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  • 1 Georgikon Kar, Keszthely
  • | 2 Talajtani és Agrokémia Intézet, Budapest
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A víztartó-képesség meghatározása, eszközeit és módszertanát tekintve, jelentős előrelépéseken ment keresztül az elmúlt megközelítőleg 60 évben, mind a közvetlen mérések, mind a modellek területén, például a dinamikus, spektroszkópiai és digitális képazonosítási eljárások kidolgozása, fejlesztése, illetve a mintázatfelismerésen alapuló pedotranszfer típusú becslő eljárások fejlesztése, validálása, beépítése szoftverekbe, almodellekbe. A pórustér hierarchikus hálózati rendszerként való új értelmezésével, illetve a geometriai alapú, a szemifizikus, majd a statisztikus közelítő eljárásokkal lehetővé vált a pórustér és az abban lejátszódó folyamatok mind pontosabb jellemzése.

A talaj víztartó-képességét — és ezáltal a pórusméret-eloszlását is — többmódusú függvénnyel jellemző egyszerű, vagy összetett összefüggések lehetőséget nyújtanak a porozitás, illetve a porozitás-változási jelenségek, folyamatok (aggregátumstabilitás, tömődöttség változása, pórusdeformációs jelenségek stb.) tanulmányozására, valamint a hiszterézis számszerűsítésére és mind pontosabb meghatározására, akár az SWRC teljes nyomástartományában.

A modellezés különböző léptékeiben értelmezett talajjellemzők közötti összefüggések vizsgálatához a hidrológiai talajtulajdonságokat és az áramlási folyamatokat egyaránt meghatározó talajszerkezet szerepének számszerűsítése mind a mai napig kihívást jelent a talajtani, hidrológiai, környezetvédelmi szakterületen dolgozó kutatók számára.

Az NAPL típusú szennyezőanyagok felszín alatti terjedését szimuláló modellek jellemzően a víztartó-képesség használatával állítják fel az NAPL-visszatartó képességre (elsődleges bemeneti paraméter) alkalmazott összefüggéseket. Ezen összefüggések nem veszik figyelembe a különböző fizikai-, kémiai és fizikokémiai tulajdonságokkal jellemezhető folyadékok, illetve a folyadékok és a szilárd fázis között lezajló különböző mértékű kölcsönhatások jelentőségét (duzzadás, dezaggregáció stb). Több különböző környezetvédelmi célú kutatás (hulladéklerakók agyagszigetelésének kompatibilitási tesztjei, mikromorfológiai vizsgálatok, illetve dinamikus NAPL visszatartó- és vezetőképesség mérési módszertan fejlesztésére vonatkozó vizsgálatok stb.) eredményei alapján a víztartó-képességből kiinduló számítási eljárások alkalmazhatósága a talajok NAPL-visszatartó képességének meghatározására megkérdőjelezhető.

Megoldást jelenthet, hogy a víztartó-képesség görbék illesztésére alkalmazott parametrikus eljárásokkal az NAPL-visszatartó képesség görbék is meghatározhatóak. A különböző polaritású folyadékokkal felvett folyadékvisszatartó-képesség görbék alaki jellemzői alapján igazolt a differenciált porozitás különböző mértékű megváltozása a talaj vízzel és nem vizes fázisú szerves folyadékokkal való telítése során. A víztartó-képesség becslésére képzett szemifizikus és empirikus eljárások kidolgozásának és fejlesztésének módszertana szerint az NAPL-visszatartó képesség meghatározására alkalmas PTF típusú becslő összefüggések is képezhetőek, melyek pontossága elsősorban 0–1500 kPa nyomástartományban megfelelő. A porozitásváltozás mértékére vonatkozóan a víz- és NAPL-visszatartó képesség görbék alapján meghatározott pórusméret-eloszlási görbék statisztikai jellemzői nyújthatnak információt. A multimodális függvények alkalmazásával lehetővé válhat az NAPL-visszatartó képesség görbék végponti értékei és a becslésbe vont talajtulajdonságok közötti öszefüggések pontosabb feltérképezése. Szükséges a PTF típusú NAPL-visszatartó képesség becslő eljárások fejlesztése; pl. az NAPL-visszatartó képesség görbék meghatározására alkalmas parametrikus eljárás megválasztása; a többfázisú folyadéktranszport modellezésben kulcsfontosságú telítettségi értékek (pl. maradvány telítettség), illetve az azokhoz rendelhető kapilláris nyomás (pl. belépési küszöbnyomás) meghatározása és a folyadékvisszatartó-képesség görbék függvény paraméterei közötti konverziós lehetőségek kidolgozása.

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  • Wipfer, E. L. & Van Der Zee, S. E. A. T. M. 2001. A set of constitutive relationships accounting for residual NAPL in the unsaturated zone. J. Contam. Hydrol. 50. 5377.

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  • Wösten, J. H. M., Lilly, A., Nemes, A. & Le Bas, C. 1999. Development and use of a database of hydraulic properties of European soils. Geoderma. 90. 169185.

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  • Wösten, J. H. M., Pachepsky, Y. A. & Rawls, W. J. 2001. Pedotransfer functions: bridging the gap between available basic soil data and missing soil hydraulic characteristics. J. Hydrol. 251. 123150.

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  • Zhou, D. & Blunt, M. 1997. Effect of spreading coefficitent on the distribution of light non-aqueous phase liquid in the subsurface. J. Contam. Hydrol. 25. (1–2) 119.

