Citations: 1.) | Liu, Y., Li, Z., Yang, L., Nie, L., Liu, D., Lu, X., 2024. One‐Step Nitrogen Fixation by a Magnetic Field Stabilized Glow Discharge (MSGD) With Ethanol Solution and Nitrogen. Plasma Processes & Polymers e2400144. https://doi.org/10.1002/ppap.202400144 (2024) ------------- | 2.) | Bhat, S.K., Deepak, G.D., 2024. Predictive Modelling and Optimization of Double Ring Electrode Based Cold Plasma Using Artificial Neural Network. IJE 37, 83–93. https://doi.org/10.5829/IJE.2024.37.01A.08 (2024) ------------- | 3.) | Klimek, A., Piercey, D.G., 2024. Nitrogen Fixation via Plasma-Assisted Processes: Mechanisms, Applications, and Comparative Analysis—A Comprehensive Review. Processes 12, 786. https://doi.org/10.3390/pr12040786 (2024) ------------- | 4.) | Marcinauskas, L., Kavaliauskas, Ž., Jonynaitė, K., Uscila, R., Aikas, M., Keršulis, S., Strakšys, A., Stirkė, A., Stankevič, V., 2024. The Influence of Voltage on Gliding Arc Discharge Characteristics, the Composition of Air Plasma, and the Properties of BG-11 Medium. Applied Sciences 14, 2135. https://doi.org/10.3390/app14052135 (2024) ------------- | 5.) | Aceto, D., Ambrico, P.F., Esposito, F., 2024. Air cold plasmas as a new tool for nitrogen fixation in agriculture: underlying mechanisms and current experimental insights. Front. Phys. 12, 1455481. https://doi.org/10.3389/fphy.2024.1455481 (2024) ------------- | 6.) | Yu, S., Vervloedt, S.C.L., Keudell, A.V., 2024. Controlled synthesis of NO in an atmospheric pressure plasma by suppressing NO destruction channels by plasma catalysis. J. Phys. D: Appl. Phys. 57, 245203. https://doi.org/10.1088/1361-6463/ad2ef6 (2024) ------------- | 7.) | Lamichhane, P., Pourali, N., Rebrov, E.V., Hessel, V., 2024. Energy Intensified Nitrogen Fixation Through Fast Modulated Gas Discharge from Pyramid-shaped Micro-electrode. Plasma Chem Plasma Process 44, 1369–1392. https://doi.org/10.1007/s11090-023-10376-1 (2024) ------------- | 8.) | Tsonev, I., Ahmadi Eshtehardi, H., Delplancke, M.-P., Bogaerts, A., 2024. Importance of geometric effects in scaling up energy-efficient plasma-based nitrogen fixation. Sustainable Energy Fuels 8, 2191–2209. https://doi.org/10.1039/D3SE01615C (2024) ------------- | 9.) | Kumar, A., Avadhani, V.S., Nandy, A., Mondal, S., Pathak, B., Pavuluri, V.K.N., Avulapati, M.M., Banerjee, S., 2024. Water Microdroplets in Air: A Hitherto Unnoticed Natural Source of Nitrogen Oxides. Anal. Chem. 96, 10515–10523. https://doi.org/10.1021/acs.analchem.4c00371 (2024) ------------- | 10.) | Doshi, P., Scholtz, V., Oplíštilová, A., Khun, J., Klenivskyi, M., Julák, J., Šerý, M., Šerá, B., 2024. Effect of Transient Spark Discharge and Plasma Activated Water Treatments against Fusarium graminearum Infected Wheat Grains under Laboratory Conditions. Plasma Chem Plasma Process 44, 1689–1712. https://doi.org/10.1007/s11090-024-10479-3 (2024) ------------- | 11.) | Abdelaziz, A.A., Teramoto, Y., Kim, D.-Y., Nozaki, T., Kim, H.