COMPREHENSIVE THEORETICAL COMPARATIVE STUDY ON CUBIC AND MONOCLINIC LATTICE OF WO3 USING DFT AS IMPLEMENTED IN QUANTUM ESPRESSO | Blazingprojects Postgraduate Thesis
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COMPREHENSIVE THEORETICAL COMPARATIVE STUDY ON CUBIC AND MONOCLINIC LATTICE OF WO3 USING DFT AS IMPLEMENTED IN QUANTUM ESPRESSO

 

Table Of Contents


  • Title page   —       –       –       –       –       –       –       –       –       –       – i     Declaration —       –       –       –       –       –       –       –       –       –       -iiApproval page —   –       –       –       –       –       –       –       –       –       -iiiDedication —         –       –       –       –       –       –       –       –       –       -ivAcknowledgement —       –       –       –       –       –       –       –       –       -v     Table of content   —         –       –       –       –       –       –       –       –       -vi                 Abstract —   –       –       –       –       –       –       –       –       –       –       -vii

Thesis Abstract

Abstract
In this study, a comprehensive theoretical comparative analysis of the cubic and monoclinic lattice structures of tungsten trioxide (WO3) was conducted using Density Functional Theory (DFT) as implemented in the Quantum ESPRESSO software package. Tungsten trioxide is a versatile material with applications in gas sensing, electrochromic devices, and energy storage systems. The cubic and monoclinic phases are two common polymorphs of WO3 with distinct structural and electronic properties. The structural optimization was carried out for both cubic and monoclinic WO3 using the Perdew-Burke-Ernzerhof (PBE) exchange-correlation functional within the framework of DFT. The lattice parameters, formation energy, and electronic band structure were calculated to investigate the stability and electronic properties of the two phases. The results revealed that the monoclinic phase of WO3 is more energetically favorable compared to the cubic phase, consistent with experimental observations. Furthermore, the electronic band structures of the cubic and monoclinic WO3 phases were analyzed to understand their electronic properties, such as band gap and band dispersion. The calculated band structures showed that both phases are indirect bandgap semiconductors with different bandgap values. The monoclinic phase exhibited a wider bandgap compared to the cubic phase, indicating variations in the electronic behavior of the two polymorphs. Moreover, the density of states (DOS) analysis was performed to investigate the distribution of electronic states in the cubic and monoclinic WO3 structures. The DOS plots provided insights into the electronic structure and bonding characteristics of the two phases. Variations in the peak positions and intensities of the DOS curves were observed between the cubic and monoclinic phases, highlighting the differences in their electronic properties. Overall, this study presents a detailed theoretical comparative analysis of the cubic and monoclinic lattice structures of WO3 using DFT calculations implemented in Quantum ESPRESSO. The results offer valuable insights into the structural stability and electronic properties of these two phases, which are essential for understanding the behavior of tungsten trioxide in various technological applications.

