Flowing low temperature atmospheric pressure plasma devices have been used in many technological applications ranging from energy efficient combustion through to wound healing and cancer therapy. The generation of the plasma causes a sudden onset of turbulence in the inhomogeneous axisymmetric jet flow downstream of the plasma plume. The mean turbulent velocity fields are shown to be self-similar and independent of the applied voltage used to generate the plasma. It is proposed that the production of turbulence is related to a combination of the small-amplitude plasma induced body forces and gas heating causing perturbations in the unstable shear layers at the jet exit which grow as they move downstream, creating turbulence.
Low-temperature plasmas are strongly non-equilibrium systems, where the energy of electrons typically exceeds that of the ions and neutrals by several orders of magnitude1,2; such conditions give rise to striking physical and chemical characteristics. Over the past half-century our growing understanding of these unique systems has underpinned some of the greatest achievements of the modern age, including semiconductor fabrication and energy efficient lighting3. The generation of low-temperature plasma under atmospheric pressure conditions presents a new domain in plasma physics and enables the unique physical and chemical properties of the discharge to be accessed beyond the confines of a vacuum chamber.
Of the many different low temperature atmospheric pressure plasma devices currently under investigation, the dielectric barrier plasma plume stands alone due to its inherent ability to produce a plasma which is projected well beyond the confines of the generating electrodes4. Such plasmas are typically created by ionizing a flowing noble gas within a capillary which exits into a background gas, creating an inhomogeneous axisymmetric jet flow4. The plasma plume, rich in energetic metastable species and electrons, is free to interact with the background gas and in doing so initiates an abundance of dissociation, excitation and ionization reactions, ultimately yielding a rich reactive chemistry which is both accessible and non-thermal. These unique characteristics have been exploited across multiple diverse domains including nanoscale materials modification5 where reactive plasma species impinge on a surface to elicit changes in both functionality and morphology, energy efficient combustion where energetic plasma species provide new reaction pathways6 and healthcare related applications including wound healing and cancer therapy, where reactive plasma species initiate biological responses in living tissues7,8.
Underpinning all of these diverse applications is the reactive plasma chemistry. Uncovering a deeper physical and quantitative description of the velocity fields generated downstream of the discharge is the essential first step to improve our understanding of the production mechanisms of reactive chemical species at the plasma-gas interface. In order to address this complex and multifaceted challenge which spans the fields of plasma physics, fluid dynamics and non-equilibrium plasma chemistry, we report on the first quantitative measurements of the velocity fields generated downstream of a low temperature atmospheric pressure plasma plume.
Results and Discussion
The turbulent flow field of variable-density jets is characterized by the Froude number (Fr), which is the ratio of momentum flux to buoyancy flux. The Froude number is defined as , where ρj is the density of the injected fluid, ρa is the density of the ambient fluid and g is the acceleration due to gravity. The vertical flow field is divided into three sections9, which are functions of downstream distance (x). First there is a region of pure jet behaviour which is dominated by momentum flux. This region begins at the jet exit (x/D = 0, where D is the inner diameter of the capillary) and extends as far as the dimensionless abscissa, XI = (xI/D)Fr−0.5(ρj/ρa) −0.25 ≈ 0.5. The pure jet transitions into a buoyant jet in an intermediary region which extends to ~10XI. Beyond the intermediary region, the flow is dominated by buoyancy. The data presented here predominantly resides in the pure jet region where buoyancy is negligible: see Table 1 which details the downstream extent of the pure jet region, xI/D.
Figure 1 shows Schlieren photography of the axisymmetric helium jet flow at a Reynolds number of Re = UmD/νj = 135 (where Um is the jet exit velocity and νj is the kinematic viscosity of helium). The jet flow begins at x/D = 0 and r is radial distance. In the absence of plasma (Fig. 1a) the helium jet flow remains laminar. This is entirely consistent with observations at Re = 260 and is broadly consistent with the flow fields at Re = 400, which begin to transition into a turbulent regime at x/D ≈ 25. These observations are in contrast to the instantaneous flow fields of the helium jet flow with plasma ignited, Fig. 1(b–d), where density fluctuations generated by the application of the plasma indicate a transition-to-turbulence from x/D ≈ 10. The developing turbulent flow fields observed in Fig. 1(b–d) are entirely consistent with all others in the literature10,11,12,13; the turbulent flow fields generated downstream of atmospheric plasma plumes have been qualitatively observed over a wide range of Reynolds number (135–840), applied voltage (8–30 kV peak-peak) and frequencies (125–50,000 Hz; Stθ = fθ/Um = 0.000012–0.035, where θ(~0.01D) is the momentum thickness of the shear layers at the jet exit).
