2D metal-organic layer covers gold substrate

Networks provide new surface functionality and could enable the formation of more complex structures
nanotechweb.org: all news

Full field nano imprint on mask aligners using substrate conformal imprint lithography technique

A white paper from SUSS MicroTek
nanotechweb.org: all news

Determination of trace thiocyanate with nano-silver coated multi-walled carbon nanotubes modified glassy carbon electrode

Product Description
This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.

Description:
Novel nano-silver coated multi-walled carbon nanotube composites were prepared and used to fabricate a modified electrode. The application of the nano-silver coated multi-walled carbon nanotube composites modified electrode for determination of trace thiocyanate is demonstrated for the first time. The influence of substrate, pH and interference of coexisting substances was investigated for response properties of the electrode. There was a linear relationship at the range 2.5×10^-^9 to 5×10^-^8molL^-^1 and 5×10^-^8 to 1×10^-^6molL^-^1 of thiocyanate with the decrement of anodic DPV peak currents. The limit of detection was 1×10^-^9molL^-^1(S/N=3). The constructed electrode showed excellent reproducibility and stability. Actual urine and saliva samples of smoker and non-smoker were analyzed and satisfactory results were obtained. This method provides a new way to construct any electrode for biological and environmental analysis.

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Light Scattering from Microstructures: Lectures of the Summer School of Laredo, University of Cantabria, Held at Laredo, Spain, Sept.11-13, 1998

Product Description
With a tutorial approach, this book covers the most important aspects of the scattering of electromagnetic radiation from structures (isolated or on a substrate) whose size is comparable to the incident wavelength. Special emphasis is placed on the electromagnetic problem of microstructures located close to an interface by reviewing the most important numerical methods for calculating the scattered field. The polarization propagation and the statistics of scattered intensity in microstructured targets are also presented from a didactic point of view. The final part of the book is dedicated to the most significant applications in both basic and applied research: surface enhanced Raman scattering, monitoring and detection of surface contamination by particles, optical communications, particle sizing and others.

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Microfluidic Technologies for Miniaturized Analysis Systems

Product Description

Microfluidic Technologies for Miniaturized Analysis Systems provides a comprehensive overview of the fluidic aspects of Lab-on-a-Chip technology. This book describes the most important and state-of-the-art microfluidic technologies and the underlying principles utilized in the implementation of fluidic protocols of miniaturized analysis systems. This book discusses many of the effects, outcomes, and techniques which are unique to microfluidic systems. The specific components of this technology toolbox are elucidated through research and examples presented by some of the most renowned experts in the field.

Microfluidic Technologies for Miniaturized Analysis Systems is an important reference for professionals and academic researchers seeking information about the latest techniques, including:

• Control and pumping of small amounts of liquid
• Particle and cell manipulation
• Micromixing
• Separation technology
• Bioanalytic methods

 

About the MEMS Reference Shelf:
The MEMS Reference Shelf is a series devoted to Micro-Electro-Mechanical Systems (MEMS), which combine mechanical, optical, or fluidic elements on a common microfabricated substrate to create sensors, actuators, and microsystems. This series strives to provide a framework where basic principles, known methodologies, and new applications are integrated in a coherent and consistent manner.
STEPHEN D. SENTURIA, MASSACHUSETTS INSTITUTE OF TECHNOLOGY,
PROFESSOR OF ELECTRICAL ENGINEERING, EMERITUS

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