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Inductively Coupled Plasma-Mass Spectrometry (ICP-MS): Interferences01:20

Inductively Coupled Plasma-Mass Spectrometry (ICP-MS): Interferences

Inductively coupled plasma–mass spectrometry (ICP–MS) is a highly selective and sensitive technique for accurate elemental analysis. Though the analysis of ICP–MS mass spectra is comparatively straightforward, it is affected by spectroscopic and non-spectroscopic interferences. Spectroscopic interferences arise when the plasma contains ionic species with an m/z value the same as the analyte ion. Spectroscopic interference can be categorized as isobaric, polyatomic ions, and refractory oxide ion...
Insensitive Nuclei Enhanced by Polarization Transfer (INEPT)01:15

Insensitive Nuclei Enhanced by Polarization Transfer (INEPT)

Insensitive Nuclei Enhanced by Polarization Transfer (INEPT) is an advanced Nuclear Magnetic Resonance (NMR) technique specifically designed to detect and enhance the signals of low-abundance nuclei, such as carbon-13 and nitrogen-15, in small molecules. The fundamental principle behind INEPT is the transfer of polarization from a more abundant and highly polarizable nucleus, typically hydrogen-1, to the low-abundance nucleus of interest. This process effectively boosts the NMR signal of the...
Inductively Coupled Plasma–Mass Spectrometry (ICP–MS): Overview01:19

Inductively Coupled Plasma–Mass Spectrometry (ICP–MS): Overview

In inductively coupled plasma–mass spectrometry (ICP–MS), an inductively coupled plasma (ICP) torch is used as an atomizer and ionizer. Solid samples are dissolved and volatilized before being introduced into the high-temperature argon plasma, while solution samples are nebulized and passed through the high-temperature argon plasma. Plasma dissociates the analytes and ionizes their component atoms to form a mixture of positive ions and molecular species. The positive ions are then passed on to...
Atomic Emission Spectroscopy: Interference01:30

Atomic Emission Spectroscopy: Interference

In atomic emission spectroscopy (AES), high-temperature atomizers excite a broad range of elements and molecules that generate complex emissions from sources such as oxides, hydroxides, and flame combustion products in the flame or plasma. Several strategies can be employed to minimize spectral interferences caused by overlapping emission lines or bands. These include increasing instrument resolution, choosing alternative emission lines, optimally placing the detector in low-background regions,...
Mass Analyzers: Common Types01:19

Mass Analyzers: Common Types

The quadrupole mass analyzer consists of four cylindrical metal rods arranged in a diamond carrying a DC voltage and a radio-frequency AC voltage. The motion of ions through the quadrupole depends on the field strength, causing only ions of a certain m/z to resonate successfully and strike the detector at a given field strength. Though the transmission rate for these analyzers is high, the exact elemental composition of the sample is not determined because of low resolution; however, they are...
Atomic Absorption Spectroscopy: Interference01:25

Atomic Absorption Spectroscopy: Interference

Interference leads to systematic error in atomic absorption (AA) measurements by enhancing or diminishing the analytical signal or the background. These interferences can be grouped into three main categories: spectral interference, chemical interference, and physical interference.
Spectral interference occurs when signals from other elements or molecules overlap with the analyte signal, falsely elevating or masking the analyte's absorbance. This interference can be corrected using Zeeman,...

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Updated: Jul 6, 2026

Automated Delivery of Microfabricated Targets for Intense Laser Irradiation Experiments
06:40

Automated Delivery of Microfabricated Targets for Intense Laser Irradiation Experiments

Published on: January 28, 2021

Self-interference patterns and their application to inertial-fusion target characterization.

M D Wittman1, R S Craxton

  • 1Laboratory for Laser Energetics, University of Rochester, 250 East River Road, Rochester, New York 14623-1299, USA.

Applied Optics
|March 8, 2008
PubMed
Summary

A novel Self-Interference Pattern (SIP) technique precisely measures the wall thickness of inertial-fusion targets. This method achieves high accuracy, crucial for direct-drive inertial fusion energy applications.

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Area of Science:

  • Physics
  • Materials Science
  • Optical Metrology

Background:

  • Direct-drive inertial-fusion targets demand sub-micrometer sphericity and wall-thickness uniformity.
  • Achieving such precision is critical for successful fusion reactions.
  • Existing metrology methods face challenges in non-destructively assessing these parameters.

Purpose of the Study:

  • To introduce and validate a new optical technique for precise measurement of inertial-fusion target shell-wall thickness.
  • To demonstrate the capability of the Self-Interference Pattern (SIP) method for assessing target uniformity.
  • To provide a non-destructive, accurate, and potentially faster metrology solution.

Main Methods:

  • Irradiating target shells with spatially incoherent, narrow-bandwidth light.
  • Observing Self-Interference Patterns (SIPs) using a compound microscope.
  • Analyzing fringe patterns to determine wall thickness and uniformity.
  • Employing ray tracing for theoretical modeling of fringe formation.

Main Results:

  • Wall thickness determined to within +/-0.5 micrometers by counting SIP fringes.
  • Thickness uniformity verified to better than 0.05 micrometers.
  • Accurate thickness measurement achieved irrespective of gas fill or pressure.
  • SIP technique successfully selects polymer shells within specified diameter and thickness ranges.

Conclusions:

  • The SIP fringe technique offers a highly accurate and reliable method for metrology of inertial-fusion target shells.
  • This technique is independent of target fill gas and pressure, simplifying measurements.
  • SIP analysis provides critical data for quality control and selection of fusion targets.