-H., 2024. Critical Considerations in Power Measurements for the Precise Estimation of Energy Costs in Plasma NOx Synthesis. Plasma Chem Plasma Process 44, 1493–1512. https://doi.org/10.1007/s11090-024-10472-w (2024) ------------- | 12.) | Klenivskyi, M., Khun, J., Thonová, L., Vaňková, E., Scholtz, V., 2024. Portable and affordable cold air plasma source with optimized bactericidal effect. Sci Rep 14, 15930. https://doi.org/10.1038/s41598-024-66017-w (2024) ------------- | 13.) | Panchal, D., Lu, Q., Sakaushi, K., Zhang, X., 2024. Advanced cold plasma-assisted technology for green and sustainable ammonia synthesis. Chemical Engineering Journal 498, 154920. https://doi.org/10.1016/j.cej.2024.154920 (2024) ------------- | 14.) | Green, G., Watanabe, N., 2024. Green Flashes Observed in Optical and Infrared during an Extreme Electric Storm. Applied Sciences 14, 6938. https://doi.org/10.3390/app14166938 (2024) ------------- | 15.) | Sterie, VA; Zhao, Y and Stancu, GD 2023 Nitric oxide generation by microwave capillary discharges under thermal control at atmospheric pressure; FRONTIERS IN PHYSICS 11:1188549; 10.3389/fphy.2023.1188549 (2023) ------------- | 16.) | Bas-Calopa, P; Riba, JR and Moreno-Eguilaz, M 2023 Analyzing the Effect of Dynamic Pressure Drop on Corona Discharges for Aircraft Applications; AEROSPACE 10:320; 10.3390/aerospace10030320 (2023) ------------- | 17.) | Abdelaziz, AA et al. 2023 Toward Reducing the Energy Cost of NOx Formation in a Spark Discharge Reactor through Pinpointing Its Mechanism; ACS SUSTAINABLE CHEMISTRY & ENGINEERING 11:4106-4118; 10.1021/acssuschemeng.2c06535 (2023) ------------- | 18.) | Li, Y et al. 2023 High efficiency NOx synthesis and regulation using dielectric barrier discharge in the needle array packed bed reactor; CHEMICAL ENGINEERING JOURNAL 461:141922; 10.1016/j.cej.2023.141922 (2023) ------------- | 19.) | Roy, NC et al. 2023 Mechanisms of reducing energy costs for nitrogen fixation using air-based atmospheric DBD plasmas over water in contact with the electrode; CHEMICAL ENGINEERING JOURNAL 461:141844; 10.1016/j.cej.2023.141844 (2023) ------------- | 20.) | Li, J., Lan, C., Nie, L., Liu, D., Lu, X., 2023. Distributed plasma-water-based nitrogen fixation system based on cascade discharge: Generation, regulation, and application. Chemical Engineering Journal 478, 147483. https://doi.org/10.1016/j.cej.2023.147483 (2023) ------------- | 21.) | Li, Z., Wu, E., Nie, L., Liu, D., Lu, X., 2023. Magnetic field stabilized atmospheric pressure plasma nitrogen fixation: Effect of electric field and gas temperature. Physics of Plasmas 30, 083502. https://doi.org/10.1063/5.0155713 (2023) ------------- | 22.) | Wang, J., Zhang, B., Liu, Y., Ru, Q., Cao, H., Zhu, Y., Li, S., Zhang, Z., Cheng, G., Du, Z., 2023. Efficient N2 fixation in air enabled by mechanical-energy-driven triboelectric plasma jet. Chem Catalysis 3, 100647. https://doi.org/10.1016/j.checat.2023.100647 (2023) ------------- | 23.) | Miao, Y., Yokochi, A., Jovanovic, G., Zhang, S., Von Jouanne, A., 2023. Application-oriented non-thermal plasma in chemical reaction engineering: A review. Green Energy and Resources 1, 100004. https://doi.org/10.1016/j.gerr.2023.100004 (2023) ------------- | 24.) | Zhou, X.-F., Xiang, H.-F., Yang, M.-H., Geng, W.-Q., Liu, K., 2023. Temporal evolution characteristics of the excited species in a pulsed needle-water discharge: effect of voltage and frequency. J. Phys. D: Appl. Phys. 56, 455202. https://doi.org/10.1088/1361-6463/acec81 (2023) ------------- | 25.) | Abdelaziz, A.A., Teramoto, Y., Nozaki, T., Kim, H.