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Összefoglalás
Tanulmányunkban 27 különböző hazai talajszelvényben vizsgáltuk, hogy a talajok N2-BET fajlagos felületét mely talajtulajdonságok milyen mértékben befolyásolják.
Az egytényezős elemzések alapján elmondható, hogy a talajok mechanikai összetétele mutatja a legszorosabb kapcsolatot a fajlagos felülettel, az agyagtartalommal szoros pozitív kapcsolat van, ugyanakkor a homoktartalom növekedésével a fajlagos felület csökken. Igazolható a mész- és humusztartalom negatív előjelű nem túl szoros kapcsolata is a N2-BET felület értékekkel. A korrelációs vizsgálat gyenge pozitív kapcsolatot mutat a Hargitai-féle humuszstabilitási mutatóval. A talaj kémhatása és fajlagos felület közötti kapcsolatot nem tudtuk igazolni.
Vizsgáltuk a különböző talajtulajdonságok együttes hatását is a talaj N2-BET fajlagos felületére, valamint a talajok főtípusának, illetve a talajtípusoknak a szerepét. A teljes adatbázis alapján a N2-BET fajlagos felület kialakításában a legfontosabb tényezők az agyagtartalom, majd a humusztartalom, végül a mésztartalom. Amennyiben a talajok humuszanyagainak minőségéről is rendelkezünk információkkal, akkor az agyagtartalom, a humusztartalom, a humuszminőség és kémhatás azok a talajtulajdonságok, amelyek elsősorban felelősek a talajok a N2-BET fajlagos felületének kialakításáért. Megállapítottuk, hogy a fajlagos felületet becslő modellek pontossága tovább javítható a talajok rendszertani besorolásának (főtípus, típus), mint kategóriaváltozónak figyelembevételével. A talajok rendszertani helyének ismerete ugyanis számos olyan talajjellemzőről, azok együttes hatásairól nyújt közvetett információt, melyekről egyébként nem rendelkezünk közvetlen mérési eredménnyel.
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Szili-Kovács, Tibor
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| 2022 | |
|---|---|
| Web of Science | |
| Total Cites WoS |
not indexed |
| Journal Impact Factor | not indexed |
| Rank by Impact Factor |
not indexed |
| Impact Factor without Journal Self Cites |
not indexed |
| 5 Year Impact Factor |
not indexed |
| Journal Citation Indicator | not indexed |
| Rank by Journal Citation Indicator |
not indexed |
| Scimago | |
| Scimago H-index |
10 |
| Scimago Journal Rank |
0.151 |
| Scimago Quartile Score |
Agronomy and Crop Science (Q4) |
| Scopus | |
| Scopus Cite Score |
0.6 |
| Scopus CIte Score Rank |
Agronomy and Crop Science 335/376 (11th PCTL) Soil Science 134/147 (9th PCTL) |
| Scopus SNIP |
0.263 |
| 2021 | |
|---|---|
| Web of Science | |
| Total Cites WoS |
not indexed |
| Journal Impact Factor | not indexed |
| Rank by Impact Factor |
not indexed |
| Impact Factor without Journal Self Cites |
not indexed |
| 5 Year Impact Factor |
not indexed |
| Journal Citation Indicator | not indexed |
| Rank by Journal Citation Indicator |
not indexed |
| Scimago | |
| Scimago H-index |
10 |
| Scimago Journal Rank |
0,138 |
| Scimago Quartile Score | Agronomy and Crop Science (Q4) Soil Science (Q4) |
| Scopus | |
| Scopus Cite Score |
0,8 |
| Scopus CIte Score Rank |
Agronomy and Crop Science 290/370 (Q4) Soil Science 118/145 (Q4) |
| Scopus SNIP |
0,077 |
| 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% |
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