The ecohydrology of the Fransehoek Trust Wetland: water, soils and vegetation.

Kotzee, Ilse

January 2010

>Magister Scientiae - MSc / The research was driven by a need to increase the knowledge base concerning wetland ecological responses, as well as to identify and evaluate the factors driving the functioning of the Franschhoek Trust Wetland. An ecohydrological study was undertaken in which vegetation cover, depth to groundwater, water and soil chemistry were monitored at 14 sites along three transects for a 12 month period. The parameters used include temperature, pH, electrical conductivity (EC), sodium, potassium, magnesium, calcium, iron, chloride, bicarbonate, sulphate, total nitrogen, ammonia, nitrate, nitrite and phosphorus. T-tests and Principal Component Analysis (PCA) were used to analyze trends and to express the relationship between abiotic factors and vegetation. Results reflect the strong influence of hydrology, microtopography and nutrient availability in structuring vegetation composition in the wetland. The wetland has been classified as a palustrine valley bottom with channel wetland, which is predominantly groundwater-fed (phreatrotropic), but receives surface water inputs as well. Small scale gradients of microtopography allow for differences in flooding frequency and duration resulting in hydrologically distinct sites which differ chemically. Three zones were distinguished in the wetland. Hollows or low sites were characterized by intermittent flooding and drying and higher nutrient concentrations in soil and groundwater. High sites which were rarely or never flooded exhibited higher groundwater temperature and ammonia as well as iron in soils and groundwater. The inundated sites remained flooded throughout the year and were characterized by high nitrate and nitrite in soil as well as high EC, magnesium, bicarbonate, sulphate and phosphorus in groundwater. The limited availability of nitrogen in the wetland favoured plant types Typha capensis, Paspalum urvillei and Juncus .kraussii which are able to either fix nitrogen or store nitrogen during more favorable conditions. The main chemical concentration changes take place between summer and winter. The Principal Component Analyses suggest that sodium, chloride, potassium, ammonia and phosphorus are the dominant ions determining the chemistry of groundwater. Increased abstraction from the table mountain aquifer to supplement human demand may put the wetland at risk of degradation. Intensified agriculture and other land use in the area are likely to increase pollution loads into the wetland causing shifts in nutrient availability and vegetation composition. Continued and long term monitoring is essential to ensure effective management of the wetland and is highly recommended. Closer partnerships between wetland managers and scientists as well as community awareness and involvement through a volunteer monitoring programme should be encouraged

Wetlands

Ecohydrology

Hydrologic regime

Management

Water table

Water chemistry

Vegetation

Soil Nutrient availability

Topography

Soil Nutrient Cycling and Water Use in Response to Orchard Floor Management in Stone-Fruit Orchards in the Intermountain West

Culumber, Catherine Mae

01 May 2016

Fruit growers in Utah and other areas across the Intermountain West are faced with growing production challenges stemming from declining soil quality and water resources. Population growth presents challenges in terms of the cost and availability of land, but also presents opportunities in the form of new marketing options such as organic fruit. Few certified organic fruit orchards are operating in Utah currently, which is attributed to a lack of locally tested and adapted organic management practices. An organic peach orchard trial evaluated the effectiveness of different organic management approaches to enhance soil quality and conserve water without compromise to fruit tree growth and fertility. Two tree-row treatments: ‘straw mulch' (Triticum aestivum L.) and ‘living mulch’ (Lobularia maritima (L.) Desv.) were tested in combination with two alleyway groundcovers: ‘grass’ (Festuca rubra L. with Lolium perenne L.) and a legume, ‘Birdsfoot trefoil’ (Lotus corniculatus L.). The novel systems were compared with industry standards, tillage and weed fabric tree-rows with grass alleyways. Trefoil alleyway biomass deposited into tree-rows contributed an estimated 6.24 kg biomass and 0.21 kg total N/tree annually. Trefoil treatments had higher levels of organic carbon (C) and nitrogen (N), inorganic N, microbial biomass and enzyme activities, suggesting trefoil alleyways enhanced soil nutrient cycling, as well as C and N reserves in comparison to grass and tillage treatments. A functional gene array analysis was conducted to describe the mechanisms, microbial functional composition and diversity underlying the observed soil processes, however few differences were detected in soil community structure between soils under different orchard floor management. Significantly lower leaf δ15N in trees grown with trefoil compared to grass, and an association between root biomass, diameter and trunk cross-sectional area (TCSA) suggests nitrogen sources derived from the trefoil groundcover contributed to improved fruit tree vigor. Few differences resulted among orchard treatments for water use (mm/week). Trends indicated slightly higher water use in trefoil over grass, but not enough to offset observed soil quality and tree growth benefits. These findings suggest, trefoil alleyways may provide ecological benefits such as improved soil quality and efficient nutrient cycling, without substantial increases in water use.

