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Soğuk Plazma Teknolojisi ve Tarımdaki Çeşitli Uygulama Alanları

Yıl 2021, Cilt: 35 Sayı: 1, 217 - 245, 01.06.2021

Öz

Maddenin katı, sıvı ve gaz halinden farklı, kendine özgü özellikleri ile uzun zamandır kullanılan plazma
terimi, kısaca “iyonize olmuş gaz” olarak tanımlanmaktadır. Bir gazın ısıltılmaya devam etmesi sonucunda
gerçekleşen sıralı reaksiyonlar ile oluşan iyon, elektron ve nötr atom karışımı, plazmanın temel bileşenlerini
oluşturmaktadır. Ayrıca plazma içerisinde; fotonlar, elektronlar, serbest radikaller ve nötral atomların yanısıra
kovalent bağları parçalamakla görevli, yeterli elektrik enerjisine sahip reaktif türler de bulunmaktadır. Plazma
sistemleri; termodinamik özelliklerine (yüksek ve düşük sıcaklık) ve çalışma basınçlarına (düşük basınç ve
atmosferik basınç) göre sınıflandırılmaktadır. Düşük sıcaklık plazmaları arasında en yeni teknolojilerden olan
soğuk plazma teknolojisi; belirli bir vakum altında ve oda sıcaklığında bulunan gazların, belirli bir elektrik akımı veya elektromanyetik radyasyon uygulaması sonucunda oluşturulan plazma olarak tanımlanmaktadır. Soğuk plazma; etki mekanizmalarının çeşitliliği ve diğer teknolojiler ile birleştirilebilmesini sağlayan uygulama esnekliği sayesinde, doğa ve yaşam bilimleri için yenilikçi, çevre dostu ve ekonomik çözümlerin sunulmasında zengin bir biyoteknolojik kaynaktır. Özellikle son yirmi yıldır soğuk plazma teknolojisi, etki mekanizmasını oluşturan reaktif türlerin biyolojik sistemlerle etkileşime geçebilmesinden dolayı tıp, medikal, çevre, tarım ve gıda gibi alanlarda karşılaşılan problemler için alternatif çözüm önerileri sunmaktadır. Gerçekleştirilen bu derlemede, soğuk plazma teknolojisinin tarım ve bitkisel uygulama olanlarından olan tohum çimlenmesi, tohum dekontaminasyonu, toprak zenginleştirilmesi ve plazma aktif su konuları üzerine yoğunlaşmıştır ve ayrıca in vitro koşullarda bitkisel materyal üzerine olan etkilerinden de bahsedilmiştir.

Kaynakça

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Cold Plasma Technology and Various Applications Areas In Plants

Yıl 2021, Cilt: 35 Sayı: 1, 217 - 245, 01.06.2021

Öz

Different from the solid, liquid and gaseous state of the matter, the term plasma, which has been used
for a long time by its unique properties, is briefly defined as “ionized gas”. The mixture of ions, electrons and
neutral atoms formed by sequential reactions that occur as a result of the heating of a gas constitutes the basic components of the plasma. There are also photons, electrons, free radicals and neutral atoms in the plasma, as well as reactive species with sufficient electrical energy, which are responsible for breaking down covalent bonds. Plasma systems; thermodynamic properties (high temperature and low temperature) and operating pressures (low pressure and atmospheric pressure). Cold plasma technology, one of the newest technologies among low temperature plasmas; is defined as the plasma produced by the application of a certain electric current or electromagnetic radiation of gases present under a certain vacuum and at room temperature. Cold plasma; It is a generous biotechnological resource in the provision of innovative, environmentally friendly and economical solutions for the natural and life sciences, thanks to the variety of its mechanisms of action and its flexibility in application which allows it to be combined with other technologies. Especially in the last two decades, cold plasma technology offers alternative solutions for problems encountered in medicine, medical, environment, agriculture and food, because of reactive species that make up the mechanism of action can interact with biological systems. In this review, agricultural applications of cold plasma, seed germination and seed decontamination, soil enrichment, plasma active water applications and also effects of plasma on plant material in vitro are discussed.

