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1. Thermal Development of an Impinging Jet Using Planar Laser Induced Fluorescence (PLIF)

   Wright, L.; Seitz, S. (June 2019, ASME Turbo Expo 2019: Turbomachinery Technical Conference and Exposition)

   Planar Laser Induced Fluorescence (PLIF) has been demonstrated to investigate a round jet impinging on a flat surface. Detailed thermal field distributions have been obtained near the flat target surface to characterize the wall jet development ensuing from the stagnation point. While PLIF has been demonstrated for combustion applications to measure concentration gradients within a mixture, its application for temperature field measurements is less established. Therefore, the technique was applied to a simple, cylindrical impinging jet. The jet Reynolds number varied with Rejet = 5,000 – 15,000 while the jet – to – target surface spacing varied from H / D = 4 – 10. The cooling jet (Tjet ~ 300 K) impinged on a flat, heated surface. The PLIF technique was able to capture the free jet structure and jet development along the target surface. With a short impingement length (H / D = 4), the potential core of the jet strikes the target surface. The thermal gradients captured during the experiments demonstrate the fully turbulent nature of the impinging jet with H / D = 10. The thermal boundary development along the target surface is clearly captured using this fluorescence method. The near wall temperature gradients acquired with the PLIF method have been used to calculate heat transfer coefficients on the heated surface, and these values compare favorably to those measured using a well-established steady state, heat transfer method. The PLIF technique has been demonstrated for this fundamental impingement setup, and it has proven to be applicable to more complex heat transfer and cooling applications. 

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2. PLIF Exploration of an Active Co-Axial Injector in Crossflow From a Rectangular CD Nozzle

   https://doi.org/10.2514/6.2025-3321  

   Solomon, John T; Lockyer, Rhys; Tubbs, Lauryn; Connel, Russell (July 2025, American Institute of Aeronautics and Astronautics)

   AIAA (Ed.)

   The mixing characteristics of an active coaxial injector in crossflow configurations are explored in this paper. A miniature rectangular CD nozzle generates crossflow for the injector for subsonic and supersonic test conditions. The flowfield of the active injection system consists of an actuation air jet at the inner core of the coaxial nozzle (1mm ID) that provides large mean and fluctuating velocity profiles in the shear layers of a fluid stream injected surrounding the core through an annular nozzle with ID=1.5 mm and OD=1.96 mm. The baseline flowfield of the annular stream in various crossflow conditions was studied first without actuation. The injector's active and passive actuation modes of operation are then evaluated and compared across multiple crossflow conditions with the baseline data. In the active mode, the annular stream is actuated by a pulsed jet operating at 17 kHz. In steady mode, the actuation jet is a steady coaxial underexpanded jet. Measurements using planar laser-induced fluorescence (PLIF) indicate that the active coaxial injection approach using high-frequency pulsed jets at the core significantly improves mixing of the acetone-seeded annular stream in supersonic crossflow conditions compared to the steady and baseline test cases. Data suggests that such a system has the potential to be evaluated further for real-life flow mixing and control applications, such as supersonic and hypersonic combustors. 

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3. Flow dynamics of a 15kHz supersonic coaxial injector: insights from PLIF and PIV measurements

   https://doi.org/10.1017/aer.2025.10047  

   Solomon, JT; Lockyer, R; Hackworth, N (August 2025, The Aeronautical Journal)

   Holger, Babinsky (Ed.)

   Abstract This paper presents experimental studies on a novel active high-frequency coaxial injector system designed for enhanced flow mixing and control at extreme flow velocity conditions. The flow dynamics and mixing characteristics of the system operating at 15kHz were captured using planar laser-induced fluorescence (PLIF) and particle image velocimetry (PIV) techniques and compared against its steady and baseline modes. In pulsed mode, this active injection system delivers a pulsed supersonic actuation air jet at the inner core of the coaxial nozzle that provides large mean and fluctuating velocity profiles in the shear layers of an acetone-seeded fluid stream injected surrounding the core through an annular nozzle. The instantaneous velocity, vorticity and acetone concentration fields of the injector are discussed. The high-frequency streamwise vortices and shockwaves tailored to the mean flow significantly enhanced supersonic flow mixing between the fluids compared to a classical steady coaxial configuration operating at the same input pressure. The paper analyses the dynamic and diffusion characteristics of this active coaxial injection system, which may have potential for supersonic mixing applications. 

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4. Jet in Accelerating Turbulent Crossflow with Passive Scalar Transport

   https://doi.org/10.3390/en15124296  

   Quiñones, Carlos; Araya, Guillermo (June 2022, Energies)

   The interaction of a turbulent, spatially developing crossflow with a transverse jet possesses several engineering and technological applications such as film cooling of turbine blades, exhaust plumes, thrust vector control, fuel injection, etc. Direct Numerical Simulation (DNS) of a jet in a crossflow under different streamwise pressure gradients (zero and favorable pressure gradient) is carried out. The purpose is to study the physics behind the transport phenomena and coherent structure dynamics in turbulent crossflow jets at different streamwise pressure gradients and low/high-velocity ratios (0.5 and 1). The temperature was regarded as a passive scalar with a molecular Prandtl number of 0.71. The analysis is performed by prescribing accurate turbulent information (instantaneous velocity and temperature) at the inlet of a computational domain. The upward motion of low-momentum fluid created by the “legs” of the counter-rotating vortex pair (CVP) encounters the downward inviscid flow coming from outside of the turbulent boundary layer, inducing a stagnation point and a shear layer. This layer is characterized by high levels of turbulent mixing, turbulence production, turbulent kinetic energy (TKE) and thermal fluctuations. The formation and development of the above-mentioned shear layer are more evident at higher velocity ratios. 

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5. PLIF and PIV on a 15 kHz Supersonic Co-Axial Injector

   Solomon, JT; Noah, H; Lockyer, R (June 2024, AIAA Aviation 2024)

   AIAA (Ed.)

   With a focus on improving mixing at extreme flow velocity conditions, this paper presents planar laser-induced fluorescence (PLIF) and particle image velocimetry (PIV) studies on the flowfield of a high-speed, pulsed co-flow system integrated with a high-frequency actuator operating at 15 kHz. This active injection system delivers a supersonic pulsed actuation air jet at the inner core of the co-axial nozzle that provides large mean and fluctuating velocity profiles in the shear layers of a fluid stream injected surrounding the core through an annular nozzle. The instantaneous velocity, vorticity, and acetone concentration fields of the injector in three distinct modes of operation – pulsed actuation, steady actuation, and without actuation -are presented. The high-frequency streamwise vortices and shockwaves tailored to the mean flow significantly enhanced supersonic flow mixing between the fluids compared to the steady co-axial configuration operating at the same input pressure. The study analyzes the mixing and dynamic characteristics of this active co-axial injection system, which has the potential for supersonic mixing applications. 

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