-H., 2023. Performance of high-frequency spark discharge for efficient NO production with tunable selectivity. Chemical Engineering Journal 470, 144182. https://doi.org/10.1016/j.cej.2023.144182 (2023) ------------- | 26.) | X. Y. Lei, H. Cheng, L. L. Nie, X. P. Lu: Nitrogen Fixation as NOx Enabled by a Three Level Coupled Rotating Electrodes Air Plasma at Atmospheric Pressure, Plasma Chem. Plasma Process. X, xxx (2022), citation no. 25, INDEX (2022) ------------- | 27.) | D. Li, L. Zan, S. Chen, Z.–J. Shi, P. Chen, Z. Xi, D. Deng: Direct conversion of N2 and O2: Status, challenge, and perspective X, xxx (2022), citation no. 28, INDEX (2022) ------------- | 28.) | L. Hollevoet, E. Vervloessem,Y. Gorbanev, A. Nikiforov, N. De Geyter, A. Bogaerts, J. A Martens: Energy-efficient Small-scale Ammonia Synthesis Process with Plasma-enabled Nitrogen Oxidation and Catalytic Reduction of Adsorbed NOx, Chem. Sus. Chem. X, 20210252 (2022), citation no. 21, INDEX (2022) ------------- | 29.) | V. Rathore, S. K. Nema: A comparative study of dielectric barrier discharge plasma device and plasma jet to generate plasma activated water and post-discharge trapping of reactive species, Phys. Plasmas 29, 033510 (2022), citation no. 22, INDEX (2022) ------------- | 30.) | Landl, NV et al 2022 Production of nitrogen oxides in a positive column of a glow-type discharge in air flow, PLASMA CHEMISTRY AND PLASMA PROCESSING 42:1187-1200, 10.1007/s11090-022-10262-2 (2022) ------------- | 31.) | Shao, KT et al. 2022 Active learning-guided exploration of parameter space of air plasmas to enhance the energy efficiency of NOx production, PLASMA SOURCES SCIENCE & TECHNOLOGY 31:055018, 10.1088/1361-6595/ac6e04 (2022) ------------- | 32.) | Riba, JR 2022 Spectrum of Corona Discharges and Electric Arcs in Air under Aeronautical Pressure Conditions, AEROSPACE 9:524, 10.3390/aerospace9090524 (2022) ------------- | 33.) | Xu Y. et al 2022 Effects of contact glow discharge plasma and seed treatment methodology on alfalfa seed germination [接触辉光放电等离子体对紫花苜蓿种子萌发的促进作用及处理工艺] Journal of Radiation Research and Radiation Processing, 40 (3), art. no. 030401, DOI: 10.11889/j.1000-3436.2021-0305 (2022) ------------- | 34.) | X. Y. Dong, X. Y Ren, J. Wang: Interaction of air cold plasma with Saccharomyces cerevisiae in the multi-scale microenvironment for improved ethanol yield, Bioresource Technology 323, 124621 (2021), citation no. X, WoS (2021) ------------- | 35.) | H. Chen, A. Wu, S. Mathieu, P. Gao, X. Li, B. Z. Xu, J. Yan, X. Tu: Highly efficient nitrogen fixation enabled by an atmospheric pressure rotating gliding arc, Plasma Process Polym. X, e2000200 (2021), citation no. 39, WoS (2021) ------------- | 36.) | K. H. R. Rouwenhorst, F. Jardali, A. Bogaerts, L. Lefferts: From the Birkeland-Eyde process towards energy-efficient plasma-based NOX synthesis: a techno-economic analysis, Energy Environm. Sci. X, xxx (2021), citation no. 40, WoS (2021) ------------- | 37.) | H. Chen, D. Yuan, A. Wu,X. Lin, X. Li: Review of low-temperature plasma nitrogen fixation technology, Waste Dispos Sustain Energy X, xxx (2021), citation no. 83, INDEX (2021) ------------- | 38.) | N. Britun, V. Gamaleev, M. Hori: Evidence of near-the-limit energy cost NO formation in atmospheric spark discharge, Plasma Sources Sci. Technol. X, xxx (2021), citation no. X, INDEX (2021) ------------- | 39.) | M.-H. Hsueh, C.-J. Lai, M.-C. Hsieh, S.-H. Wang, C.-H. Hsieh, C.-Y. Pan, W.