser re-usado. Gracias al uso de técnicas espectroscópicas avanzadas se ha podido relacionar la actividad intrínseca de las especies de Ru soportadas identificándose a los átomos aislados de Ru como los más activos (TOF > 12.000 h-1). / [CA] This doctoral thesis has focused on the design and optimization of heterogeneous Pd and Ru catalysts supported on metallic oxides and carbon materials. In order to optimize the catalysts a relationship has been stablished between the observed reaction kinetics and the physico-chemical properties of the materials by means of different characterization techniques (XPS, HAADF-STEM, photoluminescence, IR ¿) following an iterative kinetic test-characterization-optimization process. In particular, this thesis can be divided in two different parts depending on the reaction studied: 1. In chapter 3, different catalysts based on Au, Pd and Pd(OH)2 supported on a variety of mixed oxides have been prepared with the aim of performing the oxidative homocoupling of methyl benzoate in absence of solvent with molecular oxygen as the only oxidising agent. In this case, Pd clusters have been identified as the active species by means of photoluminescence and infrared spectroscopy using CO as probe molecule. After identifying the active species, a specific activation pre-treatment could be designed in order to maximize the catalytic activity which is on par with the homogeneous Pd(OAc)2 counterpart. 2. In the next chapter (Chapter 4), the hydroformylation of 1-hexene using alternative Ru based catalysts was studied. In particular, a series of hybrid organic-inorganic Ru catalysts composed of a natural biopolymer, chitosan, and SiO2 were developed which showed and interesting synergistic effect between the lixiviated species of Ru and the functional groups of chitosan. This effect was studied by X-ray absorption spectroscopy. The catalyst showed a high activity (TON > 3000 and TOF > 550 h-1) as well as a high regioselectivity towards formation of lineal aldehyde (S > 95%). 3. Finally, the objective of chapter 5 was to go one step further trying to stabilize the Ru species observed in previous chapter by means of a pyrolytic thermal treatment. Thus, with the aid of a natural biopolymer and a carbonaceous support the goal of designing a reusable and stable catalyst, able to selectively catalyse the hydroformylation of terminal olefins with variable chain length and high regioselectivity (S > 90%) towards the lineal aldehyde was successfully achieved. In this case, the intrinsic activity of the different Ru supported entities was studied by advanced spectroscopy techniques allowing the identification of isolated single Ru atoms as the most active catalytic centers (TOF > 12000 h-1) / [EN] En general, el treball realitzat durant la present tesi doctoral s'ha centrat en l'optimització de catalitzadors heterogenis basats en Pd i Ru suportat sobre òxids metàl·lics i materials carbonacis. Amb l'objectiu d'optimitzar els catalitzadors, s'ha establert una relació entre els resultats dels experiments catalítics i les propietats fisicoquímiques dels materials mitjançant la utilització de diferents tècniques (XPS, HAADF - STEM, fotoluminescència, IR,...) seguint un esquema iteratiu d'assaig - caracterització - optimització. En concret, la present tesi doctoral es pot dividir en dos parts, en funció de les reaccions estudiades: 1. En la primera part, capítol 3, s'han preparat catalitzadors basats en Au, Pd i Pd(OH)2 suportat sobre diferents òxids metàl·lics amb l'objectiu de realitzar la reacció d'homoacoblament oxidatiu del benzoat de metil en absència de dissolvent i utilitzant oxigen com a únic agent oxidant. S'ha aconseguit identificar els clústers de Pd com a espècies actives de la reacció gràcies a l'espectroscòpia d'infraroig d'adsorció de CO i a la fotoluminescència. D'aquesta forma, s'ha pogut dissenyar un pretractament d'activació específic per aconseguir maximitzar l'activitat catalítica. S'han aconseguit obtenir uns valors de rendiment catalític similars al presentats pel catalitzador homogeni Pd(OAc)2. 2. En la segona part de la tesi, s'ha estudiat la hidroformilació de l'1-hexè utilitzant catalitzadors alternatius basats en Ru. En concret, en el capítol 4, s'han desenvolupat catalitzadors de Ru suportats sobre una matriu orgànica - inorgànica constituïda per un biopolímer natural, quitosan, i SiO2. Així doncs, s'ha pogut detectar un efecte sinèrgic entre les espècies lixiviades de Ru (TON > 3000 and TOF > 550 h-1) i els grups funcionals del quitosan. Dit efecte s'ha estudiat per mitjà de l'espectroscòpia d'absorció de rajos X. Finalment, l'objectiu del capítol 5 ha consistit en estabilitzar les espècies de Ru per mitjà d'un tractament tèrmic de piròlisis. Utilitzant un biopolímer natural, s'ha aconseguit dissenyar un catalitzador estable, capaç d'hidroformilar selectivament i amb una elevada regioselectivitat (S> 90%) l'enllaç terminal d'olefines de diferent longitud; i poder ésser posteriorment reutilitzat. A partir de tècniques d'espectroscòpia avançades, s'ha pogut relacionar l'activitat intrínseca de les espècies de Ru suportades, i s'han identificat els àtoms aïllats de Ru com aquelles espècies més actives (TOF > 12.000 h-1). / Escobar Bedia, FJ. (2021). Catalizadores metálicos subnanométricos altamente eficientes en reacciones de formación de enlaces C-C [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/172628 / TESIS

Biopolymers

Hydroformylation

Isolated atoms

Catalysis

Heterogeneous catalysis

Oxidative homocoupling

Metallic clusters

Biopolímeros

Hidroformilación

Átomos aislados

Catálisis

Catálisis heterogénea

Homoacoplamiento oxidativo

Clústeres metálicos

Nitrogen-doped carbon materials

An interfacial engineering approach towards two-dimensional porous carbon hybrids for high performance energy storage and conversion

Lu, Chenbao, Liu, Shaohua, Zhang, Fan, Su, Yuezeng, Zou, Xiaoxin, Shi, Zhan, Li, Guodong, Zhuang, Xiaodong

17 July 2017

In order to improve the performance and fundamental understanding of conducting polymers, development of new nanotechnologies for engineering aggregated states and morphologies is one of the central focuses for conducting polymers. In this work, we demonstrated an interfacial engineering method for the rational synthesis of a two-dimensional (2D) polyaniline (PANI) nano-array and its corresponding nitrogen-doped porous carbon nanosheets. Not only was it easy to produce a sandwich-like 2D morphology, but also the thickness, anchored ions and produced various metal phosphides were easily and rationally engineered by controlling the composition of the aqueous layer. The novel structural features of these hybrids enabled outstanding electrochemical capacitor performance. The specific capacitance of the as-produced diiron phosphide embedded nitrogen-doped porous carbon nanosheets was calculated to be as high as 1098 F g−1 at 1 A g−1 and an extremely high specific capacitance of 611 F g−1 at 10 A g−1, outperforming state-of-the-art performance among porous carbon and metal-phosphide-based supercapacitors. We believe that this interfacial approach can be extended to the controllable synthesis of various 2D material coupled sandwich-like hybrid materials with potential applications in a wide range of areas.

info:eu-repo/classification/ddc/540

ddc:540