Selective nanoparticle deposition

Slides:

Advertisements

Similar presentations

Day 3 Platforms Biological sensors Chemical sensors.

Advertisements

Thermal Inkjet Printing of Quantum Dot Inks for Overt and Covert Security Printing James Stasiak1, Tom Etheridge1, Steve Simske2, Tim Strecker1, and Garry.

Self-healing materials Multidisciplinary project group 2.

Using DEM-CFD method to model colloids aggregation and deposition

Fabrication and Testing of Thin-Film Igniter Bridge Contact: Dr. Azad Siahmakoun Director, MiNDS Facility Rose-Hulman Institute of Technology A Technology.

Revision for Mid year Examination

Simplified Example of a LOCOS Fabrication Process

Biomimetic Surfaces for Manipulation and Targeting Of Bacteria and / or Mammalian Cells (in Flow) Santore, Cell surface collector.

Development of an Electrochemical Micro Flow Reactor (EMFR) for electrocatalytic studies of methanol oxidation and fuel cell applications. Nallakkan Arvindan*,

Plasmon enhanced thin-film solar cells: Advanced theoretical analysis and ellipsometric characterization Supervisor: Jesper Jung Postdoc

John Pulsifer, Mark Tillack S. S. Harilal, Joel Hollingsworth GIMM experimental setup and tests at prototypical pulse length HAPL Project Meeting Princeton,

Nucleation of gold nanoparticles on graphene from Au 144 molecular precursors Andrei Venter 1, Mahdi Hesari 2, M. Shafiq Ahmed 1, Reg Bauld 1, Mark S.

Galen Biology and Experiment. Galen and Experimental Methodology Galen wanted to demonstrate the irreversibility of the flow of urine from the bladder.

4.3 Exchange of gases in the lungs. Learning outcomes Students should understand the following: The essential features of the alveolar epithelium as a.

Chapter 3: Sound Wave Intensity of Periodic Sound Waves

Solar Cells 3 generations of solar cells:

Strands of DNA have been used as tiny scaffolds to create superconducting nanodevices that demonstrate a new quantum interference phenomenon. These nanowire.

Patterning and Templating on Multi-Layer Films Eric Baer, Case Western Reserve University, DMR Researchers at CWRU are focused on harnessing the.

Computer Science and Engineering - University of Notre Dame Jimmy Neutron CSE 40827/60827 – Ubiquitous Computing November 13, 2009 Project Presentation.

Smart Fabrics. What is a Smart fabric? Smart materials or textiles can be defined as the materials and structures which have sense or can sense the environmental.

Realization of an All-Dielectric Zero-Index Optical Metamaterial P. Moitra, Y. Yang, Z.Anderson, I.I.Kravchenko, D.B.Briggs, J.Valentine, Nature Photonics,

Resistless Fabrication of Embedded Nanochannels by FIB Patterning, Wet Etching and Atomic Layer Deposition Zhongmei Han Marko Vehkamaki Markku Leskelä.

Nanogrooved silicon dioxide (SiO 2 ) was used to fabricate organic field-effect transistors (OFETs) with a mobility approaching 50 cm 2 V -1 s -1. We expect.

Atomic Layer Deposition (ALD) Conformality in Nanopores Rubloff Research Group Accomplishments.

Robin L. Garrell Department of Chemistry & Biochemistry University of California, Los Angeles Jared Hund Inertial Fusion Technology General Atomics, San.

Department of Chemistry Seminar Announcement Date/Time/VenueTitle/Speaker 14 Mar (Mon) 11am – S8 Level 3 Executive Classroom Structure and Dynamics.

Hollow Gold Nanoparticles Are Very Sensitive Sensors Mostafa A. El-Sayed, Georgia Tech Research Corporation, DMR Sensing of biological materials,

NIRT: Controlling Interfacial Activity of Nanoparticles: Robust Routes to Nanoparticle- based Capsules, Membranes, and Electronic Materials (CBET )

Ferroelectric Nanolithography Extended to Flexible Substrates Dawn A. Bonnell, University of Pennsylvania, DMR Recent advances in materials synthesis.

Biomimetic Applications of Mussel Adhesives

It is widely appreciated that the supramolecular ordering of polymers, surfactants and liquid crystals (LCs) can be impacted by confinement. In many cases,

CORPORATE INSTITUTE OF SCIENCE & TECHNOLOGY, BHOPAL DEPARTMENT OF ELECTRONICS & COMMUNICATIONS NMOS FABRICATION PROCESS - PROF. RAKESH K. JHA.

Despite tremendous progress made in the synthesis of surface-grafted polymer brushes, there have been few reports of polymer brushes in organic electronics.

