Exfoliation and Utilization of at By : Anton and Diana.

Slides:

Advertisements

Similar presentations

Experimental Investigation and Mathematical Modeling of Cold-Cap Behavior in HLW Melter D. Pierce, J. Chun, P. Hrma, J. Rice, R. Pokorny, M. Schweiger.

Advertisements

NE Introduction to Nuclear Science Spring 2012

Pressure-Induced Hydrogen-dominant metallic state in Aluminum Hydride HAGIHARA Toshiya Shimizu-group Igor Goncharenko et al., Phy. Rev. Lett. 100,

IwIw InIn 0,55 0,24 0,44 In/IwIn/Iw ESR Study of NR/Montmorillonite Nanocomposites M. Didović 1, D. Klepac 1 S. Valić 1,2 A.P. Meera 3 and S. Thomas 3.

Thermal Energy. 1.Thermal Energy is the vibration or movement of atoms and molecules. 2.All matter has thermal energy because the atoms are always moving.

Catalysis and Catalysts - XPS X-Ray Electron Spectroscopy (XPS)  Applications: –catalyst composition –chemical nature of active phase –dispersion of active.

RAMAN SPECTROSCOPY Scattering mechanisms

Lecture 6. FT-IR and Raman Spectroscopy. FT-IR Analytical infrared studies are based on the absorption or reflection of the electromagnetic radiation.

Energy in Thermal Processes

Magneto-optical study of InP/InGaAs/InP quantum well B. Karmakar, A.P. Shah, M.R. Gokhale and B.M. Arora Tata Institute of Fundamental Research Mumbai,

Optics on Graphene. Gate-Variable Optical Transitions in Graphene Feng Wang, Yuanbo Zhang, Chuanshan Tian, Caglar Girit, Alex Zettl, Michael Crommie,

Introduction to Infrared Spectroscopy

THERMAL CONDUCTION LABORATORY Dr. E. Marotta Department of Mechanical Engineering Clemson University Clemson, SC.

STRUCTURAL CHANGES STUDIES OF a-Si:H FILMS DEPOSITED BY PECVD UNDER DIFFERENT HYDROGEN DILUTIONS USING VARIOUS EXPERIMENTAL TECHNIQUES Veronika Vavruňková.

X-Ray Diffraction Spectroscopy RAMAN Microwave. What is X-Ray Diffraction?

Kevin Cai, AMSA Charter School Matthew Greenlaw, Pioneer Charter School of Science Dr. Birol Ozturk, Northeastern University Professor Swastik Kar, Physics,

Wittaya Julklang, Boris Golman School of Chemical Engineering Suranaree University of Technology STUDY OF HEAT AND MASS TRANSFER DURING FALLING RATE PERIOD.

What is Energy  Energy is the ability to cause change. Change in ANYTHING  There are two general types of energy Kinetic energy Potential energy.

very strong , and Modif. Epoxies Polycarbo= nates Alkyd-, Polyesters, Cellulose= ether, PVC (plasticized) Polyvinyl=

KHS ChemistryUnit 3.4 Structural Analysis1 Structural Analysis 2 Adv Higher Unit 3 Topic 4 Gordon Watson Chemistry Department, Kelso High School.

Zn x Cd 1-x S thin films were characterized to obtain high quality films deposited by RF magnetron sputtering system. This is the first time report of.

Investigation of fluid- fluid phase transition of hydrogen under high pressure and high temperature 2014/11/26 Shimizu laboratory SHO Kawaguchi.

Synthesis of Solar Cell Materials, and Fabrication of Novel Polymer- Based Solar cells Yan Jin Prof. Vikram K. Kuppa.

Chapter 1 An Introduction to Organic Reactions Nabila Al- Jaber

Increased surface area on nanoparticles

JUN YAN UNIVERSITY OF MASSACHUSETTS AMHERST 2015 SUMMER INSTITUE ON NANOSCIENCE.

INTRODUCTION Characteristics of Thermal Radiation Thermal Radiation Spectrum Two Points of View Two Distinctive Modes of Radiation Physical Mechanism of.

1 Investigation of Optical Properties n, k … index of refraction and damping  1,  2 … polarization and absorption Problems: The penetration depth of.

Techniques of synthesizing mono-layer Molybdenum Sulfide (MoS 2 ) Wu Kam Lam.