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  • Redolfi, M., Makhloufi, C., Ognier, S. and Cavadias, S. 2010. Oxidation of kerosene components in a soil matrix by a dielectric barrier discharge reactor. Process Safety and Environmental Protection, 88(3), 207-212.
  • ReynaMartinez, R., Cespedes, R.N., Alonso, M.I. and Acosta, Y.R. 2018. Use of Cold Plasma Technology in Biomaterials and Their Potential Utilization in Controlled Administration of Active Substances. Journal Material Science, 4(5). 555649.
  • Safari, N., Iranbakhsh, A. and Ardebili, Z.O. 2017. Non-thermal plasma modified growth and differentiation process of Capsicum annuum PP805 Godiva in in vitro conditions. Plasma Science and Technology, 19(5), 055501.
  • Sarangapani, C., Patange, A., Bourke, P., Keener, K. and Cullen, P.J. 2018. Recent advances in the application of cold plasma technology in foods. Annual Review of Food Science and Technology, 9, 609-629.
  • Schnabel, U., Niquet, R., Krohmann, U., Winter, J., Schlüter, O., Weltmann, K.D. and Ehlbeck, J. 2012. Decontamination of microbiologically contaminated specimen by direct and indirect plasma treatment. Plasma Processes and Polymers, 9(6), 569-575.
  • Será, B., Stranák, V., Serý, M., Tichý, M. and Spatenka, P. 2008. Germination of Chenopodium album in response to microwave plasma treatment. Plasma Science and Technology, 10(4), 506.
  • Será, B., Spatenka, P., Sery, M., Vrchotová, N. and Hruskova, I. 2010. Influence of plasma treatment on wheat and oat germination and early growth. IEEE Transactions on Plasma Science, 38(10), 2963-2968.
  • Será B. and Serý M. 2018. Non-thermal plasma treatment as a new biotechnology in relation to seeds, dry fruits, and grains. Plasma Science and Technology, 20(4), 044012.
  • Será, B., Zahoranová, A., Bujdáková, H. and Šerý, M. 2019. Disinfection from pine seeds contaminated with Fusarium circinatum Nirenberg & O’Donnell using non-thermal plasma treatment. Romanian Reports in Physics, 71, 701.
  • Shen, J., Tian, Y., Li, Y., Ma, R., Zhang, Q., Zhang, J. and Fang, J. 2016. Bactericidal Effects against S. aureus and Physicochemical Properties of Plasma Activated Water stored at different temperatures. Scientific Reports, 6, 28505.
  • Šimončicová, J., Kaliňáková, B., Kováčik, D., Medvecká, V., Lakatoš, B., Kryštofová, S., Hoppanová, l., Palušková, V., Hudecová, D., Durina, P. and Zahoranová, A. 2018. Cold plasma treatment triggers antioxidative defense system and induces changes in hyphal surface and subcellular structures of Aspergillus flavus. Applied Microbiology and Biotechnology, 102(15), 6647-6658Singh, C. R., 2018, Review on problems and its remedy in plant tissue culture, Asian Journal of Biological Sciences, 11, 165-172 pp.
  • Singh, H., Jassal, R.K., Kang, J.S., Sandhu, S.S., Kang, H. and Grewal, K. 2015. Seed priming techniques in field crops-A review. Agricultural Reviews, 36(4).
  • Singh, S., Chandra, R., Tripathi, S., Rahman, H., Tripathi, P., Jain, A. and Gupta, P. 2014. The bright future of dentistry with cold plasma—review. J Dent Med Sci, 13, 6-13.
  • Sivachandiran, L. and Khacef, A. 2017. Enhanced seed germination and plant growth by atmospheric pressure cold air plasma: combined effect of seed and water treatment. RSC Advances, 7(4), 1822-1832.
  • Štěpánová, V., Slavíček, P., Kelar, J., Prášil, J., Smékal, M., Stupavská, M., Jurmanova, J and Černák, M. 2018. Atmospheric pressure plasma treatment of agricultural seeds of cucumber (Cucumis sativus L.) and pepper (Capsicum annuum L.) with effect on reduction of diseases and germination improvement. Plasma Processes and Polymers, 15(2), 1700076.
  • Stolárik, T., Henselová, M., Martinka, M., Novák, O., Zahoranová, A. and Černák, M. 2015. Effect of low-temperature plasma on the structure of seeds, growth and metabolism of endogenous phytohormones in pea (Pisum sativum L.). Plasma Chemistry and Plasma Processing, 35(4), 659-676.
  • Stryczewska, H.D., Ebihara, K., Takayama, M., Gyoutoku, Y. and Tachibana, M. 2005. Non‐Thermal Plasma‐ Based Technology for Soil Treatment. Plasma Processes and Polymers, 2(3), 238-245.