-C. Huang: Effect of Water Vapor Injection on the Performance and Emissions Characteristics of a Spark-Ignition Engine, Sustainability 13, 9229 (2021), citation no. 27, WoS (2021) ------------- | 40.) | C. Lu, X. Chen, Y. Wang, Y. Zhu, Z. Zou, Z. Xiong: Effect of dielectric parameters on the transformation of operation mode and the energy cost of nitrogen fixation ofsurface microdischarge in air, Plasma Process Polym. X, e2100107 (2021), citation no. 29, INDEX (2021) ------------- | 41.) | M. Arcanjo, J. Montanyà, M. Urbani, V. Lorenzo: Optical Signatures Associated With Streamers and Leaders of Laboratory Discharges, Geophys. Research Lett. X, xxx (2021), citation Janda, INDEX (2021) ------------- | 42.) | D. Chen, Y. Peng, X. Gao, Z. Hou: Effects of the N2 to O2 ratio in air on the removal rate and the degree of decomposition of 2-chloroethyl ethyl sulphide by atmospheric plasma, J. Environ. Chem. Engineer. 9 (6), 106776 (2021), citation no. 19, WoS (2021) ------------- | 43.) | X. Lei, H. Cheng, L. Nie, Y. Xian, X.P. Lu: Plasma-catalytic NOx production in a three-level coupled rotating electrodes air plasma combined with nano-sized TiO2, J. Phys. D. Appl. Phys. X, xxx (2021), citation no. X, INDEX (2021) ------------- | 44.) | S. R. Noh, W. Jung, S. Chae, B. Han, J. Lee, C. G. Woo: Control of the size of nanoparticles by spark discharge with an atomizer and a bubbler, Aerosol Sci. Technol. X, xxx (2022), citation no. X, INDEX (2021) ------------- | 45.) | Zabidi N.Z.A. et al 2021 A Brief Review on Atmospheric Air Plasma, Journal of Physics: Conference Series, 2071 (1), art. no. 012004, DOI: 10.1088/1742-6596/2071/1/012004 (2021) ------------- | 46.) | I. Jõgi, K. Erme, J. Raud, S. Raud: The Effect of TiO2 Catalyst on Ozone and Nitrous Oxide Production by Dielectric Barrier Discharge, Catalysis Letters 150, 992–997 (2020), citation no. 5, WoS (2020) ------------- | 47.) | X. Pei, D. Gidon, D. B. Graves: Specific energy cost for nitrogen fixation as NOx using DC glow discharge in air, J. Phys. D: Appl. Phys. 53 (4), 044002 (2020), citation no. 16, WoS (2020) ------------- | 48.) | J. Li, S. L. Yao, Z. L. Wu: NOx production in plasma reactors by pulsed spark discharges, J. Phys. D. Appl. Phys. 53 (38), 385201 (2020), citation no. 16, WoS (2020) ------------- | 49.) | N. C. Roy, C. Pattyn, A. Remy, N. Maira, F. Reniers: NOx synthesis by atmospheric‐pressure N2/O2 filamentary DBD plasma over water: Physicochemical mechanisms of plasma–liquid interactions, Plasma Process. Polym. X, xxx (2020), citation no. 26, WoS (2020) ------------- | 50.) | T. Liu, Y. Zeng , J. Chen, D. Wei, Q. Zeng, Y. Fu, Y. Fu, F. Yang, F. Feng: Acinetobacter Baumannii Sterilization Using DC Corona Discharge, IEEE Trans. Plasma Sci. 49 (1), 317-325 (2020), citation no. 38, WoS (2020) ------------- | 51.) | J. Pawłat, P. Terebun, M. Kwiatkowski, K. Wolny-Koładka: Possibility of Humid Municipal Wastes Hygienisation Using Gliding Arc Plasma Reactor, Water 13, 194 (2021), citation no. 3, WoS (2020) ------------- | 52.) | N. K. Kaushik, B. Ghimire, Y. Li, M. Adhikari, M. Veerana, N. Kaushik, N. Jha, B. Adhikari, S.-J. Lee, K. Masur, T. von Woedtke, K.-D. Weltmann, E. H. Choi: Biological and medical applications of plasma-activated media, water and solutions, Biol. Chem. 400 (1), 39-62 (2019), citation Janda, WoS (2019) ------------- | 53.) | E. Acayanka, J.