Measurements of Absolute Atomic Nitrogen Density by Two-Photon Absorption Laser-Induced Fluorescence Spectroscopy in Hot Air Plasma Generated by Microwave Resonant Cavity

Abstract

For the first time, absolute densities of atomic nitrogen in its ground state (N4S) have been measured in hot dry and humid air plasma columns under post-discharge regime. The determination of space-resolved absolute densities leads to obtain the dissociation degrees of molecular nitrogen in the plasma. The hot plasmas are generated inside an upstream gas-conditioning cell at 600 mbar when the air gas flow is directly injected at 10 slm in a microwave resonant cavity (2.45 GHz, 1 kW) placed in the downstream side. Density measurements based on laser induced fluorescence spectroscopy with two-photon excitation (TALIF), are more particularly performed along the radial and axial positions of the plasma column. Calibration of TALIF signals is performed in situ (i.e. in the same gas-conditioning cell but without plasma) using an air gas mixture containing krypton. Optical emission spectroscopy is considered to estimate the rotational gas temperature by adding a small amount of H2 in dry air to better detect OH (A-X) spectra. The rotational temperatures in humid air plasma column (50% of humidity) are larger than those of dry air plasma column by practically 30% near the nozzle of resonant cavity on the axis of the plasma column. This is partly due to attachment heating processes initiated by water vapor. A maximum of the measured absolute nitrogen density is also observed near the nozzle which is also larger for humid air plasma column. The obtained dissociation degrees of molecular nitrogen in both dry and humid air plasma along the air plasma column are lower than the cases where only thermodynamic equilibrium is assumed. This is characteristic of the absence of chemical and energetic equilibria not yet reached in the air plasma column dominated by recombination processes.

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Marchal, F. , Merbahi, N. , Wattieaux, G. , Piquemal, A. and Yousfi, M. (2017) Measurements of Absolute Atomic Nitrogen Density by Two-Photon Absorption Laser-Induced Fluorescence Spectroscopy in Hot Air Plasma Generated by Microwave Resonant Cavity. Journal of Analytical Sciences, Methods and Instrumentation, 7, 93-115. doi: 10.4236/jasmi.2017.74008.

1. Introduction

This work is devoted to the experimental determination of absolute density of atomic nitrogen in the background state (N4S) coming from dissociation of molecular nitrogen of a hot air plasma generated by a microwave at 2.45 GHz resonant cavity for an input power of 1 kW. Many applications and understanding of plasma physics are expected from the characterization of the present hot air plasma. In our case, the experimental characterization to obtain more particularly the density of atomic nitrogen in such air plasma can be used, when coupled with previously obtained atomic oxygen densities [1] [2] , for validation of a complex hydro-kinetics model involving transport and plasma chemistry.

As is known, the classical optical emission spectroscopy (OES) can give direct access only to the radiative excited species not to the ground state species. In fact, OES allows the determination of absolute densities of the upper level of the emissive transition after a prior spectrum calibration using a spectral lamp. OES gives also information on for instance the temperatures of gas, rotation and vibration species from classical comparison between synthetic and experimental specific molecular spectra. However, OES cannot directly give any direct information on the non-emissive states as the density of the atomic ground state which can exceed the excited species density by several orders of magnitude in the case of the present microwave plasma.

The alternative to obtain, for instance, the density of atomic nitrogen in the ground state, due to molecular nitrogen dissociation in the present microwave hot air plasma, is to use the absorption spectroscopy and more particularly the laser-induced fluorescence spectroscopy (LIF) that generally allows direct access to the density of the non-emissive species as atomic ground states and also metastables. It can be found in for instance [3] and the references given therein, many details on the laser-induced fluorescence spectroscopy and its advantages in comparison for instance to standard absorption or Raman spectroscopy.

In the present work, two-photon absorption laser-induced fluorescence (TALIF) spectroscopy is used for the estimation of atomic nitrogen density in the ground state while optical emission spectroscopy is used to estimate the gas temperature from comparisons between experimental and synthetic OH (A-X) spectra. It is noteworthy to emphasize in the case of the measurements of atomic nitrogen density that TALIF spectroscopy has been already used in the framework of a few literature setups of lower temperature plasmas generated for instance by a nitrogen microwave discharge (433 MHz, 300 W) at low pressure and its afterglow in the presence of the so-called short-lived afterglow [4] or by a flowing microwave post-discharge sustained by a 2.45 GHz surfatron source in pure nitrogen at atmospheric pressure [5] .

However, TALIF and absorption spectroscopy were not used up to now to measure atomic nitrogen density in the case of hot air plasma generated by a microwave resonant cavity. The next Section 2 is devoted to a summary of the principle of TALIF measurement with the calibration method. This is followed in Section 3 by the descriptions of the experimental setup used to generate the hot air plasma from the microwave resonant cavity, the laser setup of TALIF spectroscopy used to measure the absolute density of nitrogen oxygen and the optical emission spectroscopy used to measure the gas temperature. The latter is required for the analysis in Section 4 of the measured N atom densities along the axial and radial directions of both humid and dry air plasma columns.

