Development and Characterization of a Low-flow, Low-power Inductively Coupled Plasma (ICP) |
Contents
A Brief History of ICP Development | 8 |
ICPAES as an Ideal Technique | 12 |
Comparison of ICPAES with Other Techniques | 18 |
15 other sections not shown
Common terms and phrases
15 20 DISTANCE Acta aerosol injection tube aerosol tube Anal annular spacing Appl applied rf power atomic spectroscopy calcium ion 393.3 calcium signal Chem concentration conventional ICP conventional-sized coolant flow rate coolant gas desolvation detection limits DISTANCE ABOVE LOAD droplet electron number density elements excitation temperature flame flared portion G. M. Hieftje Galan Horlick hydrazine ICP torch ICP-AES Inductively Coupled Plasma ionization L/min LOAD COIL LOAD COIL mm low-flow low-power ICP magnitude matrix interferences mini-torch nigrosin observation height operating conditions outer flow rate P. W. J. M. Boumans parameters phosphate phosphate on calcium plasma and coolant Plasma stability curves plasma torch plasma tube portion of plasma R. M. Barnes R. N. Kniseley R. N. Savage RELATIVE INTENSITY 100 Rezaaiyaan sample-introduction system shown in Figure Signal-to-background ratio sodium solutions spatial emission profiles spatial profiles Spectrochim Spectrometry Spectrosc Spectroscopy spray chamber stability curves illustrating Trassy V. A. Fassel XRFS