‑B. Tarkwa, S. Laminsi: Evaluation of Energy Balance in a Batch and Circulating Non‑thermal Plasma Reactors During Organic Pollutant Oxidation in Aqueous Solution, Plasma Chem. Plasma Proc. 39, 75-87 (2019), citation no. 29, SCOPUS, WoS (2019) ------------- | 54.) | X. Pei, D. Gidon, Y-J. Yang, Z. Xiong, D.B. Graves: Reducing Energy Cost of NOx Production in Air Plasmas, Chem. Engineer. J. 53(4), 217-228 (2019), citation no. 30, WoS (2019) ------------- | 55.) | K. Erme, I. Jõgi: The effect of catalyst on ozone and nitrous oxide production in dielectric barrier discharge, 22nd Symposium on Application of Plasma Processes and 11th EU-Japan Joint Symposium on Plasma Processing SAPP XXII, Štrbské Pleso, January 18-24, pp. 298-301, citation no. 4 (2019) ------------- | 56.) | R. J. Wandell, H. Wang, R. K. M. Bulusu, R. O. Gallan, B. R. Locke: Formation of Nitrogen Oxides by Nanosecond Pulsed Plasma Discharges in Gas–Liquid Reactors, Plasma Chem. Plasma Process. 39 (3), 643-666 (2019), citation no. 71, WoS (2019) ------------- | 57.) | H. Dai, L. Li, H. Wu, J. Xiong, T. Shao, C. Zhang: Characteristics of N2/O2 reaction in spark gap switch: The effect of high-current pulsed arc, IEEE Trans. Dielect. Electric. Insul. 26 (2) 492-500 (2019), citation no. 13, WoS (2019) ------------- | 58.) | P. Peng, C. Schiappacasse, N. Zhou, M. Addy, Y. Cheng, Y. Zhang, K. Ding, Y. Wang, P. Chen, R. Ruan: Sustainable non-thermal plasma-assisted nitrogen fixation - Synergistic catalysis, Chem. Sus. Chem. 12, 3702-3712 (2019), citation no. 51, WoS (2019) ------------- | 59.) | Y. D. Korolev, V. O. Nekhoroshev, O. B. Frants, N. V. Landl, I. Suslov. V. Bolotov: Features of the Current Sustainment in a Low-Current Discharge in Airflow, Plasma Chem. Plasma Process 39 (6), 1519-1532 (2019), citation no. 32, WoS (2019) ------------- | 60.) | X. He, Y. Zeng, J. Chen, F. Wang, Y. Fu, F. Feng, H. Huang: Role of O3 in the removal of HCHO using a DC streamer plasma, J. Phys. D. Appl. Phys. 52(46), 465203 (2019), citation no. 26, WoS (2019) ------------- | 61.) | K. Tachibana, T. Nakamura: Comparative study of discharge schemes for production rates and ratios of reactive oxygen and nitrogen species in plasma activated water, J. Phys. D. Appl. Phys. 52, 385202 (2019), citation no. 38, WoS (2019) ------------- | 62.) | R. Bálek, M. Klenivsky: DC-driven atmospheric pressure pulsed discharge with volume-distributed filaments in a coaxial electrode system, J. Appl. Phys. 126, 083301 (2019), citation no. 13, WoS (2019) ------------- | 63.) | J. Jo, Q. Hung Trinh, S. H. Kim, Y. S. Mok: Plasma-catalytic decomposition of nitrous oxide over γ-alumina-supported metal oxides, Catalysis Today 310, 42-48 (2018), citation no. 24, INDEX (2018) ------------- | 64.) | J. Pawlat, A. Starek, A. Sujak, M. Kwiatkowski, P. Terebun, M. Budzeń: Effects of atmospheric pressure plasma generated in GlidArc reactor on Lavatera thuringiaca L. seeds’ germination, Plasma Process. Polym. 15, e170006 (2018), citation no. 21, INDEX (2018) ------------- | 65.) | J. Pawłat, A. Starek, A. Sujak, P. Terebun, M. Kwiatkowski, M. Budzeń, D. Andrejko: Effects of atmospheric pressure plasma jet operating with DBD on Lavatera thuringiaca L. seeds germination, PLoS ONE 13 (4), e0194349 (2018), citation no. 19, WoS (2018) ------------- | 66.) | L. Scally, J. Lalor, M. Gulan, P. Cullen, V. Milosavljevic: Spectroscopic study of excited molecular nitrogen generation due to interactions of metastable noble gas atoms, Plasma Process. Polym. 