1 / 47

Nanotechnology in Mechanical Engineering

UEET 101 Introduction to Engineering. Nanotechnology in Mechanical Engineering. Presented By Pradip Majumdar, Ph.D Professor Department of Mechanical Engineering Northern Illinois University DeKalb, IL 60115. Outline of the Presentation. Lecture In-class group activities and homework

yates
Download Presentation

Nanotechnology in Mechanical Engineering

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. UEET 101 Introduction to Engineering Nanotechnology in Mechanical Engineering Presented By Pradip Majumdar, Ph.D Professor Department of Mechanical Engineering Northern Illinois University DeKalb, IL 60115

  2. Outline of the Presentation Lecture In-class group activities and homework Video Clips

  3. Course Outline Lecture – II • Nano-Mechanics • Nanoscale Thermal and Flow Phenomena • Experimental Techniques • Modeling and Simulation Lecture - I • Basic concepts • Length and time scales • Nano-structured materials - Nanocomposites - Nanotubes and nanowire • Applications and Examples

  4. Lecture Topics Key issues of nano-technology in Mechanical Engineering. Topics to be addressed are basic concepts, length and time scales, nano-structured materials; nanoparticles and nanofluids, nanodevices and sensors, and applications.

  5. Major Topics in Mechanical Engineering • Design of machines and structures • Dynamics system, sensors and controls - Robotics • Computer-Aided Design (CAD/CAM) - Solid model and Analysis • Computational Fluid Dynamics (CFD) and Finite Element Method • Fabrication and • Manufacturing processes • Mechanics: Statics : Deals with forces, Moments, equilibrium of a stationary body Dynamics: Deals with body in motion - velocity, acceleration, torque, momentum, angular momentum. • Structure and properties of material (Including strengths) • Thermodynamics, power generation, alternate and regenerative energy (power plants, solar, wind, geothermal, engines, nuclear, fuel cells and battery storage)

  6. Length Scales in Sciences and Mechanics Quantum Mechanics: Deals with atoms - Molecular Mechanics: Molecular Networks - Nanomechanics: -deals with Nano-materials Micromechanics: Macro-mechanic: - Continuum substance

  7. Time Scale Electron – Photon relaxation time: 0.5 – 50 ps Material heating and melt with high energy laser : 1-10 ns

  8. Ultrafast Applications Ultrafast Lasers: (macro-micro second lasers: CW laser, ND-YAG, Diode ps/fs-lasers: Ti-Sapphire) Material processing - Laser ablation of material removal process Health Care - Eye-surgery - Correction of eye surface - Excimer Laser Ablation Only a thin skin (100-200nm) absorbs the laser energy and vaporizes

  9. Quantum and Molecular Mechanics • All substances are composed molecules or atoms in random motion. • A gas system consisting of a cube of 25-mm on each side contains atoms. • To describe the behavior of this system, we need to deal with at least equations. • A computational challenge - even with the most powerful computer available today. • There are two approaches to handle this situations: Microscopic or Macroscopic model

  10. Fundamental Limit • A structure of the size of an atom represents one of the fundamental limit. • Fabricating or making anything smaller require manipulation in atomic or molecular level • Changes one chemical form to other.

  11. Microscopic Vs Macroscopic Microscopic viewpoint -kinetic theory and statistical mechanics • On the basis of statistical considerations and probability theory, it deals with average values of all atoms or molecules in connection with a atomic model. Macroscopic view point - continuum assumption. • Consider gross or average behavior of a number of molecules • Deals with time averaged influence of many molecules. • These macroscopic or average effects can be perceived by our senses and measured by instruments. • This leads to our treatment of substance as an infinitely divisible substance known as continuum.

  12. Breakdown of Continuum Model Limit of continuum or macroscopic model Density is defined as the mass per unit volume and expressed as Where is the smallest volume for which substance can be assumed as continuum. • Volume smaller than this will leads to the fact that mass is not uniformly distributed, but rather concentrated in particles as molecules, atoms, electrons etc. • Density varies as volume decreases below the continuum limit.