Figure 2 shows ensemble-averaged streamwise velocity of helium jet flow at Re = 260 with a plasma ignited at 12–16 kV peak-peak. We observe that increasing the applied voltage does not increase the magnitude of the ensemble-averaged streamwise velocity within the turbulent flow region downstream of the discharge. This observation is entirely consistent with data at Re = 135 and 400. Note that throughout Fig. 2, the location where the visible plasma ends is marked with a pink dot and data in the laminar flow regime is omitted due to lack of PIV seeding.
The ensemble-averaged electro-hydrodynamic force generated by guided streamers is ~5 × 103 Nm−3 14. Assuming, conservatively, that each guided streamer has a sheath width of ~250 μm14, the increase in velocity due to the electro-hydrodynamic body force is ~0.003−0.025Um over Re = 135–400. Further, the plasma increases the mean temperature of helium at the jet exit by ~10–30 degrees Celsius at 10–16 kV over Re = 135–400. Such a change in temperature causes an increase in jet exit velocity of ~0.03–0.09Um. Thus, gas heating and electro-hydrodynamic body forces do not significantly alter the mean velocity fields.
It is well known that the shear layers at the exit of an axisymmetric jet are highly unstable15,16. Small finite perturbations (~0.1Um) over a wide frequency range (Stθ < 0.04) can grow exponentially in the unstable shear layers to transition jet flows into a turbulent regime from Re > 5017,18,19,20. Indeed, linear stability theory19 and many experimental investigations21 of homogeneous axisymmetric jet flow predict a dominant excitation frequency (f0) at a Strouhal number of Stθ ≈ 0.017. In this investigation at a Re = 260, a Stθ ≈ 0.017 gives a dominant excitation frequency of f0 ~ 51 kHz (see Table 1), which is close to the driving frequency of the sinusoidal waveform used to generate the plasma. More recently global instability modes in low density axisymmetric jets22 have been found to scale as fD2/vj ~ Re(D/θ0)1/2(1 + (ρj/ρa)1/2), entirely consistent with dominant frequencies on the order of 10’s kHz for the helium jet flows discussed here, albeit with them located in the lower limit of this scaling law. Indeed, energy spectra of the discharge current show a dominant peak at the driving frequency of f ≈ 50 kHz, accompanied by multiple high energy harmonics: see the (upper left) inset of Fig. 3. Thus, we propose that the sudden onset of turbulence observed within the flow fields (Fig. 2(b–d)) is generated by a combination of small-amplitude electro-hydrodynamic body forces and gas heating causing perturbations in the unstable shear layers at the jet exit, which become amplified as they travel downstream causing velocity fluctuations, Reynolds shear stresses and thus the production of turbulence. Moreover, at higher applied voltages, the energy injected into the developing shear layers at the jet exit is increased, see for example the increase in energy around f ≈ 50 kHz in the (upper left) inset in Fig. 3, which causes the onset of turbulence closer to the jet exit; an observation well known within the literature10,11,12,13 and one which is not accompanied by any significant increase in jet velocity, see Fig. 2. The reduction in plasma plume length for higher applied voltages (see for example the locations of the pink dots in Fig. 2) is also due to the production of turbulence, mixing air into the helium jet flow and quenching the discharge.