  • Stryczewska, H.D., Pawłat, J. and Ebihara, K. 2013. Non-thermal plasma aided soil decontamination. Journal of Advanced Oxidation Technologies, 16(1), 23-30.
  • Thirumdas, R. 2018. Exploitation of cold plasma technology for enhancement of seed germination. Agri. Res. Tech, 13, 1-4.
  • Thirumdas, R., Kothakota, A., Annapure, U., Siliveru, K., Blundell, R., Gatt, R. and Valdramidis, V.P. 2018. Plasma activated water (PAW): chemistry, physico-chemical properties, applications in food and agriculture. Trends in Food Science & Technology, 77, 21-31.
  • Thomas-Popo, E., Mendonça, A., Misra, N.N., Little, A., Wan, Z., Moutiq, R., Coleman, S. and Keener, K. 2019. Inactivation of Shiga-toxin-producing Escherichia coli, Salmonella enterica and natural microflora on tempered wheat grains by atmospheric cold plasma. Food Control, 104, 231-239.
  • Tolouie, H., Mohammadifar, M.A., Ghomi, H. and Hashemi, M. 2018. Cold atmospheric plasma manipulation of proteins in food systems. Critical Reviews in Food Science And Nutrition, 58(15), 2583-2597.
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  • Volkov, A.G., Xu, K.G. and Kolobov, V.I. 2017. Cold plasma interactions with plants: Morphing and movements of Venus flytrap and Mimosa pudica induced by argon plasma jet. Bioelectrochemistry, 118, 100-105.
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  • Wang, T., Ren, J., Qu, G., Liang, D. and Hu, S. 2016. Glyphosate contaminated soil remediation by atmospheric pressure dielectric barrier discharge plasma and its residual toxicity evaluation. Journal of Hazardous Materials, 320, 539-546.
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  • Whitehead, J.C. 2016. The Chemistry of Cold Plasma: Cold Plasma in Food and Agriculture: Fundamentals and Applications, Ed: Misra, N.N., Schlüter, O.K., Cullen, P.J., Academic Press, Elsevier, London, United Kingdom, pp: 53-78.
  • Xiang, Q., Liu, X., Liu, S., Ma, Y., Xu, C. and Bai, Y. 2019. Effect of plasma-activated water on microbial quality and physicochemical characteristics of mung bean sprouts. Innovative Food Science & Emerging Technologies, 52, 49-56.
  • Yodpitak, S., Mahatheeranont, S., Boonyawan, D., Sookwong, P., Roytrakul, S. and Norkaew, O. 2019. Cold plasma treatment to improve germination and enhance the bioactive phytochemical content of germinated brown rice. Food chemistry, 289, 328-339.
  • Yüksel Ç.Y. ve Karagözlü, N. 2017. Soğuk Atmosferik Plazma Teknolojisi ve Gıdalarda Kullanımı. Adnan Menderes Üniversitesi Ziraat Fakültesi Dergisi, 14(2), 81-86.
  • Zahoranová, A., Henselová, M., Hudecová, D., Kaliňáková, B., Kováčik, D., Medvecká, V. and Černák, M. 2016. Effect of cold atmospheric pressure plasma on the wheat seedlings vigor and on the inactivation of microorganisms on the seeds surface. Plasma Chemistry and Plasma Processing, 36(2), 397-414.
  • Zhan, J., Liu, Y., Cheng, W., Zhang, A., Li, R., Li, X., Ognier, S., Cai, S., Yhang, C. and Liu, J. 2018. Remediation of soil contaminated by fluorene using needle-plate pulsed corona discharge plasma. Chemical Engineering Journal, 334, 2124-2133.
  • Zhang, H., Ma, D., Qiu, R., Tang, Y. and Du, C. 2017a. Non-thermal plasma technology for organic contaminated soil remediation: A review. Chemical Engineering Journal, 313, 157-170.
  • Zhang, S., Rousseau, A. and Dufour, T. 2017b. Promoting lentil germination and stem growth by plasma activated tap water, demineralized water and liquid fertilizer. RSC Advances, 7(50), 31244-31251.
  • Zheng, Y., Wu, S., Dang, J., Wang, S., Liu, Z., Fang, J., Han, P. and Zhang, J. 2019. Reduction of phoxim pesticide residues from grapes by atmospheric pressure non-thermal air plasma activated water. Journal of Hazardous Materials, 377, 98-105.
  • Ziuzina, D., Patil, S., Cullen, P.J., Keener, K.M. and Bourke, P. 2014. Atmospheric cold plasma inactivation of Escherichia coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes inoculated on fresh produce. Food Microbiology, 42, 109-11.
Toplam 126 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Çevresel Olarak Sürdürülebilir Mühendislik
Bölüm Derleme
Yazarlar