  13. Macroscopic Properties and Measurement Pressure Pressure is defined as the average normal-component of force per unit area and expressed as Where is the smallest volume for which substance can be assumed as continuum. Pressure Measurement For a pressure gauge, it is the average force (rate of change of momentum) exerted by the randomly moving atoms or molecules over the sensor’s area. Unit: Pascal (Pa) or

  14. Introduction- Nanotechnology • Nanoscale uses “nanometer” as the basic unit of measurement and it represents a billionth of a meter or one billionth of a part. • Nanotechnology deals with nanosized particles and devices • One- nm is about 3 to 10 atoms wide. This is very tiny when compared with normal sizes encountered day-to-day. - For example, this is 1/1000th the width of human hair.

  15. Some Characteristics • Any physical substance or device with structural dimensions below 100 nm is called nanomaterial or nano-device. • Nanotechnology rests on the technology that involves fabrication of material, devices and systems through direct control of matter at nanometer length scale. • Departure from continuum assumption. • Exhibit unusual mechanical, optical, chemical and physical properties.

  16. Nanoparticles • Nanoparticles are the building blocks of nanomaterials and nanotechnology. • Nanoparticles include graphene, nanotubes, nanofibers, fullerenes, dendrimers, nanowires. • Nanoparticles are made of ceramics, metals, nonmetals, metal oxide, organic or inorganic.

  17. Behavior Different from Bulk or Continuum • At this small scale level, the physical, chemical and biological properties of materials differ significantly from the fundamental properties at bulk level. • Many forces or effects such as inter-molecular forces, surface tension, electromagnetic, electrostatic, capillary becomes significantly more dominant than gravity. • Nanomaterial can be physically and chemically manipulated to alter the properties that are measured using nanosensors and nanogages.

  18. Scientist and engineers have just started developing new techniques for making nanostructures. • The nanoscience has • matured. • The age of nanofabrication • is here. • The age of nanotechnology – • that is the practical use of • nanostructure has just started.

  19. Nanotechnology in Mechanical Engineering New Basic Concepts Nano-Scale Heat Transfer Nano-Mechanics Nano-fluidics Applications

  20. Applications • Structural materials • Nano devices and sensors • Coolants, heat spreaders and lubrication • Engine emission reduction • Fuel celland Battery storage – nanoporous electrode/membranes/nanocatalyst • Hydrogen storage medium • Sustainable energy generation - Photovoltaic cells for power conversion • Biological systems and biomedicine

  21. Basic Concepts Energy Carriers Phonon: Quantized lattice vibration energy with wave nature of propagation - dominant energy carrier in crystalline material Free Electrons: - dominant energy career in metals Photon: Quantized electromagnetic energy with wave nature of propagation - energy carrier of radiation energy of electromagnetic waves

  22. Length Scales Two regimes: I. Classical microscale size-effect domain – Useful for microscale phenomena in micron-size environment. Where mean free path length of the substance characteristic device dimension II. Quantum nanoscale size-effect domain – More relevant to nanoscale phenomena Where characteristic wave length of the electrons or phonons

  23. Time Scales Relaxation time for different collision process: Relaxation time for phonon-electron interaction: Relaxation time for electron-electron interaction: Relaxation time for phonon-phonon interaction:

  24. Nanotechnology: Modeling Methods • Quantum Mechanics • Atomistic simulation • Molecular Mechanics/Dynamics Nanomechanics Nanoheat transfer and Nanofluidics

  25. Models for Inter-molecules Force - Inter-molecular Potential Model - Inverse Power Law Model or Point Centre of Repulsion Model - Hard Sphere Model - Maxwell Model - Lennard-Jones Potential Model Inter-molecular Potential Model

  26. Nanotools Nanotools are required for manipulation of matter at nanoscale or atomic level. Devices which manipulate matter at atomic or molecular level are Transmission electron microsope (TEM),Scanning-probe microscopes, atomic force microscopes, atomic layer deposition devices and nanolithography tools. Nanolithography creates nanoscale structure by etching or printing. Nanotools comprises of fabrication techniques, analysis and instruments and software. Softwares are utilized in nanolithography, 3-D printing, nanofluidics and chemical vapor deposition.

