skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Pre-Ionization Controlled Laser Plasma Formation for Ignition Applications (Final Scientific/Technical Report)

Technical Report ·
DOI:https://doi.org/10.2172/1581303· OSTI ID:1581303
 [1];  [2];  [1]; ORCiD logo [3]; ORCiD logo [1];  [1]
  1. Colorado State Univ., Fort Collins, CO (United States)
  2. Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)
  3. Cummins Inc., Columbus, IN (United States)
+ Show Author Affiliations

This report consists of three grand funded papers. Abstracts for each follow. 1) In this work, we present experimental and modeling studies of air pre-ionization using ultraviolet (UV) laser pulses and its effect on laser breakdown of an overlapped near-infrared (NIR) pulse. Experimental studies are conducted with a 266 nm beam (fourth harmonic of Nd:YAG) for UV pre-ionization and an overlapped 1064 nm NIR beam (fundamental of Nd:YAG), both having pulse duration of 10 ns. Results show that the UV beam produces a pre-ionized volume which assists in breakdown of the NIR beam, leading to reduction in NIR breakdown threshold by factor of >2. Numerical modeling is performed to examine the ionization and breakdown of both beams. The modeled breakdown threshold of the NIR, including assist by pre-ionization, is in reasonable agreement with the experimental results. 2) The present contribution compares the energy absorption, optical emission, temperature, and fluid dynamics of ultraviolet (UV) λ = 266 nm and near infrared (NIR) λ = 1064 nm nanosecond laser induced plasmas in ambient air. For UV pulses at the conditions studied, energy absorption by the plasmas increases relatively gradually with laser pulse energy starting at delivered energy of E~8 mJ. Corresponding measurements of plasma luminosity show that the absorption of UV radiation does not necessarily result in visible plasma emission. For the NIR induced plasmas, the energy absorption profile is far more abrupt and begins at ~55 mJ. In contrast with UV, the absorption of NIR radiation is always accompanied by intense optical emission. The temperatures of both types of plasma have been measured with Rayleigh scattering thermometry (at times after the Thomson signal sufficiently diminishes). The UV plasmas can attain a wider range of temperatures, including lower temperatures, depending on the pulse energy (e.g., T ~400–2000K for E ~7–35 mJ at Δt = 10 μs after the pulse) while the NIR plasmas show only hotter temperatures (e.g., T ~ 12 000 K for E = 75 mJ at Δt = 10 μs after the pulse) as is consistent with the literature. Differences in the fluid dynamics for UV versus NIR pulses are shown with Schlieren imaging. In this work, the contrast in the UV and NIR plasma threshold behavior is attributed to differing roles of avalanche ionization and multiphoton ionization as is also illustrated by a simple numerical model. 3) The present contribution examines the impact of plasma dynamics and plasma-driven fluid dynamics on the flame growth of laser ignited mixtures and shows that a new dual-pulse scheme can be used to control the kernel formation process in ways that extend the lean ignition limit. We perform a comparative study between (conventional) single-pulse laser ignition (λ = 1064 nm) and a novel dual-pulse method based on combining an ultraviolet (UV) pre-ionization pulse (λ = 266 nm) with an overlapped near-infrared (NIR) energy addition pulse (λ = 1064 nm). We employ OH* chemiluminescence to visualize the evolution of the early flame kernel. For single-pulse laser ignition at lean conditions, the flame kernel separates through third lobe detachment, corresponding to high strain rates that extinguish the flame. In this work, we investigate the capabilities of the dual-pulse to control the plasma-driven fluid dynamics by adjusting the axial offset of the two focal points. In particular, we find there exists a beam waist offset whereby the resulting vorticity suppresses formation of the third lobe, consequently reducing flame stretch. With this approach, we demonstrate that the dual-pulse method enables reduced flame speeds (at early times), an extended lean limit, increased combustion efficiency, and decreased laser energy requirements.

Research Organization:
Colorado State Univ., Fort Collins, CO (United States)
Sponsoring Organization:
National Science Foundation (NSF); USDOE Office of Science (SC); NSF/DOE Partnership in Basic Plasma Science and Engineering
DOE Contract Number:
SC0012454; PHY-1418845; CHE-1461040
OSTI ID:
1581303
Report Number(s):
DOE-CSU-12454; TRN: US2102451
Country of Publication:
United States
Language:
English

Similar Records

Control of Early Flame Kernel Growth by Multi-Wavelength Laser Pulses for Enhanced Ignition
Journal Article · Thu Aug 31 00:00:00 EDT 2017 · Scientific Reports · OSTI ID:1581303
+1 more
Threshold characteristics of ultraviolet and near infrared nanosecond laser induced plasmas
Journal Article · Thu Sep 01 00:00:00 EDT 2016 · Physics of Plasmas · OSTI ID:1581303
Collinear dual-pulse laser optical breakdown and energy deposition
Journal Article · Thu Mar 12 00:00:00 EDT 2020 · Journal of Physics. D, Applied Physics · OSTI ID:1581303
+2 more

Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
42 ENGINEERING
Shock waves
Plasma production
Ultraviolet lasers
Numerical methods
Ultraviolet light
Photoionization
Partial differential equations
Energy efficiency
Plasma diagnostics
Optical devices
Fluid dynamics
Temperature metrology
Light scattering
Optical imaging
Laser-induced plasma
Lenses
Thomson scattering
Applied optics
Mechanical engineering