2. Principle of TALIF Measurements

TALIF measurements are a two-photon absorption spectroscopic method to measure the ground state density of an atomic species in a gaseous plasma medium. Absolute density measurements are based on the comparison of two-photon absorption spectra with a noble gas whose the two-photon absorption wavelength is close to the transition of the investigated atomic species. Figure 1 shows the classical TALIF excitation and de-excitation schemes of atomic nitrogen and krypton. The TALIF measurements are performed by recording the fluorescence coming from the radiative decay of the excited state (labeled 2) created by two-proton laser absorption of the atomic ground state (labeled 1).

The two-photon transition probability W ( r , t ) is proportional to the square

Figure 1. Two-photon excitation schemes of krypton and atomic nitrogen.

of the laser energy flux [6] :

W 12 ( r , t ) = σ ^ ( 2 ) ( I ( r , t ) h ν ) 2 (1)

where I ( r , t ) is the laser intensity and σ ^ ( 2 ) is the generalized excitation cross section. σ ^ ( 2 ) depends on the cross section σ ( 2 ) of the absorbing specie, on g ( ν ) , the normalized line profile of the two-photon excitation ( g ( ν ) d ν = 1 ), which is the convolution of the laser line profile and the Doppler broadened absorption line, and on a statistical factor G ( 2 ) equal to 2 in the case of a stochastic multimode laser [7] :

σ ^ ( 2 ) = σ ( 2 ) g ( ν ) G ( 2 ) (2)

In the case of low laser intensities, the ground state is not depleted, its density n 1 remains unchanged and the ionization of the exited state can be neglected. Therefore, the density of the excited state n 2 is given by

d n 2 ( r , t ) d t = W 12 ( r , t ) n 1 ( A 2 + Q ) n 2 ( r , t ) (3)

where A 2 is the fluorescence rate of the excited state, inverse of the natural lifetime τ n and Q is the effective quenching rate. Assuming a gaussian temporal profile for the laser pulse where the pulse width Δ t L = 2 s L 2 l n 2 is the FWHM, the two-photon excitation rate can be rewritten as a function of the laser energy pulse E and of the beam waist w 0 of the laser beam

W 12 ( r , t ) = σ ( 2 ) g ( ν ) G ( 2 ) E 2 ( π w 0 2 ) 2 ( h ν ) 2 1 2 π s L 2 exp ( t 2 s L 2 ) (4)

The excited state radiatively decays and populates an intermediate state (labeled 3 in Figure 1). A 23 is the Einstein coefficient for spontaneous emission of this optical transition.

The number of fluorescence photons per unit time and unit volume is given by

d n F ( r , t ) d t = A 23 n 2 ( r , t ) = n 1 A 23 σ ( 2 ) g ( ν ) G ( 2 ) E 2 ( π w 0 2 ) 2 ( h ν ) 2 1 4 π s L e x p [ s L 2 4 ( A 2 + Q ) 2 ] × [ erf ( t s L s L A 2 + Q 2 ) + 1 ] e x p [ ( A 2 + Q ) t ] (5)

The time integrated TALIF signal S results by integrating the number of fluorescence photons over the two-photon transition and the probed volume, including experimental system factors

S = Δ Ω 4 π T η V ν t = t = + A 23 n 2 ( r , t ) d V d ν d t (6)

Δ Ω is the solid angle of detection, T is the transmission of the optical system of detection and η is the efficiency of the photomultiplier at the fluorescence wavelength. The density of the excited state n 2 in a small volume of detection

is assumed to be homogeneous. Introducing the branching ratio a 2 = A 23 A 2 + Q and integrating over the time and over the detection volume V, the expression of the TALIF signal can be written as

S = n 1 a 2 Δ Ω T η 4 π σ ( 2 ) G ( 2 ) E 2 ( π w 0 2 ) 2 ( h ν ) 2 V 2 π s L (7)

The TALIF signal S, measured by integrating the two-photon excitation spectrum over all the resonance line and over time, exhibits quadratic laser energy dependence. S strongly depends on the branching ratio a 2 which decreases with the quenching rate Q of the excited state. The collisional quenching rate is given by

Q = q k q ( T ) n q (8)

k q ( T ) is the quenching coefficient of the colliding species q of density n q . The quenching coefficient depends on temperature T of the detection volume which is often assumed in the literature equal to the room temperature T r e f . The collisional cross section usually exhibits a weak temperature dependence [8] , according to the ideal gas law and for a thermal velocity distribution, k q ( T ) can be written as

k q ( T ) = k q ( T r e f ) T T r e f (9)