Energy Changes.

Trimester 2 Science vocabulary and concepts: Heat & Energy.

The study of liquid-solid and glass transitions in finely divided aqueous systems Anatoli Bogdan Institute of Physical Chemistry, University of Innsbruck.

Desorption mechanism of hydrogen isotope from metal oxides Contents 1.Background 2.Experimental system and Mechanism 3.Results and discussion 4.Conclusions.

Nitrogen-Doped Carbon

1 EFFECTS OF MOLECULAR ORIENTATION AND ANNEALING ON OPTICAL ABSORBTION OF ORIENTED PET POLYMER By Montaser Daraghmeh.

指導教授：王聖璋博士 (Pro.S-C Wang) 學生 : 黃伯嘉 (Bo-Jia Huang) 2015/11/22 Temperature effects on the growth of SnS nanosheet structure using thermal decomposition.

Synthesis of diamond-like carbon films with super-low friction and wear properties A. Erdemir, O.L. Eryilmaz, and G. Fenske J. Vac. Sci. Technol. A 18(4),

Electronic state calculation for hydrogenated graphene with atomic vacancy Electronic state calculation of hydrogenated graphene and hydrogenated graphene.

Matter: Properties and Change. What is Matter? Matter is anything that takes up space and/or has mass. Matter is made up of atoms and molecules.

Raman Enhancement Effect on Two-dimensional Layered Materials: Graphene, h-BN, and MoS 2 Mildred Dresselhaus, Massachusetts Institute of Technology, DMR.

NANO 225 Intro to Nano/Microfabrication

STEF-NANO-ACC Stimulating, Encouraging and Facilitating the Participation of ACC Nanotechnology and Nanoscience Research Organisations To FP6 Topic:

Introduction to Waves. The location of energy sources may be different than where they are needed. The energy must be transferred from one location to.

日期：指導老師：林克默博士學生：陳冠廷. Outline 1.Introduction 2.Experimental 3. Results and discussion 4. Conclusions.

Energy “The energy of the mind is the essence of life” Aristotle. “If you want to find the secrets of the universe, think in terms of energy, frequency.

Properties of materials. The behaviour of a given material is characterised by the response to a stimulus. Mechanical properties (behaviour under a set.

Weather and Climate Unit Investigative Science. * All materials are made of particles (atoms and molecules), which are constantly moving in random directions.

Thermal Properties of Materials

Material Processing of Polystyrene Boron Nitride Nanocomposites Raed Ayoob Supervisor(s): Thomas Andritsch and Alun Vaughan 16 September 2015 Early Career.

The coating thermal noise R&D for the 3rd generation: a multitechnique investigation E. Cesarini 1,2), M.Prato 3), M. Lorenzini 2) 1)Università di Urbino.

Conduction, Convection, Radiation Chapter 6, Lesson 2.

Date of download: 5/31/2016 Copyright © ASME. All rights reserved. From: Influence of Interfacial Mixing on Thermal Boundary Conductance Across a Chromium/Silicon.

Raman spectroscopy.

First steps towards the PhD thesis

Fabrication of Hybrid Solar Cells using ZnS Nanoparticles

Materials Classification and Properties Metals, Ceramics, and Semiconductors NANO 52 Foothill College.

Chemical Vapor Transport (CVT)

Rama Gaur and P. Jeevanandam*

APTES-BNNs / Epoxy Composites

Boron Removal from Metallurgical-Grade Silicon Using CaO-SiO2 Slag

High Performance Computing on Condensed Matter Physics

Mass Transfer In Chemical Engineering

5. EXPERIMENT Material: Instrument Experiment condition:

5.4 Learning from Light Our goals for learning

The different forms of energy Notes-feb. 7

21.1 Properties of Ocean Water

Direct Tooth colored restorative materials

Graphenea Graphene Oxide (GO)

Evaluating the Scalability of the Sonication Method of Graphene oxide Synthesis Evan Dexter.