  27. Nanoparticles and Nanomaterials • Nanoparticles are significantly larger than individual atoms and molecules. • Nanoparticles are not completely governed by either quantum chemistry or by laws of classical physics. • Nanoparticles have high surface area per unit volume. • With reduced size, the number of atoms on the surface increases than that in the interior. • The surface structure dominates the properties.

  28. Carbon -Nanotubes • Carbon nanotubes are hollow cylinders made up of carbon atoms. • The diameter of carbon nanotube is few nanometers and they can be several millimeters in length. • Carbon nanotubes looks like rolled tubes of graphene and their walls are like hexagonal carbon rings and are formed in large bundles. • Have high surface area per unit volume • Carbon nanotubes are 100 times stronger than steel at one-sixth of the weight. • Carbon nanotubes have the ability to sustain high temperature ~ 2000 C.

  29. There are four types of carbon nanotube: Single Walled Carbon Nanotube (SWNT),Multi Walled carbon nanotube (MWMNT), Fullerene and Torus. SWNTs are made up of single cylindrical graphene layer MWNTs is made up of multiple grapheme layers. SWNT possess important electric properties which MWNT does not. SWNT are excellent conductors, so finds its application in miniaturizing electronics components.

  30. Nanocomposites • Formed by combining two or more nanomaterials to achieve better properties. • Gives the best properties of each individual nanomaterial. • Show increase in strength, modulus of elasticity and strain in failure. • Interfacial characteristics, shape, structure and properties of individual nanomaterials decide the properties. • Find use in high performance, lightweight, energy savings and environmental protection applications - buildings and structures, automobiles and aircrafts.

  31. Examples of nanocomposites include nanowires and metal matrix composites. • Classified into multilayered structures of inorganic or organic composites. • Multilayered structures are formed from self-assembly of • monolayers. • Nanocomposites may provide heterostructures formed from various inorganic or organic layers, leading to multifunctional materials.

  32. Nanostructured Materials • All the properties of nanostructured are controlled by changes in atomic structure, in length scales, in sizes and in alloying components. • Nanostructured materials are formed by controlling grain sizes and creating increased surface area per unit volume. • Decrease in grain size causes increase in volumetric fraction of grain boundaries, which leads to changes in fundamental properties of materials. Different behavior of atoms at surface has been observed than atom at interior. Structural and compositional differences between bulk material and nanomaterial cause change in properties.

  33. The size affected properties are color, thermal conductivity, mechanical, electrical, magnetic etc. • Nanostructure material show increase in hardness and modulus of elasticity than bulk metals. • Nanostructured materials are produced in the form of powders, thin films and in coatings. • Synthesis of nanostructured materials take place by Top – Down or Bottom- Up method. • - In Top-Down method the bulk solid is decomposed into • nanostructure. • - In Bottom-Up method atoms or molecules are • assembled into bulk solid. • The future of nanostructured materials deal with controlling characteristics, processing into and from bulk material and in new manufacturing technologies.