The TALIF calibration method is based on the comparison of TALIF signals obtained respectively with the atomic species to be quantified and with a noble gas of known density. Xenon is generally used for atomic oxygen density measurements and krypton is suitable for calibration of atomic nitrogen densities. Assuming the same experimental optical conditions of fluorescence detection and the same laser beam geometries and pulse widths, the atomic density n X of the specie X is obtained from the density n R of the reference gas R according to Equation (7):

n X = n R S ( X ) S ( R ) a 2 ( R ) a 2 ( X ) T ( R ) η ( R ) T ( X ) η ( X ) σ ( 2 ) ( R ) σ ( 2 ) ( X ) ( E R E X ν X ν R ) 2 (10)

This expression remains valid at high pressure if the lifetime of the laser-excited state is lower than the laser pulse width. To minimize uncertainties, the calibration method requires similar excitation conditions for R and X. The excitation and fluorescence wavelengths have to be close and the optical system of detection needs to remain unchanged. For low pressure plasmas, Q A 2 , the calibration method requires the knowledge of the optical branching ratio

a 20 = A 23 i A 2 i of the fluorescence transition. The radiative lifetime τ n of the laser excited atomic level is related to the sum of transition probabilities to all levels lower in energy: τ n = 1 i A 2 i . For high pressure plasmas, if the quenching

coefficients are not well defined, the calibration method cannot be applied with a good accuracy. Therefore the absolute branching ratio a 2 can be experimentally determined by comparing the energy normalized TALIF signal at low and high pressure respectively S low and S high measured in the same optical conditions [9] :

a 2 a 20 = 1 1 + τ n Q = n low S high n high S low (11)

3. Experimental Setup

3.1. Plasma Source

We experimentally analyzed an air plasma generated by a microwave resonant cavity. The 2.45 GHz microwave power supply (magnetron source, SAIREM) can provide power up to 3 kW. The microwaves are guided to the resonant cavity via a waveguide system (WR-340) closed by an adjustable short circuit. The matching was adjusted to maintain the reflected power below 2% of the incident microwave power. The total gas flux of 10 slm at a total pressure of 600 mbar was injected inside the microwave cavity and the plasma expanded in the direction of the upstream side towards a gas-conditioning cell where the analysis of the post discharge regime was performed. The power delivered to the plasma was set to 1 kW. Synthetic dry air flow (80% N2, 20% O2) was monitored by a mass flow controller and the total pressure was controlled by a capacitive pressure gauge and a throttle valve located between the cell and the vacuum pump. A small amount of H2 with a flow of 200 sscm could be injected to increase the intensity of OH (A-X) spectrum used to estimate gas temperature. A small amount of water vapor (18.5 g/h corresponding to 50% of humidity) can also be added to the main gas flow to study plasma generated in humid air. Figure 2 displays a view of the of the air plasma column ejected from the resonant cavity (not visible because placed in the downstream part) through the nozzle (at z = 0 mm ) inside the gas-conditioning cell kept at 600 mbar for the present experiment.

The whole plasma reactor (MW resonant cavity and gas-conditioning cell) were mounted on a (r, z) plateau allowing a milimetric vertical (z axis) and horizontal (r axis) translations of the plasma cell without moving the laser beam and the optics. Such a translation setup enables to perform TALIF and OES spectroscopies along the axial and the radial directions of the air plasma column in order to determine the spatial cartography of N(4S) density and gas temperature. The plasma cell is equipped of two 70 mm diameter quartz viewports perpendicularly to the laser beam and of two 40 mm diameter quartz viewports along the laser beam. The view ports dimensions limits the TALIF measuring range along the plasma column.

Figure 2. Picture of the air plasma column inside the gas-conditioning cell and generated by the microwave resonant cavity placed in the downstream side below the nozzle. The air plasma column diameter is 15 mm at the bottom of the column and the diameter of the window is 60 mm.

Figure 3. Schematic view of the TALIF experimental setup.

3.2. TALIF Setup

A general scheme of the TALIF setup is displayed in Figure 3. A tunable dye laser (Sirah Strech-Cobra) pumped by a the second harmonic of a Nd:YAG laser (Quanta-Ray CGR-150) was operated in the red spectral range, from 591 to 636 nm. The dye is a mixture of rhodamine B and rhodamine 101 dissolved in ethanol. The output beam is first frequency doubled by a temperature stabilized BBO crystal and the resulting UV beam is frequency mixed with the residual dye laser beam in a second temperature stabilized BBO crystal. A set of 4 dichroic mirrors selects the UV radiations of the laser beam. The UV laser radiations are located in the UV-C wavelength range, from 202 to 212 nm. The spectral line-width of the UV vertically polarized laser beam is specified to be 3 pm, the pulsed length is 7 ns with a 30 Hz repetition rate. The UV laser pulse energy is measured with an energy meter (Ophir Nova II) equipped with a pyroelectric energy sensor. The laser energy of the output beam is controlled by a motorized variable laser attenuator (Standa 10 MVAA) having an extremely low output beam deviation and a wide spectral range emission flux variation. The UV laser pulse energy was typically lower than 50 mJ per pulse to avoid saturation effects. The fluctuation of the laser pulses obeys to a gaussian statistical distribution. The energy-meter is connected th the computer ti meausre te mean and the dispersion of the laser pulses energies during the TALIF measurements.