15, e1800018 (2018), citation no. 28, INDEX (2018) ------------- | 67.) | R. Bálek, S. Pekárek: Acoustic waves effect on the generation of nitrogen oxides by corona discharge in air, J. Phys. D.: Appl. Phys. 27, 075019 (2018), citation no. 6, INDEX (2018) ------------- | 68.) | S. Li, J. A. Medrano, V. Hessel, F. Gallucci: Recent Progress of Plasma-Assisted Nitrogen Fixation Research: A Review, Processes 2018, 6 (12), 248 (2018), citation no. 73, WoS (2018) ------------- | 69.) | H. Dai, L. Li, M.-Y. Peng, H. Wu, J. Xiong, B. Yu, T. Shao, C. Zhang: Study on the Reaction of Oxygen and Nitrogen under the Effect of Intense Pulsed Arc in Gap Switch, IEEE International Power Modulator and High Voltage Conference (IPMHVC) New York: IEEE, 2018; 95-98 ; CPCI-S ; SCOPUS (2018) ------------- | 70.) | J. Pawłat , J. Diatczyk , B. Gunaydin-Dasan , B. Onal-Ulusoy , Y. Sun Mok: Mini glide-arc plasma reactor for biological decontamination, Eur. J. Medical Technol. 1 (14) 29-32 (2017), citation no. 12 (2017) ------------- | 71.) | I. E. Vlad, S. D. Anghel: Time stability of water activated by different on-liquid atmospheric pressure plasmas, J. Electrostat. 87, 284-292 (2017), citation no. 8, WoS (2017) ------------- | 72.) | S. Pekarek: Experimental Study of Nitrogen Oxides and Ozone Generation by Corona-Like Dielectric Barrier Dischargewith Airflow in a Magnetic Field, Plasma Chem Plasma Process 37(5), 1313-1330 (2017), citation no. 4, WoS (2017) ------------- | 73.) | K. Wolny-Koładka, J. Pawlat, P. Terebun, M. Kwiatkowski, J. Diatczyk: Ocena możliwości zastosowania plazmy niskotemperaturowej w celu higienizacji zmieszanych odpadów komunalnych służących do produkcji paliwa alternatywnego, Przeglad Elektrotechniczny 93, 209-213 (2017), citation no. 10, INDEX (2017) ------------- | 74.) | M. Kopacki, A. Starek, P. Kiczorowski, J. Pawlat, J. Diatczyk: Efficacy of Ozone Fumigation to Control Eupteryx Decemnotata in Rosemary Growing Under Cover, IEEE, 10th International Conference Electromagnetic Devices and Processes in Environment Protection + 13th Seminar "Applications of Superconductors" (ELMECO & AOS), Nałęczów (Poland), December 3-6 (2017), citation no. 19, WoS (2017) ------------- | 75.) | J. Pawlat, P. Terebun, M. Kwiatkowski, A. Starek, P. Kiczorowski, D. Andrejko, M. Kopacki: Effects of Helium-Air RF Plasma Jet on Onion Seeds’ Germination, 9th International Conference Electromagnetic Devices and Processes in Environment Protection ELMECO-9 + 12th Seminar "Applications of Superconductors" AoS-12, Nałęczów (Poland), December 3-6 (2017), citation no. 13, WoS (2017) ------------- | 76.) | J. Pawlat, P. Terebun, M. Kwiatkowski, B. Chudzik, M. Gagos: Candida Albicans Inactivation with DBD He/O2 Plasma Jet, 9th International Conference Electromagnetic Devices and Processes in Environment Protection ELMECO-9 + 12th Seminar "Applications of Superconductors" AoS-12, Nałęczów (Poland), December 3-6 (2017), citation no. 5, WoS (2017) ------------- | 77.) | M. A. Malik: Nitric Oxide Production by High Voltage Electrical Discharges for Medical Uses: A Review, Plasma Chem. Plasma Process. 36, 737-766 (2016), cit. 31, WoS/SCOPUS (2016) ------------- | |