Presentation transcript:

Exfoliation and Utilization of at By : Anton and Diana

Table of Contents IntroductionBackground Methods Sonication Factors Result Measurement Techniques Thermal Management Research and Future WorkSummary Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 2

3 Introduction

-As, 3D chip architecture increases in complexity there is increase in heat flux -Current polymer encapsulation does not have sufficient K eff Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 4

Introduction Hexagonal boron nitride (h-BN) : Analog to graphene Large band gap of ~ 5.5eV High theoretical thermal conductivity Difficult to exfoliate Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 5

Introduction Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 6 Exfoliation Specifically Focused On Liquid Phase Sonication

7 Background

8 - Methods -

Methods Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 9 Mechanical Cleavage Ball Milling Chemical Functionalization Liquid Phase Sonication

Methods Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 10 Mechanical Cleavage Ball Milling Chemical Functionalization Liquid Phase Sonication

11 Background - Sonication Factors -

Factors SolventsSonication settingsSize of Solutes Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 12

Factors SolventsSonication settingsSize of Solutes Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 13

Factors - Solvents Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 14 Effective Solvent Low enthalpy of system Low energy for sonication Matching surface energy InexpensiveEco friendly No foreign materials produced

Water as solvent -H-BN normally hydrophobic in water -Boron- nitrogen bonds near defect sites make exfoliation easier -Boron edges formed hydroxyl groups under hydrolysis Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 15

Solvent Promoting Chemical Functionalization -Polymer—poly (sodium 4-styrenesulfonate) (PSS) used as a dispersant and functionalization agent -Improved the separation of layers from h-BN structure Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 16 Exfoliation and Utilization of h-BN

Isopropyl Alcohol(IPA) solution as solvent -IPA has matching surface energy to h-BN( mJ/m^2) -Ammonia water also has matching surface energy of ~ 57 mJ/m^2 -Create solution of IPA: ammonia solution of ~3:2 -Boron atoms temporarily act like lewis acids and are susceptible to attack from amines Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 17

Factors SolventsSonication settingsSize of Solutes Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 18

Sonication Settings Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 19 Uses sound wave with a preset wavelength to agitate particles in a solution

Factors SolventsSonication settingsSize of Solutes Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 20

Size of Solutes Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 21 Sonication Sound Wavelength Sizes of pristine h-BN → Higher Exfoliation yield can be achieved Exfoliation and Utilization of h-BN

22 Background - Result Measurement -

Result Management Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 23 Infrared Thermal Imaging Optical Absorption Raman Spectroscopy X-ray diffraction

Infrared Thermal Imaging -Model developed by Georgia Institute of Technology is commonly used -Measures the thermal Resistance & Thermal Conductivity of the sample Exfoliation and Utilization of h-BN Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 24

Optical Absorption Band Gap: the bulk h-BN < an isolated h-BNNS Exfoliation ↑ the absorptivity of the dispersion Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 25 Exfoliation and Utilization of h-BN

Raman Spectroscopy Helps identify the number of layers of h- BN Mono-layers: slightly upward Bi-layers: downward in peak position Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 26 Exfoliation and Utilization of h-BN

X-ray Diffraction (XRD) Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 27 Exfoliation and Utilization of h-BN

28 Background - Thermal Management -

Thermal Management -Ceramics only use the vibration of phonons to transfer heat -Issue with using ceramic fillers is you need high filler loading (>50 wt%) -H-BN nanosheets provide a way to increase thermal conductivity substantially Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 29 Exfoliation and Utilization of h-BN

Thermal Management Thermal Enhancement factor(TEF) of a h-BN/ epoxy composite was observed using: (k composite - k epoxy )/ k epoxy * 100%, k refers to the thermal conductivity Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 30 Exfoliation and Utilization of h-BN

Thermal Management -With increase in filler loading, viscosity increases making it more difficult to process -Coefficient of thermal expansion decreases and glass transition temperature slightly decreases Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 31 Exfoliation and Utilization of h-BN

Thermal Management -Theoretical calculations show thermal conductivity should increase as amount of layers decreases -But the experimental data showed this was not the case -Thickness of sheets proved to be more important as when the sheets are thinner they are less thermally conductive Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 32 Exfoliation and Utilization of h-BN

33 Research and Future Work

Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 34 Exfoliation and Utilization of h-BN

Research and Future Work Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 35 Exfoliation and Utilization of h-BN

Research and Future Work Multifunctional Materials | Micro-and-Nanostructuring Laboratory Slide 36 Exfoliation and Utilization of h-BN

37 Summary

Questions/Comments? 38 Exfoliation and Utilization of h-BN