The UV laser beam is focused by a MgF2 lens having a 200 mm focal length. The diameter of the focused spot is about 20 mm and the depth of focus is about 12 mm. The position of the laser spot can be adjusted from z = 15 mm to z = 50 mm from the nozzle. The size of the of the viewport prevented measurements at shorter distances from the nozzle.

The fluorescence light, emitted by a small volume centered at the focused spot is collected perpendicularly to the laser beam and focused by a BK7 lens with a focal length of 75 mm onto the photocathode of a photomultiplier (PMT Hamamatsu H7421-50) equipped with interference filters (bandwidth 10 nm) and an aperture slot to minimize the detection volume. The photomultiplier is operating in photon counting mode requiring a second diaphragm placed in front of the lens in order to reduce the fluorescence flux. Taking into account the parameters of the fluorescence detection optical system and of the focused laser beam, the detection volume can be assumed as a cylinder of 20 mm diameter and 200 mm length with an horizontal axis is coincident with that of the laser beam. The size of this detection volume corresponds to the spatial resolution of the TALIF measurements (200 mm along the radial axis and 20 mm along the z axis). Time-resolved photon counting is performed by a multichannel scaler Stanford Research SR 430 triggered by a fast photodiode with a time resolution of 5 ns. The laser and the multichannel scaler were triggered by a digital delay-pulse generator (Standford Research DG 645). Measurements are performed by scanning the laser wavelength and accumulating the time-resolved histogram of counts over 600 laser shots.

Figure 4 shows an example of an acquired N-TALIF measurement.

The experimental TALIF signal S is obtained by integrating over time and excitation wavelength the fluorescence photons detected. For this purpose, the time-integrated counts were fit with a Gaussian profile. The normalized TALIF signal S* is calculated by dividing S by the mean of the squared energy pulse.

The evaluations and expressions of measurement uncertainty estimations were consistent with the broad principles of the GUM [GUM:1995]. All major uncertainties sources were identified. The relevant uncertainty sources associated

Figure 4. Time and wavelength resolved N-TALIF signal. The detection volume is located at the center of the plasma ( r = 0 mm and at z = 15 mm from the nozzle of the microwave resonant cavity. Dry air flow q air = 10 slm , microwave power P M W = 1 kW , operating pressure p = 600 mbar .

Figure 5. Cause and effect diagram for normalized TALIF signal estimation.

with the output quantity S* are shown in the cause and effect diagram of the Figure 5.

The uncertainty component of the laser energy was obtained by a type B evaluation based on the technical specifications of the energy meter and of the sensor (calibration, linearity, reading, and inaccuracy due to errors in the wavelength sensitivity curve):

u ( E 2 ) = ( 2 [ u 2 ( calibration ) + u 2 ( wavelength ) + u 2 ( reading ) + u 2 ( linearity ) ] ) (12)

Typically, the relative uncertainty of the mean of the squared energy pulse is 6.7%. The uncertainty of the TALIF signal S is rather complex to quantify because some of the uncertainty components are correlated and also because the model that gives the TALIF Signal S as a function of all the input parameters is not linear. It is quite difficult to provide the partial derivatives of the model, as needed by the law of propagation of uncertainty. For example the repeatability of the numerical fit method depends on the number of the fluorescence photons detected and on background level. The number of counts recorded is correlated to the number of laser shots. So a statistical analysis (type A evaluation) was performed to evaluate the uncertainty of the single measurement of the TALIF signal. Uncertainty of the TALIF signal was estimated by a Monte-Carlo method. The probability distribution function of the laser-pulse energies was assumed to be Gaussian. For a typical laser energy of 50 mJ, the fluctuation of pulse-to-pulse energies measured are characterized by a standard deviation around 10% of the laser energy. The fluorescence flux detected remains rather weak (lower than 1 photon per laser pulse), therefore the probability of detection of a number of photons is assumed to obey to a Poissons law. The TALIF signal standard uncertainty is obtained by the determination of the standard deviation of the probability density function of the TALIF signal estimations obtained by series of 104 Monte Carlo simulated two-photon excitation spectra. As expected, the number of fluorescence photon detected per laser pulse is the major contribution of all the uncertainty sources. Figure 6 shows the evolution of the combined

relative standard uncertainty u ( S ) S of the normalized TALIF-Signal as a

function of the number of recorded counts. Then, the combined standard uncertainty of the measured normalized TALIF signal S * derives from energy and TALIF signal uncertainties:

[ u ( S * ) S * ] = [ u ( S ) S ] 2 + [ u ( E 2 ) E 2 ] 2 (13)

This uncertainty estimation of the normalized TALIF signal does not take into account variations of the laser beam parameters that define the detection volume or possible modifications of the geometry of the optical detection system. These variations may be caused by temperature changes, vibrations or degraded laser dye performance and may occur in the case of long time experiments. In this case, repeatability conditions are no longer fulfilled and reproducibility of TALIF measurements is affected. To improve the reproducibility, TALIF measurements using the same krypton air mixture are repeated on different days. If the results

Figure 6. Estimation of the relative TALIF signal uncertainty as a function of the TALIF signal. N-TALIF and Kr-TALIF signal relative uncertainties remain lower than 10% for TALIF-signals more than 2.0 × 10 4 counts nm pulse 1 . The estimated values of the relative TALIF uncertainty are fitted with a three parameters hyperbola. The value of the horizontal asymptote is 1.8%.

differ up to two times the standard uncertainty u ( S * ) , a new calibration is achieved.

3.3. Optical Emission Spectroscopy Setup

OES is used to estimate gas temperature along the axial and radial directions of the air plasma column generated by the MW resonant cavity and launched inside the gas-conditioning cell. We used a spectrophotometer with 0.75 m of focal length (Acton Spectra SP 2750, in the Czerny Turner configuration) covering a spectral range lying between 200 nm and 920 nm. The detecting device set at the exit of this spectrophotometer is a CCD camera (PIXIS 100, 1340 × 100 imaging array of 20 μm × 20 μm pixels). The plasma spectra are collected through an optical fiber (UV-silicon LG-455-020-3) placed at the spectrometer entrance slit (having 100 mm wide) and connected, on the plasma side, to an optical system (composed by 2´ magnification lens) aimed to target a small plasma volume. The optical system is mounted on a sliding stand which is able to move radially and axially in order to scan the plasma column with a spatial resolution of 1 mm. Spectra collections are performed using a 2400 grooves/mm grating in the UV range and a 1800 grooves/mm grating in the visible range. An optical high pass filter is used for the visible range in order to prevent any perturbation of the visible range spectra due to the unwanted grating second order of diffraction of the UV light.

Gas temperature is determined from the best fit between measured and calculated OH ( A 2 Σ + , v = 0 X 2 Π 3 / 2 , v = 0 ) molecular band since the rotation temperature is equivalent to the gas temperature. This is correct when the assumption of a quasi-instantaneous equilibrium between the rotation and the translation temperatures is fulfilled. The calculated or synthetic spectra are determined using Lifbase software [10] . A small amount of H2 was added in order to improve the sensitivity of the temperature measurements in the case of dry air. In other words, introducing a small percentage of H2 in the plasma is an efficient way to better observe the OH (A-X) spectrum. We have ensured that this small amount of H2 does not induce any effect on the thermal characteristics of the air plasma by observing the very good superposition of the NOg spectra of the air plasma column with and without this small amount of H2 (data not shown). The rotational temperature of the OH radical is assumed close to the gas temperature since the characteristic time of rotation-translation is very short. The relative uncertainty is estimated by varying the temperature of the simulated spectrum as long as the peak correlation remains upper than 0.97.

Figure 7 displays the measured OH (A-X) spectrum recorded on the axis of air plasma column at z = 15 mm (corresponding to the TALIF lower position of nitrogen TALIF measurements). The spectrum calculated for a rotational temprature of 4100 K gives the best agreement with the experimental one in the Figure 7. This peak correlation is then measured and, in this example, will amount to 0.98. The temperature relative uncertainty is estimated at 10%.

Figure 7. Comparison between experimental spectrum and calculated one for T r o t = 4100 K at the position of plasma column: r = 0 , z = 15 mm in the case of P M W = 1 kW , p = 600 mbar , inlet gas composition = Air + 3% H2 and Gas flow = 10 slm .

4. Results

4.1. N-TALIF Signal

For each considered ( r , z ) position along the air plasma column, the N-TALIF signal measurements are performed by scanning the laser wavelength near the two-photon resonance line of the 2 p 3 4 S 3 / 2 3 p 3 4 S 3 / 2 transition and recording the fluorescence of the 3 p 3 4 S 3 / 2 state at 745 nm. For high quenching rates, the effective life time of the 3 p 3 4 S 3 / 2 state is smaller than the laser pulse width. A low gate-time of integration is required to minimize the influence of the continuous background radiations from the plasma. The radiative decay is integrated over 50 ns after the laser pulse. The line profile is fitted by a Gaussian profile which corresponds to the convolution of a laser line profile and Doppler broadening (see Figure 8). The N-TALIF signal S N is given by integrating the line profile over the laser wavelength. The wavelength maximum position may slightly fluctuate due to variations of the temperature of the laser cavity.

