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Colliding Laser Produced Plasma Physics and Applications in Inertial Fusion and Nanolithography

<div>Laser-produced plasmas (LPP) have been used in a wide range of applications such as in pulsed laser deposition (PLD), extreme ultraviolet lithography (EUVL), laser-induced breakdown spectroscopy (LIBS), and many more. In the collision of two laser-produced plasmas, the two counter-streaming plasmas may face a degree of stagnation which influences the subsequent development of the compound plasma plume. The plume development of the stagnation layer can deviate quite noticeably from typical laser-plasma behavior. For instance, an enhanced degree of collisionality is expected, especially when the plasma collision transpires in a low pressure ambient. Colliding plasma can be intentionally implemented or conversely may occur naturally. In EUV lithography colliding plasma could service as an efficient EUV source with inherent debris mitigation. Conversely, colliding plasma could manifest in an inertial fusion energy (IFE) chamber leading to contamination, disrupting successful device operation.</div><div><br></div><div>Various techniques such as optical emission spectroscopy (OES), CCD plume imaging, laser-induced fluorescence (LIF), laser-induced incandescence (LII), and scanning electron microscopy (SEM) may be used to study laser-produced plasmas and their associated byproducts. These techniques will be used extensively throughout this work to aid in developing an understanding of the various physical and chemical phenomena occurring in these plasmas.</div><div><br></div><div><div>Chapter 1 provides introductory knowledge regarding LPPs with a specific exploration into colliding plasma and its relevance to a broad body of scientific knowledge. Additionally, the principles behind the various experimental techniques are capitulated.</div><div><br></div><div>Chapter 2 presents the laboratory facilities available at our Center for Materials Under eXtreme Environment (CMUXE) which can be used to study LPP. The various equipment (chambers, lasers, spectrograph, etc.) are discussed in detail.</div><div><br></div><div>Chapter 3 begins the series of substantive chapters which comprise the original research of this thesis. Here, the early formation (< 1 μs) of colliding carbon plasmas produced from the ablation of graphite is explored. The influence of plume hydrodynamics on the temporary lateral confinement of the stagnation layer is discussed with attention to the three different laser intensities studied. Additionally, species in the plasma were identified using OES and monochromatic plume imaging. A large increase in Swan emission from C2 dimers is observed in the stagnation layer, suggesting formation of C2 and/or re-excitation of C2 produced ab initio during laser ablation. Results were compared with HEIGHTS computational modeling to verify observations and to validate the code package for a new plasma regime.</div><div><br></div><div>Chapter 4 functions as a continuation from Chapter 3, looking into the intermediate time (1-10 μs) dynamics of colliding carbon plasma. To observe transient molecular species of carbon, C2 and C3, LIF was employed. By acquiring plume images through LIF, the various mechanisms by which C2 and C3 appear at different times in the plasma lifetime may be discerned. Using optical time-of-flight (OTOF), more information of carbon species populations may be determined to construct space-time contours which offer corroborative information regarding the spatiotemporal development of the stagnation layer.</div></div><div><br></div><div><div>Chapter 5 presents work on colliding Sn plasma for application as a EUV light source. The accumulation of material along the stagnation layer makes colliding plasmas a suitable preplasma in a dual pulse laser scheme. Dual-pulse EUV concepts call for the formation of a preplasma from the stagnation of two Sn plasmas. This preformed plasma is then subject to a second, pumping laser purposed to optimize the conversion efficiency (CE) of laser energy into EUV output. Characterization of the stagnation layer was obtained through optical emission spectroscopy while CE data is obtained using an absolutely calibrated EUV photodiode. HEIGHTS computational modeling then provides prediction of EUV emission upon using a CO2 laser for preplasma reheat.</div><div><br></div><div>Chapter 6 explores the collision between two dissimilar plasmas. Laser-produced plasma of Si and C are created in a manner which enables the two plasmas to collide. The ensuing development of the colliding plasma regime is then discussed in terms of relevant plume hydrodynamics. Analysis of the colliding regime is accomplished using fast-gated plume imaging and optical time-of-flight.</div><div><br></div><div>The final chapter, Chapter 7, provides a concise summary of the results presented in the preceding chapters. Additionally, recommended research directives are presented which are designed with consideration for the current facilities and capabilities at CMUXE.</div></div>

  1. 10.25394/pgs.7423853.v1
Identiferoai:union.ndltd.org:purdue.edu/oai:figshare.com:article/7423853
Date17 January 2019
CreatorsJohn P. Oliver (5930102)
Source SetsPurdue University
Detected LanguageEnglish
TypeText, Thesis
RightsCC BY 4.0
Relationhttps://figshare.com/articles/Colliding_Laser_Produced_Plasma_Physics_and_Applications_in_Inertial_Fusion_and_Nanolithography/7423853

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