Finally, we characterize the turbulent velocity fields generated by the atmospheric pressure plasma plumes. Figure 3 shows excellent collapse of the decay of the ensemble-averaged centreline velocity (Uc) when plotted with reduced streamwise coordinate, x* = (x − x0)/de(x)23. The decay of the ensemble-averaged centerline velocity with increasing distance downstream from the jet exit does not depend on applied voltage. The linear fit to the data in Fig. 3 has gradient, K = 0.120 ± 0.017 (to one standard deviation), which is in excellent agreement with inhomogeneous jet flow data in the literature9,23,24. The error bars show the uncertainty in obtaining the virtual origin (x0), which is ultimately due to the spatial resolution of the PIV setup. For comparative purposes, data from a helium jet flow at Re = 400 with no discharge is also included (green closed circles) and shows the same rate of decay of the ensemble-averaged centerline velocity. For reference, the unscaled mean centreline velocity is shown on the (lower right) inset in Fig. 3. The jet-half width scales as r1/2 ~ x, a linear fit to the data provides the virtual origin. Noteworthy is the jet half-angle, tan(β) ≈ 0.14, which is approximately double the typical angle found in the literature23,25, most likely due to a low Reynolds number effect26. The local effective diameter, de(x) = D(ρj/ρe)1/2, accounts for the density gradient along the centreline of the developing inhomogeneous jet flow. Djeridane et al.27 showed that the axial evolution of local density within the pure jet region of helium and carbon dioxide axisymmetric jets scales as ρe ~ Kc(ρj/ρa)−0.6(x − xc)/D, albeit over Re ~ 103–104. Here Kc = 0.1339,27 is a constant and xc is the length of the potential core of the jet, which is assumed to be negligibly small28.
Figure 4 shows the self-similar turbulence structure of the developing inhomogeneous axisymmetric jet flow at Re = 135 (black symbols), Re = 260 (red symbols) and Re = 400 (blue symbols). With increasing distance from the jet exit, the radial profiles of the ensemble-averaged streamwise velocity (top) collapse to a single normalised exponential curve of the form: U/Uc = exp(−r/r1/2)2 ln(2), which is entirely consistent with all other turbulent jet data in the literature9,16,23,24. The streamwise (u′; middle) and radial (v′; middle) velocity fluctuations, which represent local turbulence intensities and the Reynolds shear stresses (uv; bottom), which indicates turbulence production, collapse when x* > 35. The radial velocity fluctuations at Re = 260 and 400 follow a curve of the form: 3v′/2Uc = 0.117 exp(−0.33r/r1/2)2 ln(2), whilst the radial velocity fluctuations at Re = 135 follow: 3v′/2Uc = 0.174 exp(−0.4r/r1/2)2 ln(2). The data at x* = 25 shows considerable scatter, indicating that the flow field is still developing into a self-similar structure at this streamwise distance (i.e. the velocity data does not collapse to a single curve). Furthermore, data for Re = 135, Fig. 4 (a, b; black symbols) does not collapse with data at higher Re. This is most likely due to the data at Re = 135 being located in the intermediate jet development region (see Table 1), which may not retain a self-similar turbulence structure9,29. Generally, the data for Re = 260 and 400 show good agreement with the helium axisymmetric jet flow data of Amielh et al.24 (grey solid and dashed lines). Further comparison is made with the helium jet flow data which is free from plasma at Re = 400, x* = 70 (green closed circles), in Fig. 4(d). These data show that the radial profiles of the mean and higher order statistics collapse to the plasma data once scaled appropriately.
In this letter we report on the characteristics of an inhomogeneous axisymmetric turbulent jet flow generated downstream of a low temperature atmospheric pressure plasma plume. We have shown that the mean turbulent velocity fields of the jet flows under investigation are independent of applied voltage. Indeed, an order-of-magnitude analysis shows that the temperature and electro-hydrodynamic forces generated by the plasma have a negligible effect on the mean velocity fields. These results allow us to posit that the production of turbulence is due to a combination of the small-amplitude electro-hydrodynamic body forces and gas heating generating perturbations in the highly unstable shear layers at the jet exit, which grow as they move downstream, creating Reynolds shear stresses and thus the production of turbulence. Finally and more broadly, by using a plasma as a unique excitation source, velocity measurements have been conducted in inhomogeneous axisymmetric turbulent jets at Reynolds numbers on the order of 100, which are one order of magnitude lower than any other study available within the literature. Even at such low Reynolds numbers, we have shown that the spatially developing velocity fields are turbulent and self-similar. Furthermore we have shown that the developing self-similar turbulent velocity fields generated by the plasma are similar to the turbulent velocity fields which develop naturally (i.e. without a plasma) with increasing distance from the jet exit. These data provide vital information for the future development of low-temperature atmospheric pressure plasma plume devices and for the validation of associated computational models.