The N-TALIF signal is proportional to the square of the laser pulse energy in the case of unsaturated excitation regime. Figure 9 shows the fluorescence signal integrated over the laser wavelength as a function of the laser energy. The energy variations were obtained by detuning the BBO crystal of the frequency doubled unit. The N-TALIF remains unsaturated for laser energies up to 50 mJ.

4.2. Temperature Effects

The effective branching ratio a 2 ( N ) can be calculated from the room temperature quenching coefficients and the measured gas temperature determined by fitting

Figure 8. Two-photon excitation spectra for the excitation of the N ground state at different laser pulse energies. The time integrated counts are averaged over 600 laser pulses. The detection volume is located at the center of the plasma ( r = 0 mm ) and at z = 15 mm from the nozzle of the microwave resonant cavity. Dry air flow q air = 10 slm , microwave power P M W = 1 kW , operating pressure p = 600 mbar .

Figure 9. TALIF signals (temporally and spectrally integrated) as a function of laser pulse energy squared. For N-TALIF, the detection volume is located at the center of the plasma ( r = 0 mm and at z = 15 mm of the nozzle of the microwave resonant cavity. Dry air flow q air = 10 slm , microwave power P M W = 1 kW , working pressure p = 600 mbar . For Kr-TALIF, the detection volume is also localized at ( r = 0 mm and at z = 15 mm in the plasma cell when the plasma is off (dry air flow q air = 10 slm with q Kr = 10 sccm , working pressure p = 600 mbar ). Kr-TALIF measurements were also achieved in a vacuum cell for Kr-air mixture ( p Kr = 0.6 mbar and p Tot = 600 mbar ).

the experimental spectra recorded in the range from 306 nm to 310 nm with synthetic spectra calculated using LifBase software [10] . Spectra were recorded along the axis of the air plasma column (Figure 10) and in the radial direction for different axial positions.

It is important to underline that the gas temperature in the case of humid air (50% of humidity) is higher than the case of dry air. For instance, at 600 mbar, the gas temperature on the axis at the output of the nozzle (i.e. r = 0 mm , z = 0 mm ) is equal to about 4500 K in dry air plasma and 6400 K in humid air plasma which corresponds to a rise of about 1900 K in presence of 50% of humidity. In fact in presence of water vapor, the plasma electronegativity becomes higher thus increasing the electron losses. In order to compensate such electron losses due to more particularly attachment processes, the electron energy deposit in the discharge (which takes place inside the resonant cavity), increases thus increasing in turn the gas heating. This can be assimilated to the known attachment heating that increases for instance the critical static electric field by about 10% in presence of humidity.

The dominant colliders responsible for the quenching of the laser excited N

Figure 10. Measured gas temperature along the axis of the air plasma column for synthetic air, dry air and humid air. Dry air flow q air = 10 slm , H2 flow q H 2 = 200 sccm , water flow q H 2 O = 18.5 g / h (50% humidity), microwave power P M W = 1 kW , working pressure p = 600 mbar .

Table 1. Radiative lifetimes and room temperature quenching coefficients of Kr ( 5 p [ 3 / 2 ] 2 ) and N ( 3 p 4 S 3 / 2 ) .

atoms are molecular oxygen and nitrogen. The quenching coefficients are given in Table 1 at room temperature and calculated using Equation (9) taking into account the radial and axial variations of temperature. The densities of both colliders are related to the gas temperature according the ideal gas law at constant pressure. In the plasma core, the dissociation degree of molecular oxygen may be high. The dissociation degree has been already estimated in a previous work [1] by atomic oxygen TALIF measurements using xenon calibration. This dissociation degree reaches a value which exceeds 50% in the axis of the plasma column at z = 15 mm from the nozzle (at z = 0 mm ) in the plasma column. The determination of the quenching rates is based on the assumption that the molecular oxygen density is directly correlated to the atomic oxygen density. This means that excited states of O2 are minority species relatively to the overall molecular oxygen densities. Based on these assumptions, and considering the plasma temperature and the quenching coefficients, the effective branching ratios a 2 ( N ) were determined at different axial and radial positions (Figure 11 and Figure 12).

4.3. In situ Calibration

The Kr calibration is performed in the gas-conditioning cell in the same experimental conditions as the N-TALIF measurements but without igniting the plasma (plasma off). Air mixed with a small known amount of krypton is introduced in the gas-conditioning cell using the same flow and pressure (10 slm and 600 mbar). The proportion of krypton (0.1%) was chosen to obtain the same order of magnitude for N-TALIF and Kr-TALIF signals. In the case of krypton, the linear regime is achieved when the laser energy is kept below 40 mJ to avoid

Figure 11. Branching ratio a 2 ( N ) in dry air. Dry air flow q air = 10 slm , microwave power P M W = 1 kW , working pressure p = 600 mbar .