  34. Nanofluids Nanofluidsare engineered colloid formed with stable suspemsions of solid nano-particles in traditional base liquids. Base fluids: Water, organic fluids, Glycol, oil, lubricants and other fluids Nanoparticle materials: - Metal Oxides: - Stable metals: Au, cu - Carbon: carbon nanotubes (SWNTs, MWNTs), diamond, graphite, fullerene, Amorphous Carbon - Polymers : Teflon Nanoparticle size: 1-100 nm

  35. Nanofluid Heat Transfer Enhancement • Thermal conductivity enhancement - Reported breakthrough in substantially increase ( 20-30%) in thermal conductivity of fluid by adding very small amounts (3-4%) of suspended metallic or metallic oxides or nanotubes. • Increased convective cooling characteristic of coolant or heating fluid. -

  36. Nano-fluid Applications • Energy conversion and energy storage system • Electronics cooling techniques • Thermal management of fuel cell energy systems • Nuclear reactor coolants • Combustion engine coolants • Super conducting magnets • Biological systems and biomedicine

  37. Nano-Biotechnology When the tools and processes of nanotechnology are applied towards biosystems, it is called nanobiotechnology. Due to smaller length scale and unique properties, nanomaterials can find its application in biosystems. Nanocomposite materials play a great role in development of materials for biocompatible implant. Nano sensors and nanofluidcs have started playing an important role in diagnostic tests and drug delivering system for decease control. The long term aim of nano-biotechnology is to build tiny devices with biological tools incorporated into it for diagonistic and treatment.

  38. National Nanotechnology Initiative in Medicine Improved imaging (www.3DImaging.com) for detection Treatment of Disease Superior Implant Drug delivery system and treatment using Denrimers, Nanoshells and Nanofluidics.

  39. - In order to improve the durability and bio-compatibility, the implant surfaces are modified with nano-thin film coating (Carbon nano-particles). - An artificial knee joint or hip coated with nanoparticles bonds to the adjacent bones more tightly. Nano-particles delivers treatment totargeted area or targeted tumors - Release drugs or release radiationto heat up and destroy tumors or cancer cells

  40. Self Powered Nanodevices and Nanogenerators Nanosize devices or machined need nano-size power generator called nanogenerators without the need of a battery. Power requirements of nanodevices or nanosystems are generally very small – in the range of nanowatts to microwatts. Example: Power source for a biosensor - Such devices may allow us to develop implantable biosensors that can continuously monitor human’s blood sugar level

  41. Waste energy in the form of vibrations or even the human pulse could power tiny devices. Arrayof piezoelectrics could capture and transmit that waste energy to nanodevices Power sources in a human body: - mechanical energy, heat energy, vibration energy, chemical energy A small fraction of this energy can be converted into electricity to power nano-bio devices. Nanogenerators can also be used for other applications - Autonomous strain sensors for structures such as bridges - Environmental sensors for detecting toxins - Energy sensors for nano-robotics - A pacemaker’s battery could be charged without requiring any replacement

  42. Nano-sensor and Nano-generator

  43. Example: Piezoelectric Nanogenerator Piezoelectric Effect Some crystalline materials generates electrical voltage when mechanically stressed A Typical Vibration-based Piezoelectric Transducer - Uses a two-layered beam with one end fixed and other end mounted with a mass - Under the action of the gravity the beam is bent with upper-layer subjected to tension and lower-layer subjected to compression.

  44. Conversion of Mechanical Energy to Electricityin a Nanosystem Gravity do not play any role for motion in nanoscale. Nanowire is flexed by moving a ridged from side to side. Array of nanowires (Zinc Oxide) with piezoelectric and semiconductor properties Rectangular electrode with ridged underside. Moves side to side in response to external motion of the structure

  45. Example: Thermo Electric Nano-generator Thermoelectric generator relies on the Seebeck Effectwhere an electric potential exists at the junctions of two dissimilar metals that are at different temperatures. The potential difference or the voltage produced is proportional to the temperature difference. - Already used in Seiko Thermic Wrist Watch

  46. In-class group activitiesand Home Work Work in a group to discuss following Questions on Bio-Nano Generators 1.How much and what different kind of energy does body produce? 2. How this energy source can be utilized to produce power. 3. What are the technological challenges? Expand your answers and submit as a homework

  47. The link to the video. http://www.kqed.org/quest/television/view/189?gclid=CMPdjcX--JwCFQEhDQodcikgbQ

More Related