The low temperature atmospheric pressure plasma device investigated in this study is shown schematically in Fig. 5. The device consists of a quartz tube with an inner diameter (D) of 1.1 mm. The discharge was generated via a 10 mm wide copper electrode, which was wrapped around the outer circumference of the quartz tube and positioned 10 mm away from the jet exit. A custom-built power source applied a sinusoidal voltage waveform to the copper electrode at a voltage of 10–16 kV peak-to-peak at an AC driving frequency of 50 kHz. The applied voltage generated a stable plasma which protruded from the quartz tube within a flow of helium; in this single electrode configuration the electrical circuit is completed via capacitive coupling to ground. An MKS mass flow controller regulated the flow of helium (99.996% purity) at 1, 2 or 3 Standard Litres per Minute (SLM). This provided a range in Reynolds number of Re = UmD/νj = 135–400 (where Um is the jet exit velocity determined by mass continuity and νj is the kinematic viscosity of helium). At a given standard flow rate, the jet exit Reynolds number (Re) monotonically decreased with increased applied voltage due to a small increase in mean fluid temperature at the jet exit (between 10–30 degrees Celsius increase above the ambient gas temperature with increasing applied voltage, measured by an Omega FOB100 fibre optic thermometer system). The nominal experimental conditions are shown in Table 1 with (±) range of Re as shown.
Global measurements of the velocity field were taken along the centreline of the jet with a time-resolved particle image velocimetry (PIV) system from TSI Incorporated. All measurements were conducted inside a closed chamber to ensure the helium jet flow was not influenced by any external drafts. The chamber had a cross-section of 1000D × 1000D and a height of 1500D. Figure 6 shows a schematic representation of the experimental setup, showing the plasma plume device positioned in the laser sheet within the PIV enclosure. Olive oil with a nominal size of 1 μm was used to seed the air. The Stokes numbers of the seeding particles used throughout this study were <0.1. This ensured that the seeding particles followed the fluid flow closely with tracing errors being <1%30. In total, 500 vector maps were acquired at a frequency of 500 Hz for each experiment. The velocity vectors were computed on a square grid with spatial resolution of 0.43D using a recursive cross-correlation technique. Finally, the flow field was visualized using Schlieren photography with a Nikon D7000 camera at a shutter speed of 1/80 s; for details of this setup see Ghasemi et al.13.
How to cite this article: Whalley, R. D. and Walsh, J. L. Turbulent jet flow generated downstream of a low temperature dielectric barrier atmospheric pressure plasma device. Sci. Rep. 6, 31756; doi: 10.1038/srep31756 (2016).
Iza, F., Lee, J. K. & Kong, M. G. Electron kinetics in radio-frequency atmospheric-pressure microplasmas. Physical Review Letters 99, 075004 (2007).
Shi, J. J. & Kong, M. G. Evolution of discharge structure in capacitive radio-frequency atmospheric microplasmas. Physical Review Letters 96, 105009 (2006).
National Research Council. Plasma Science: Advancing Knowledge in the National Interest (Physics 2010) (National Academies Press, 2014).
Lu, X., Naidis, G. V., Laroussi, M. & Ostrikov, K. Guided ionization waves: Theory and experiments. Physics Reports 540, 123 (2014).
Labay, C. et al. Antibiotic-loaded polypropylene surgical meshes with suitable biological behaviour by plasma functionalization and polymerization. Biomaterials 71, 132 (2015).
Kim, W., Do, H., Mungal, M. G. & Cappelli, M. A. Optimal discharge placement in plasma-assisted combustion of a methane jet in cross flow. Combustion and Flame 153, 603 (2008).
Kong, M. G. et al. Plasma medicine: an introductory review. New J. Phys. 11, 35, 115012 (2009).
Cheng, X. et al. The effect of tuning cold plasma composition on glioblastoma cell viability. PLoS ONE 9, e98652 (2014).
Chen, C. J. & Rodi, C. J. Vertical turbulent buoyant jets - A review of experimental data (Permagon Press, New York, 1980), The Science and Application of Heat and Mass Transfer.
Boselli, M. et al. High-speed multi-imaging of repetitive unipolar nanosecond-pulsed DBDs. IEEE Transactions on Plasma Science 42, 2744, 6845351 (2014).
Bradley, J. W. et al. Schlieren photography of the outflow from a plasma jet. IEEE Transactions on Plasma Science 39, 2312 (2011).
Papadopoulos, P. K. et al. Interpretation of the gas flow field modification induced by guided streamer (‘plasma bullet’) propagation. Journal of Physics D: Applied Physics 47, 425203 (2014).