Figure 12. Branching ratio a 2 ( N ) in humid air. Dry air flow q air = 10 slm , water flow q H 2 O = 18.5 g / h , microwave power P M W = 1 kW , working pressure p = 600 mbar .

multlphotonic ionization processes. The laser wavelength, tuned around 204.15 nm, is used to excite the krypton ground state to the 5 p [ 3 / 2 ] 2 state by a two-photon transition. The line profile is fitted by a Gaussian as shown in Figure 13. The Kr-TALIF signal S Kr is obtained by integrating the line profile over the laser wavelength.

Further Kr-TALIF measurements are achieved in a vacuum cell to relate the TALIF signals and to measure the effective branching ratio a 2 tacking into account the air and the krypton quenching. Before being filled with pure krypton or a mixture of synthetic air and krypton, the cell was pumped down to 5 × 10 7 mbar with a turbomolecular pump. Two capacitive pressure meters are used, one with a full range of 10 Torr for low pressure conditions and one with a full range of 1000 Torr for high pressure conditions. This experimental set-up has been fully described in a previous work [14] .

Firstly, measurements are performed in pure krypton at very low pressure when the self quenching of krypton can be neglected. This condition is fulfilled when the krypton pressure is kept below 0.1 mbar. For this pressure condition, the temporal decay of the excited state at 826.3 nm is exponential (Figure 14) and the measured decay rate is the inverse of the natural lifetime of the Kr 5 p [ 3 / 2 ] 2 state: τ n ( Kr ) = 34.1 ± 1.2 ns . This value is in agreement with what was measured by Niemi et al. [11] . For krypton pressures above 0.1 mbar, the fluorescence decay cannot be fitted by one exponential term. This is due to the emission line of the Kr 5 p [ 1 / 2 ] 1 at 828.1 nm and the emission of the Kr

Figure 13. Two-photon excitation spectra for the excitation of the Kr ground state at different laser pulse energies. The time integrated counts are averaged over 600 laser pulses. The detection volume is located at the center of the plasma cell ( r = 0 mm ) and at z = 20 mm . Plasma is off. Dry air flow q air = 10 slm with q Kr = 10 sccm , working pressure p = 600 mbar .

Figure 14. Fluorescence decay of the Kr 5 p [ 3 / 2 ] 2 state recorded in the vacuum cell.

5 p [ 3 / 2 ] 1 state at 829.8 nm which are also transmitted through the interferential filter. The Kr 5 p [ 1 / 2 ] 1 energy level is close to the energy level of the laser pumped state and is probably populated by collisional transfer process starting from the excited state. The observed 5 p [ 3 / 2 ] 1 population has been already observed by Chang et al. [12] following a selective excitation of Kr 5 p [ 3 / 2 ] 2 state in krypton argon mixtures. For Kr-TALIF signals measurements, we make sure that the the population of theses states by quenching can be neglected by keeping the krypton pressure below 0.1 mbar.

Secondly, Kr-TALIF measurements are performed in the vacuum cell with the same air-krypton mixture used in the gas-conditioning cell for calibration ( p = 600 mbar with 0.1% amount of krypton). For these conditions, only the emission at 826.3 nm is detected through the narrow band interferential filter. The ratio of the Kr-TALIF signals measured in pure krypton at very low pressure (=0.01 mbar) and in a air-krypton mixture give the effective branding ratio a 2 ( Kr ) required for calibration in the gas-conditioning cell. Taking into account the pure optical branching ratio given by Piracha et al. [15] a 20 ( Kr ) = 0.93 , the effective branching ratio used for calibration is a 2 ( Kr ) = 4.7 × 10 3 . This experimental value gives a qualitative indication of the quenching rate Q of the Kr 5 p [ 3 / 2 ] 2 state at 600 mbar in air + 0.1% Kr mixture. This value Q = 6.02 × 10 9 s 1 is relatively close to the one calculated from the quenching coefficients given by Niemi et al. [11] ( Q = 5.80 × 10 9 s 1 ).

4.4. Measurements of N (4S) Density in the Microwave Air Plasma Column

The absolute atomic density of nitrogen background state, calibrated in situ with krypton, is given by the ratio of the energy-normalized TALIF signals using Equation (10).

The ratio of the two photon excitation cross sections is σ ( 2 ) ( Kr ) σ ( 2 ) ( N ) = 0.67 with

an estimated uncertainty of 50% according Niemi et al. [11] . The laser excitation wavelengths are λ N = 206.673 nm and λ Kr = 204.150 nm . The count sensitivities of the PMT are nearly equal according to the specifications ( η ( N ) = 3.6 × 10 5 s 1 pW 1 , η ( Kr ) = 3.8 × 10 5 s 1 pW 1 ) and the measured transmissions of the interference filters are T ( N ) = 47 % and T ( Kr ) = 89 % . The two dimensional N-TALIF signals are measured as a function of the axial position with a step interval of 5 mm between 15 mm to 50 mm from the nozzle while the measurements are done along the radial position of air plasma column with a step of 1 mm. The resulting maps of the nitrogen density for a dry air flux and humid air flux are shown in Figure 15 and Figure 16. Reproducibility of the results over several days is better than 20% and the uncertainty of the absolute N-density measurements depends obviously first on the accuracy of the cross