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Senior editors

Editor(s)-in-Chief: Rajkai, Kálmán

Technical Editor(s): Koós, Sándor

Technical Editor(s): Vass, Csaba

Editorial Board

  • Bidló, András (Soproni Egyetem, Erdőmérnöki Kar, Környezet- és Földtudományi Intézet, Sopron)
  • Blaskó, Lajos (Debreceni Egyetem, Agrártudományi Központ, Karcagi Kutatóintézet, Karcag)
  • Buzás, István (Szent István Egyetem, Georgikon Kar, Keszthely)
  • Farsang, Andrea (Szegedi Tudományegyetem, Természettudományi és Informatikai Kar, Szeged)
  • Filep, Tibor (Csillagászati és Földtudományi Központ, Földrajztudományi Intézet, Budapest)
  • Fodor, Nándor (Agrártudományi Kutatóközpont, Mezőgazdasági Intézet, Martonvásár)
  • Győri, Zoltán (Debreceni Egyetem, Mezőgazdaság-, Élelmiszertudományi és Környezetgazdálkodási Kar, Debrecen)
  • Jolánkai, Márton (Szent István Egyetem, Növénytermesztési Intézet, Gödöllő)
  • Kátai, János (Debreceni Egyetem, Mezőgazdaság-, Élelmiszertudományi és Környezetgazdálkodási Kar, Debrecen)
  • Lehoczky, Éva (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Makó, András (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Michéli, Erika (Szent István Egyetem, Mezőgazdaság- és Környezettudományi Kar, Gödöllő)
  • Németh, Tamás (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Pásztor, László (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Ragályi, Péter (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Schmidt, Rezső (Széchenyi István Egyetem, Mezőgazdaság- és Élelmiszertudományi Kar, Mosonmagyaróvár)
  • Szili-Kovács, Tibor (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Tamás, János (Debreceni Egyetem, Mezőgazdaság-, Élelmiszertudományi és Környezetgazdálkodási Kar, Debrecen)
  • Tóth, Gergely (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Tóth, Tibor (Agrártudományi Kutatóközpont, Talajtani és Agrokémiai Intézet, Budapest)
  • Tóth, Zoltán (Szent István Egyetem, Georgikon Kar, Keszthely)

 

International Advisory Board

  • Blum, Winfried E. H. (Institute for Soil Research, University of Natural Resources and Life Sciences (BOKU), Wien, Austria)
  • Hofman, Georges (Department of Soil Management, Ghent University, Gent, Belgium)
  • Horn, Rainer (Institute of Plant Nutrition and Soil Science, Christian Albrechts University, Kiel, Germany)
  • Lichner, Ljubomir (Institute of Hydrology, Slovak Academy of Sciences, Bratislava, Slovak Republic)
  • Loch, Jakab (Faculty of Agricultural and Food Sciences and Environmental Management, University of Debrecen, Debrecen, Hungary)
  • Nemes, Attila (Norwegian Institute of Bioeconomy Research, Ås, Norway)
  • Pachepsky, Yakov (Environmental Microbial and Food Safety Lab USDA, Beltsville, MD, USA)

 

           International Editorial Board

  • Kätterer, Thomas (Swedish University of Agricultural Sciences (SLU), Sweden)
  • Ole Wendroth (Department of Plant and Soil Sciences, College of Agriculture, Food and Environment, University of Kentucky, USA)
  • Simota, Catalin Cristian (The Academy of Agricultural and Forestry Sciences, Bucharest, Romania)
  • Stolte, Jannes (Norwegian Institute of Bioeconomy Research, Ås, Norway)

Rajkai Kálmán
ATK Talajtani és Agrokémiai Intézet
Herman Ottó út 15., H-1022 Budapest, Hungary
Phone: (+36 1) 212 2265
Fax: (+36 1) 485 5217
E-mail: editorial.agrokemia@atk.hu

Indexing and Abstracting Services:

  • CAB Abstracts
  • EMBiology
  • Global Health
  • SCOPUS
  • CABI

2020  
Scimago
H-index
9
Scimago
Journal Rank
0,179
Scimago
Quartile Score
Agronomy and Crop Science Q4
Soil Science Q4
Scopus
Cite Score
48/73=0,7
Scopus
Cite Score Rank
Agronomy and Crop Science 278/347 (Q4)
Soil Science 108/135 (Q4)
Scopus
SNIP
0,18
Scopus
Cites
48
Scopus
Documents
6
Days from submission to acceptance 130
Days from acceptance to publication 152
Acceptance
Rate
65%

 

2019  
Scimago
H-index
9
Scimago
Journal Rank
0,204
Scimago
Quartile Score
Agronomy and Crop Science Q4
Soil Science Q4
Scopus
Cite Score
49/88=0,6
Scopus
Cite Score Rank
Agronomy and Crop Science 276/334 (Q4)
Soil Science 104/126 (Q4)
Scopus
SNIP
0,423
Scopus
Cites
96
Scopus
Documents
27
Acceptance
Rate
91%

 

Agrokémia és Talajtan
Publication Model Hybrid
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Agrokémia és Talajtan
Language Hungarian, English
Size B5
Year of
Foundation
1951
Publication
Programme
2021 Volume 70
Volumes
per Year
1
Issues
per Year
2
Founder Magyar Tudományos Akadémia
Founder's
Address
H-1051 Budapest, Hungary, Széchenyi István tér 9.
Publisher Akadémiai Kiadó
Publisher's
Address
H-1117 Budapest, Hungary 1516 Budapest, PO Box 245.
Responsible
Publisher
Chief Executive Officer, Akadémiai Kiadó
ISSN 0002-1873 (Print)
ISSN 1588-2713 (Online)

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