Ghasemi, M., Olszewski, P., Bradley, J. W. & Walsh, J. L. Interaction of multiple plasma plumes in an atmospheric pressure plasma jet array. Journal of Physics D: Applied Physics 46, 052001 (2013).
Xiong, R., Xiong, Q., Nikiforov, A. Y., Vanraes, P. & Leys, C. Influence of helium mole fraction distribution on the properties of cold atmospheric pressure helium plasma jets. Journal of Applied Physics 112, 033305 (2012).
Batchelor, G. K. & Gill, A. E. Analysis and instability of axisymmetric jets. Journal of Fluid Mechanics 14, 529 (1962).
O’Neill, P., Soria, J. & Honnery, D. The stability of low Reynolds number round jets. Experiments in Fluids 36, 473 (2004).
Viilu, A. Experimental determination of the minimum Reynolds number for instability in a free jet. Transactions of the ASME, 506 (1962).
Sato, H. & Sakao, F. An experimental investigation of the instability of a two-dimensional jet at low Reynolds number. Journal of Fluid Mechanics 20, 337 (1964).
Michalke, A. On spatially growing disturbances in an inviscid shear layer. Journal of Fluid Mechanics 23, 521 (1965).
Peacock, T., Bradley, E., Hertzberg, J. & Lee, Y. C. Forcing a planar jet flow using MEMS. Experiments in Fluids 37, 22 (2004).
Gutmark, E. & Ho, C. M. Preferred modes and spreading rates of jets. Physics of Fluids 26, 2932 (1983).
Hallberg, M. P. & Strykowski, P. J. On the universality of global modes in low-density axisymmetric jets. Journal of Fluid Mechanics 569, 493 (2006).
Sautet, J. C. & Stepowski, D. Dynamic behaviour of variable-density, turbulent jets in their near development fields. Physics of Fluids 7, 2796 (1995).
Amielh, M., Djeridane, T., Anselmet, F. & Fulachier, L. Velocity near-field of variable density turbulent jets. International Journal of Heat and Mass Transfer 39, 2149 (1996).
Malmstrom, T. G., Kirkpatrick, A. T., Christensen, B. & Knappmiller, K. D. Centreline velocity decay measurements in low-velocity axisymmetric jets. Journal of Fluid Mechanics 246, 363 (1997).
Hussein, H. J., Capp, S. J. & George, W. K. Velocity measurements in a high Reynolds number, momentum conserving, axisymmetric, turbulent jet. Journal of Fluid Mechanics 258, 31 (1994).
Djeridane, T., Amielh, M., Anselmet, F. & Fulachier, L. Velocity turbulence properties in the near-field region of axisymmetric variable density jets. Physics of Fluids 8, 1614 (1996).
Symons, E. P. & Labus, T. L. Experimental investigation of an axisymmetric fully developed laminar free jet, NASA Technical Note NASA TN D-6304 (1971).
So, R. M. & Aksoy, H. On vertical turbulent bouyant jets. International Journal of Heat and Mass Transfer 36, 3187 (1993).
Tropea, C., Yarin, A. & Foss, J. Springer Handbook of experimental fluid mechanics. (Springer, New York, 2007).
J.L.W. would like to acknowledge the support of the Engineering and Physical Sciences Research Council (EPSRC), grant EP/J005894/1 and EP/N021347/1. R.D.W. would like to acknowledge the support of the NATO project AVT-254. Both authors would like to thank Dr. Martin Hyde of TSI for his assistance during the initial setup of the PIV system.
The authors declare no competing financial interests.
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Whalley, R., Walsh, J. Turbulent jet flow generated downstream of a low temperature dielectric barrier atmospheric pressure plasma device. Sci Rep 6, 31756 (2016). https://doi.org/10.1038/srep31756
This article is cited by
Numerical modeling of dielectric barrier discharge actuators based on the properties of low-frequency plasmons
Scientific Reports (2022)
Revealing Plasma-Surface Interaction at Atmospheric Pressure: Imaging of Electric Field and Temperature inside the Targeted Material
Scientific Reports (2020)
The creation of electric wind due to the electrohydrodynamic force
Nature Communications (2018)
Directional mass transport in an atmospheric pressure surface barrier discharge
Scientific Reports (2017)
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.