section ratio σ ( 2 ) ( Kr ) σ ( 2 ) ( N ) which is close to 50%. For N-densities calculation, the

mapping of the a ( N ) branching ratio is taken into account. The accuracy of the absolute density measurement also depends on the accuracy of the branching ratios. Obviously, the assumptions made about the determination of the branching ratios necessarily impact the magnitude of density estimation. For example, if the oxygen dissociation is not taken into account, the N-density near the nozzle ( r = 0 mm , z = 15 mm ) is about three times higher. It is not excluded

Figure 15. Atomic nitrogen density (cm−3). Dry air flow q air = 10 slm , microwave power P M W = 1 kW , working pressure p = 600 mbar .

Figure 16. Atomic nitrogen density (cm−3). Dry air flow q air = 10 slm , water flow q H 2 O = 18.5 g / h , microwave power P M W = 1 kW , working pressure p = 600 mbar .

that N-density values are more or less underestimated because the calculations of the branching ratios a 2 ( N ) do not include the quenching of laser excited N atoms by O atoms or excited species like O2 metastable states. Thus, the relative uncertainties related to the nitrogen density are estimated about 30% without tacking into account the contribution of the cross section ratio. The relative uncertainties taking into account all contributions reach approximately 70%.

Figure 15 and Figure 16 show that the atomic nitrogen density is higher near the nozzle where the maximum gas temperature is measured: 1.6 × 10 15 cm 3 for humid air flux ( T g = 5400 K ) and 0.96 × 10 15 cm 3 for dry air flux ( T g = 4100 K ). The atomic density decreases slightly along the axis of the plasma column and more substantially along the radius.

From the knowledge of the previously measured N(4S) density and gas temperature it is possible to estimate the molecular nitrogen dissociation along the air plasma column using gas law state. Figure 17 displays the ratio between N(4S) density and N2(X) background gas along the z axis where radial position is equal to zero. It is noteworthy that:

・ N2(X) dissociation is more important in the case of humid air (about 5 times larger) even if it remains low (only 0.55% of dissociation for instance at position z = 15 mm of the air plasma column);

・ N2(X) dissociation decreases for increasing z position far from the nozzle due to the progressive gas plasma cooling which automatically leads to an increase of N2(X) density and in the same time to a decrease of N2(X) dissociation.

As expected, the measured N(4S) densities are maximal on the axis of the plasma column in the regions close to the nozzle where the temperature of the air plasma is higher. The obtained N(4S) density magnitudes are coherent with regard to temperature and pressure conditions considered in both dry and humid air. In addition, N(4S) density for instance on the position of axis r = 0

Figure 17. Ratio between N(4S) density and N2(X) background gas along the z axis for r = 0 mm .

and z = 15 mm ( n N = 3.0 × 10 15 cm 3 ) is much lower than N(4S) density calculated under thermodynamic equilibrium for the same temperature and pressure ( n N = 9.2 × 10 16 cm 3 ) . This means that the air plasma column behaves as a post-discharge when ejected from the resonant cavity. In fact, such an air plasma continually recombines and tries to relax towards its equilibrium state. The present results clearly show that no equilibrium states can be reached neither chemically since N(4S) density is different from its thermodynamic equilibrium value nor energetically.

5. Conclusion

Measurements of absolute density of atomic ground state Nitrogen (N4S) due to molecular nitrogen dissociation are performed for the first time in the literature along hot air plasma column. The latter is generated by a microwave resonant cavity at 2.45 GHz and 1 kW for injected power and 600 mbar for pressure inside the conditioning gas cell. Calibrated measurements based on TALIF laser diagnostics are done in both dry and humid air while the needed rotational temperature is estimated from OH (A-X) spectra measured using OES spectroscopy. The rotational temperatures in humid air plasma column (50% of humidity) are larger than those of dry air plasma column by practically 30% near the nozzle of resonant cavity on the axis of the plasma column. The advantage of the present work is to have set up specific experimental tool and methodology to measure the absolute density of atomic nitrogen in the hot air plasma with a good axial and radial spatial resolution. This allows to obtain the dissociation degrees of molecular nitrogen in both dry and humid air plasmas along the air plasma column. These gas dissociations are lower than those obtained when assuming thermodynamic and chemical equilibrium. This clearly characterizes the absence of chemical and energetic equilibriums that are not yet reached in the present air plasma column dominated by recombination processes.

Acknowledgements

The authors would like to thank CEA-DAM-DIF for the financial support of the plasma experimental setup.

Conflicts of Interest

The authors declare no conflicts of interest.

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