Hacer Kandemir 0000-0001-9220-1317

Fulya Aydın 0000-0001-5101-6406

Begüm Güler 0000-0002-9970-2111

Aynur Gürel 0000-0002-7002-9752

Yayımlanma Tarihi 1 Haziran 2021
Gönderilme Tarihi 3 Mart 2020
Yayımlandığı Sayı Yıl 2021 Cilt: 35 Sayı: 1

Kaynak Göster

APA Kandemir, H., Aydın, F., Güler, B., Gürel, A. (2021). Soğuk Plazma Teknolojisi ve Tarımdaki Çeşitli Uygulama Alanları. Bursa Uludağ Üniversitesi Ziraat Fakültesi Dergisi, 35(1), 217-245.

TR Dizin kriterleri gereği dergimize gönderilecek olan makalelerin mutlaka aşağıda belirtilen hususlara uyması gerekmektedir.

Tüm bilim dallarında yapılan, ve etik kurul kararı gerektiren klinik ve deneysel insan ve hayvanlar üzerindeki çalışmalar için ayrı ayrı etik kurul onayı alınmış olmalı, bu onay makalede belirtilmeli ve belgelendirilmelidir.
Makalelerde Araştırma ve Yayın Etiğine uyulduğuna dair ifadeye yer verilmelidir.
Etik kurul izni gerektiren çalışmalarda, izinle ilgili bilgiler (kurul adı, tarih ve sayı no) yöntem bölümünde ve ayrıca makale ilk/son sayfasında yer verilmelidir.
Kullanılan fikir ve sanat eserleri için telif hakları düzenlemelerine riayet edilmesi gerekmektedir.
Makale sonunda; Araştırmacıların Katkı Oranı beyanı, varsa Destek ve Teşekkür Beyanı, Çatışma Beyanı verilmesi.
Etik Kurul izni gerektiren araştırmalar aşağıdaki gibidir.
- Anket, mülakat, odak grup çalışması, gözlem, deney, görüşme teknikleri kullanılarak katılımcılardan veri toplanmasını gerektiren nitel ya da nicel yaklaşımlarla yürütülen her türlü araştırmalar
- İnsan ve hayvanların (materyal/veriler dahil) deneysel ya da diğer bilimsel amaçlarla kullanılması,
- İnsanlar üzerinde yapılan klinik araştırmalar,
- Hayvanlar üzerinde yapılan araştırmalar,
- Kişisel verilerin korunması kanunu gereğince retrospektif çalışmalar,
Ayrıca;
- Olgu sunumlarında “Aydınlatılmış onam formu”nun alındığının belirtilmesi,
- Başkalarına ait ölçek, anket, fotoğrafların kullanımı için sahiplerinden izin alınması ve belirtilmesi,
- Kullanılan fikir ve sanat eserleri için telif hakları düzenlemelerine uyulduğunun belirtilmesi.



Makale başvurusunda;

(1) Tam metin makale, Dergi yazım kurallarına uygun olmalı, Makalenin ilk sayfasında ve teşekkür bilgi notu kısmında Araştırma ve Yayın Etiğine uyulduğuna ve Etik kurul izni gerektirmediğine dair ifadeye yer verilmelidir. Etik kurul izni gerektiren çalışmalarda, izinle ilgili bilgiler (kurul adı, tarih ve sayı no) yöntem bölümünde ve ayrıca makale ilk/son sayfasında yer verilmeli ve sisteme belgenin yüklenmesi gerekmektedir. (Dergiye gönderilen makalelerde; konu ile ilgili olarak derginin daha önceki sayılarında yayımlanan en az bir yayına atıf yapılması önem arz etmektedir. Dergiye yapılan atıflarda “Bursa Uludag Üniv. Ziraat Fak. Derg.” kısaltması kullanılmalıdır.)

(2) Tam metin makalenin taratıldığını gösteren benzerlik raporu (Ithenticate, intihal.net) (% 20’nin altında olmalıdır),

(3) İmzalanmış ve taratılmış başvuru formu, Dergi web sayfasında yer alan başvuru formunun başvuran tarafından İmzalanıp, taratılarak yüklenmesi , (Ön yazı yerine)

(4) Tüm yazarlar tarafından imzalanmış telif hakkı devir formunun taranmış kopyası,

(5) Araştırmacıların Katkı Oranı beyanı, Çıkar Çatışması beyanı verilmesi Makale sonunda; Araştırmacıların Katkı Oranı beyanı, varsa Destek ve Teşekkür Beyanı, Çatışma Beyanı verilmesi ve sisteme belgenin (Tüm yazarlar tarafından imzalanmış bir yazı) yüklenmesi gerekmektedir.

Belgelerin elektronik formatta DergiPark sistemine https://dergipark.org.tr/tr/login adresinden kayıt olunarak başvuru sırasında yüklenmesi mümkündür. 


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