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Atomic Emission Spectroscopy: Lab01:29

Atomic Emission Spectroscopy: Lab

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AES is a powerful analytical technique, especially effective when used with plasma sources, producing abundant spectra in characteristic emission lines. The Inductively Coupled Plasma (ICP), in particular, yields superior quantitative analytical data due to its high stability, low noise, low background, and minimal interferences under optimal experimental conditions. However, newer air-operated microwave sources are emerging as promising alternatives that could be more cost-effective than...
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Flame Photometry: Overview01:02

Flame Photometry: Overview

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Flame photometry, also known as flame emission spectrometry, is a technique used for the qualitative and quantitative analysis of elements present in a sample using a flame as the source of excitation energy. The concept of flame photometry was realized in the early 1860s by Kirchhoff and Bunsen, who discovered that specific elements emit characteristic radiation when excited in flames. The first instrument developed for this purpose was used to measure sodium (Na) in plant ash using a Bunsen...
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Inductively Coupled Plasma–Mass Spectrometry (ICP–MS): Overview01:19

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

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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...
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Atomic Emission Spectroscopy: Interference01:30

Atomic Emission Spectroscopy: Interference

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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,...
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Inductively Coupled Plasma Atomic Emission Spectroscopy: Principle01:19

Inductively Coupled Plasma Atomic Emission Spectroscopy: Principle

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Inductively coupled plasma (ICP) is the most widely used plasma source in atomic emission spectroscopy (AES), also known as Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES). The ICP source, or torch, consists of three concentric quartz tubes with argon gas flowing through them. A spark from a Tesla coil initiates the ionization of argon, generating a high-temperature plasma.
The ions and electrons produced interact with the fluctuating magnetic field created by a water-cooled...
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Flame Photometry: Lab01:16

Flame Photometry: Lab

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In a flame photometer, when a solution like potassium chloride is aspirated into the flame, the solvent evaporates, leaving behind dehydrated salt. This salt dissociates into free gaseous atoms in their ground state. Some of these atoms absorb energy from the flame, leading to their excitation. The excited atoms return to the ground state, emitting photons at characteristic wavelengths. Because only electronic transitions are involved, the resulting emission lines are very narrow. The intensity...
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Controlling a new plasma regime.

Philosophical transactions. Series A, Mathematical, physical, and engineering sciencesยท2024
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Related Experiment Video

Updated: Jun 15, 2025

Emission Spectroscopic Boundary Layer Investigation during Ablative Material Testing in Plasmatron
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Emission Spectroscopic Boundary Layer Investigation during Ablative Material Testing in Plasmatron

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Plasma burn-mind the gap.

Hendrik Meyer1

  • 1UKAEA, Culham Campus, Abingdon , Oxon OX14 3DB, UK.

Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences
|August 26, 2024
PubMed
Summary
This summary is machine-generated.

Designing plasma scenarios for the Spherical Tokamak for Energy Production (STEP) focuses on manageable exhaust using double null configurations and high core performance with positive triangularity. Microwaves will provide external current drive for this fusion energy concept.

Keywords:
burning plasmaedge localized modesplasma scenario integrationreactorspherical tokamakturbulence

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Last Updated: Jun 15, 2025

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Area of Science:

  • Nuclear Fusion Engineering
  • Plasma Physics
  • Advanced Reactor Design

Background:

  • The Spherical Tokamak for Energy Production (STEP) program aims to design a fusion reactor for net electricity generation.
  • Current spherical tokamaks (STs) have a significant performance gap compared to future burning plasma concepts.
  • Conservative assumptions are made about plasma performance to bridge this gap.

Purpose of the Study:

  • To outline plasma scenario designs for the STEP fusion energy project.
  • To identify key physics and technical challenges for achieving net electricity production.
  • To propose strategies for managing plasma exhaust, core transport, and disruptions.

Main Methods:

  • Assessment of plasma configurations, including double null (DN) and positive triangularity (PT).
  • Evaluation of external heating and current drive (CD) systems, favoring microwave-based CD.
  • Analysis of operational requirements like resistive wall mode (RWM) stabilization and high elongation.

Main Results:

  • Double null configurations are favored for manageable plasma exhaust.
  • Positive triangularity plasmas with elevated central safety factors enhance core performance.
  • Microwaves are identified as the most effective external current drive method.
  • Active RWM stabilization and high elongation are crucial for compact STEP designs.

Conclusions:

  • Significant challenges remain in core transport due to high normalized plasma pressure, requiring dedicated experiments and advanced models.
  • Edge localized modes (ELMs) must be controlled or mitigated to ensure material integrity.
  • Novel techniques are needed to manage high runaway electron currents during disruptions for power plant viability.