Thesis Overview

<p> </p><p>Tungsten (vi) oxide, also known as tungsten trioxide or tungsten analysis, W03 is a chemical compound containing oxygen and transition metal tungsten it is obtained as an intermediate in the recovery of tungsten from its minerals. Tungsten is treated with alkali to produce W03 further reaction with carbon or hydrogen gas reduces tungsten trioxide to the pure metal. Tungsten trioxide has a rich history dating back to its discovery during the 18th century. Peter woulfe was the first to recognize a new element in the naturally occurring mineral wolframite. Tungsten was originally known as wolfram, explaining the choice of “W” for its elemental symbol. Sweetish chemist Carl Wilhelm Scheele contributed to its discovery with his studies on the mineral scheelite.</p><p>In 1841, a chemist named Robert Oxland gave the first procedures for preparing tungsten trioxide and sodium tungstate. He was grated patent for his work soon after and is considered to be the founder of systematic tungsten chemistry. </p><p>In 1781, Carl Wilhelm Scheele discovered that a new acid, tungsten acid could be made from scheelite (at the time named tungsten). Scheele and Torbern Bergman suggested that it might be possible to obtain a new metal by reducing this acid. In 1783, Jose and FaustoElhuyar found an acid made from Wolframite that was identical to tungstic acid later that year, at the Royal Beryara, Spain, and the brothers succeeded in isolating tungsten by reduction of this acid with charcoal and they are credited with the discovery of the element.</p><p>In World War II, tungsten played a significant role in background political dealings. Portugal as the main European source of the element was put under pressure from both sides because of its deposits of Wolframite ore at parasqueira. Tungsten desirable properties such as resistance to high temperatures, its hardness and density and its strengthening of alloys made it an important raw material for the arms industry both as a constituent of weapons and requirement ad employed in production itself e.g. in tungsten carbide cutting tools for machining steel. The name tungsten (from the Swedish tungsten “heavy stone”) is used in English, French and many other languages as the name of the element, but not in the Nordic Countries.</p><p>Tungsten was the old sweetish names for the mineral scheelite “Wolfram” (or “Volfram”) is used in most European (Especially Germanic and Slavic) languages and is derived from the mineral Wolframite which is the origin of the chemical symbol W. The name “Wolf rahm” (“Wolf Soot” or “Wolf Cream”) the name given to tungsten by Johan Gottschalk Wallerius in 1747. This in turn, derives “LupiSpuma”, the name Georg Agricota used for the element in 1546, which translates into English as “Wolf’s Froth” and is a reference to the large amount to tin consumed by the mineral during its extraction.</p><p>Tungsten trioxide is used for many purposes in everyday life. It is frequently. Used in industry to manufacture tungstate for x-ray screen Phosphors for fireproofing fabrics and in gas sensors Due to its rich yellow color is also used as a pigment in ceramics and paints. In recent years, tungsten trioxide has been employed in the production of electro-chromic windows or smart windows. These windows are electrically switchable glass that changes high transmission properties with an applied voltage. This allows the user to tint their windows changing the amount of heat or light passing through.</p><p>2010 ASIT report a quantum yield of 19% in photo catalytic water spitting with a cesium enhanced tungsten oxide photo catalyst.</p><p>In 2013, highly photo catalyst active titanic tungsten (vi) oxide/noble metal (Au and pt) composites toward oxalic acid were obtained by the means of selective noble metal photo deposition on the desired oxides surface either on (TiO2 or WO3) the composite showed a modest hydrogen production performance.</p><p>In 2016, shape controlled tungsten trioxide semi-conductors were obtained by the means of hydrothermal synthesis form these semi-conductors composite systems were prepared with commercial T102. This composite system showed a higher photo catalysis activity than the commercial T102 (Evonit Aeroxide P25) toward phenol and methyl orange degradation.</p><p>1.2 PROBLEM STATEMENT</p><p>Although the stable phase of pure WO3 at 17 330 <em>â—¦</em>C is monoclinic with the P21/n space group, any change in temperature may induce structural distortions and thereby cussing a phase transfer. Indeed, tungsten trioxide has an orthorhombic lattice at 330 740 <em>â—¦</em>C and a tetragonal structure above 740 <em>â—¦ </em>C. in addition, it can be crystallized in a ReO3 cubic system without a central atom. It is obvious that the electronic structure of WO3 is affected by its crystal symmetry. In order to investigate this issue, a more comprehensive comparative study of tungsten trioxide in its Bravais lattices both within theory and experiment is needed</p><p>1.3 &nbsp; AIM OF STUDY</p><p>The main aim of this work is to carry out a comprehensive theoretical comparative study on cubic and monoclinic lattice of WO3 using DFT as implemented in Quantum ESPRESSO </p><p>1.4 &nbsp; OBJECTIVES</p><p>1. &nbsp; To analyze the structural properties of cubic and monoclinic tungsten trioxide.</p><p>2. &nbsp; To Study the electronic properties (Density of State (DOS)) of both cubic and monoclinic tungsten trioxide.</p><p>3. &nbsp; To investigates its possible applications</p><p>1.5 SCOPE AND LIMITATIONS</p><p>During the course of this study we shall analyze the structural properties and also study the electronic properties of cubic and monoclinic tungsten trioxide using density functional theory.</p> <br><p></p>

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