Eureka - Innovative Engineering Design
 
   
Search :   Search Help    login
Design ShortlistDesign Shortlist
Design Software & PLMDesign Software & PLM
Bearings/Linear SystemsBearings/Linear Systems
Design Services/RPDDesign Services/RPD
Electrical/Electronic CompsElectrical/Electronic Comps
Fastening/JoiningFastening/Joining
Hydraulics/PneumaticsHydraulics/Pneumatics
MaterialsMaterials
Mechanical ComponentsMechanical Components
Motion Control/AutomationMotion Control/Automation
Power TransmissionPower Transmission
Sensors Test & MeasurementSensors Test & Measurement
Production EngineeringProduction Engineering
Electronics DesignElectronics Design
Computer SystemsComputer Systems
Plant & ManufacturingPlant & Manufacturing
NewsNews
Reference LibraryReference Library
BearingsBearings
Design / RPD servicesDesign / RPD services
Design Components / MaterialsDesign Components / Materials
Design SoftwareDesign Software
Electrical/Electronic CompsElectrical/Electronic Comps
Factory Equipment/SuppliesFactory Equipment/Supplies
Fastening / JoiningFastening / Joining
Hydraulics / PneumaticsHydraulics / Pneumatics
Industry SectorsIndustry Sectors
Industry IssuesIndustry Issues
Mechanical ComponentsMechanical Components
Motion Control / AutomationMotion Control / Automation
Power TransmissionPower Transmission
Technology SpotlightTechnology Spotlight
EventsEvents
JobsJobs
Rest & RelaxationRest & Relaxation
Advertiser ServicesAdvertiser Services
Direct Marketing servicesDirect Marketing services
How to AdvertiseHow to Advertise
Media PackMedia Pack
How ‘impossible’ data all adds up 29/04/2008
 
New techniques are enabling scientists to understand surfaces and extract data from engineering experiments under ‘impossible’ conditions

Scientists at the National Physical Laboratory (NPL) are using physics modelling to extract valuable information from experiments that cannot be undertaken in real-world conditions – and then applying advanced statistics to dig out meaningful data from the results.

NPL’s Joanna Lee is using a technique called Secondary Ion Mass Spectrometry (Sims), in conjunction with the modelling and statistical analysis, to analyse coatings and thin films. This could well prove important in fields as diverse as electronics and medicine.
Sims works by breaking molecules – such as those in a surface coating – into smaller fragments. The problem is then to make sense of it and work out which original molecules were on the surface before they were blasted to pieces.

NPL has developed a refined technique called G-Sims, which uses manganese or bismuth ions to cause different degrees of fragmentation.

More on this technology appears in the May issue of Eureka.
 
Author
Tom Shelley
 
Email this article
 
Bookmark this article using:
 
Del.icio.us digg reddit Facebook StumbleUpon
 
News Item
Linked Companies
 
 National Physical Laboratory
 
 
News Item
Similar News Articles
 
  UK production to be advanced by new Centre
 
  Pulsating detection work
 
  New method could help to determine nature of damage to materials
 
  Sensing fabric push button protects card data
 
  Spike soles customised for victory
 
 
News Item
Similar Reference Library Articles
 
  Helping dummies to understand encoders
 
  Pulsating detection work
 
  The five-minute body scan
 
  Taking up the strain
 
  Vision system keeps track of surgical instruments
 
Contact Us  |  About Us  |  Careers @ Eureka  |  Site Map  |  Terms & Conditions  |  © Findlay Publications Ltd 2008  |  Login  |  RSS News