Ion Beam Induced Exfoliation of Silicon Structures J.W. Mayer, T.L. Alford, Arizona State Univ.; S.S. Lau, UC-San Diego DMR Fig.1 A sketch of the.

Approaches to the fabrication of surfaces that combine methods for the topographic patterning of soft materials with opportunities for facile, post-fabrication.

Plasma Processes, Inc. February 5-6, Engineered Tungsten for IFE Dry Chamber Walls HAPL Program Meeting Georgia Institute of Technology Scott O’Dell,

University of Wisconsin MRSEC on Nanostructured Interfaces Juan J. De Pablo, DMR Gallium Nitride is a very promising material for interfacing microelectronics.

Biology – The Continuity of Life Objective 3 & 4 Objective 3 & 4 –Describe the various ways genetic engineering can change the organisms around us. –Demonstrate.

Buried Pipe Infrastructure Researchers: Gavin Sailor, Ali Hassan-Zahraree, Juanjuan Zhu, Michele Schirru, Mark Ke Ma Academics: Richard Collins, Robin.

National Science Foundation Outcome: Researchers at University of Maryland have created a 3D biological templated current collector with improved solar.

School of Electrical, Electronic and Mechanical Engineering Nano-particles and nano-structured surfaces in biomedical engineering. Dr. Kenneth Stanton.

VI-D-15(PP) Disassembly of the Small Engine Figure 1.

Computer Game-Based Virtual Environments for Homeland Security Applications Walt Scacchi, Craig Brown, and others Center for Computer Games and Virtual.

Research Vertically-aligned carbon nanofibers are a form of carbon with many potential applications in chemical/biological sensing and energy storage.

Figure Molecular Biology of the Cell (© Garland Science 2008)

Figure 14-1 Molecular Biology of the Cell (© Garland Science 2008)

High Q-factor Photonic Crystal Cavities on Transparent Polymers

A Facile Way to Fabricate Polyester Microcapsules

CDT in New and Sustainable PV Experimental Methods Module

Understanding the Diffusion of Polymers Confined Between Interfaces

Materials Innovation Lecture Series

Metal nanoparticle embedded floating gate memory based on MoS2 with polymer tunneling dielectric layer. Myung Hun Woo1, Byung Chul Jang1, Junhwan Choi2,

Dr. Thomas Pozegic Prof. S. R. P. Silva Dr. I. Hamerton

Date of download: 12/21/2017 Copyright © ASME. All rights reserved.

From: Wave Response of Closed Flexible Bags

Organic nanoparticles Inorganic nanoparticles

VLSI System Design LEC3.1 CMOS FABRICATION REVIEW

Robert Hatfield Material Science 3344 Spring 2006

Lesson Overview Roots and Stems.

(vary time, physiological state, disease, ...)

BY: MRS. POOLE ALPHABET OF LINES.

Andre Taylor and Jan Schroers, Yale University

Design of Biodegradable Surfactants to Control and Manipulate Physical Properties of Polymeric Nanoparticles Cristina M. Sabliov, Biological & Agricultural.

Metal Oxide Nanoparticles for High Energy Electrochemical Capacitors - PRF # DNI10 Gleb Yushin School of Materials Science and Engineering, Georgia.

Synchronized terahertz plasmons in ultra-thin membrane GaN HEMT arrays

Controlled Mechanical Buckling for Origami-Inspired 3D Microstructures

Materials Research Science and Engineering Centers DMR 2018

Presentation transcript:

Selective nanoparticle deposition Creating a “repair-and-go” system using nanoparticle microencapsulation Facile methods for detecting and repairing damaged regions of materials are critically important in numerous structural and functional materials, from airplane wings to fabrics to microelectronics to biological implant materials. Emrick, Crosby, and Russell, working in the Materials Research Science and Engineering Center (MRSEC) on Polymers at UMass Amherst, demonstrated that microcapsules can carry nanoparticles across a damaged substrate, sense the damaged regions, and deposit nanoparticles selectively into the damaged areas, leaving the rest of the surface unaffected. The work represents an experimental realization of a theoretical challenge described by Balazs (U Pittsburgh), termed “repair-and-go”. The success of “repair-and-go” hinges on microencapsulation with polymer surfactants, as the thin polymer capsule wall (the polymer structure of the capsules is shown in the figure) allows nanoparticles to pass out of the capsule and into the crack. Moreover, the polymer is anti-fouling, preventing irreversible absorption of the capsule on the substrate or in the damaged region. Selective nanoparticle deposition Polymer-stabilized microcapsule Nanoparticle release