soil nutrient management

soil quality

cover crops

mulches

water use

Agriculture

Plant Sciences

Soil Ecosystem Processes in Tropical Forests, Savanna, and Croplands of Cameroon / カメルーンの熱帯林、サバンナおよび耕地における土壌生態系プロセスに関する研究

Shibata, Makoto

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第21164号 / 農博第2290号 / 新制||農||1060(附属図書館) / 学位論文||H30||N5138(農学部図書室) / 京都大学大学院農学研究科地域環境科学専攻 / (主査)教授 舟川 晋也, 教授 縄田 栄治, 教授 北山 兼弘 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

Oxisols

Ultisols

Soil nutrient

Forest-savanna mosaic

Soil acidity

Cultivation

Leaching

610

Investigating nutrient co-limitation in northern hardwood forests

Goswami, Shinjini

31 July 2017

No description available.

Ecology

Ecological responses of two forest understory herbs to changes in resources caused by prescribed fire alone on in combination with restoration thinning

Huang, Jianjun

10 December 2007

No description available.

fire

thinning

herb

morphology

nutrient

ecophysiology

seed

biomass

light

soil nutrient

Impacts of Fertilization on Soil Properties in Loblolly Pine Plantations in the Southeastern United States

Tacilla Villanueva, Antonio

06 July 2015

We examined the effects of periodic nitrogen (N) and phosphorus (P) fertilizer applications on the O horizon and mineral soil in loblolly pine (Pinus taeda L.) plantations over a 12-year period. To accomplish this, we used 9 experimental sites located across the south, which were grouped using the CRIFF Classification System. Group 1—CRIFF A, B (poorly-drained Ultisols); group 2—CRIFF C, D, G (sandy Spodosols and Entisols); and group 3—CRIFF E, F (well-drained Ultisols). Fertilization rates were 135, 202, and 269 kg N ha-1 at 4 years application frequency. This resulted in a cumulative N application rate of 540, 808, and 1076 kg ha-1. P was added at 10% of the N rate. Fertilization increased the mass, N content, and P content of the O horizon in all soil groups. Fertilization did not impact mineral soil N. No significant increases in total N trends were observed to a depth of 1 m. Likewise, total inorganic N (NH4+ + NO3-) was not affected by fertilization. These results suggest that N fertilization will have little effect on long-term soil N availability regardless of soil types. In contrast, fertilization increased extractable P in soil CRIFF groups 1, 2, and 3 by 26, 60, and 4 kg P ha-1 respectively suggesting potential for long-term soil P availability and site quality improvement. However, the low extractable P in soil group 3 implies additional fertilization with P for the next rotation for sites included into this soil group. / Master of Science

Forest fertilization

Nitrogen

Phosphorus

O horizon

KCl extractable

soil nutrient availability

Quantitative characterization of field-estimated soil nutrient regimes in the coastal forest

Klinka, Karel, Varga, Pal, Chourmouzis, Christine

January 1999

One of the key factors in the site classification of the biogeoclimatic ecosystem classification is soil nutrient regime. Soil nutrient regime (SNR) represents the amount of essential soil nutrients available to plants over a period of several years. SNRs classes are assessed based on field identifiable (qualitative) criteria, not using quantitative measures. There have been several studies that attempted to quantitatively characterize regional soil nutrient gradients in the Coastal Western Hemlock (CWH) zone. In the study summarized here, the soils are influenced by a perhumid cool mesothermal climate. The objective of the study was to examine relationships between soil chemical properties and field-estimated SNRs.

Carbon

Classification

Coastal Western hemlock zone

Site index

Site quality

Soil nutrient regime

Soil nutrients

Nitrogen

Western hemlock

Quantitative characterization of field-estimated soil nutrient regimes in the subalpine interior forest

Klinka, Karel, Chen, Han Y. H., Chourmouzis, Christine

January 1999

Site classification of the biogeoclimatic ecosystem classification system is based on climatic regime (expressed by biogeoclimatic subzone), soil moisture regime (SMR), and soil nutrient regime (SNR). A SNR represents a segment of a regional soil nutrient gradient, i.e., a population of soils which provide similar levels of plant-available nutrients over a long period. SNR is identified in the field using a number of easily observable soil morphological properties and indicator plant species. However, we do not know the extent to which soil nutrient properties are supported by these indirect field-estimates. There have been several studies that quantitatively characterized regional soil nutrient gradients in different climatic regions (see Sciencia Silvica Number 21 for subalpine coastal forests), but this has not been done in the subalpine interior forest (Engelmann Spruce - Subalpine Fir (ESSF) zone) where soils are influenced by a continental subalpine boreal climate. In the study summarized here, relationships between soil chemical properties and field-estimated SNRs are examined and soil chemical properties and field-identified SNRs are related to the site index of subalpine fir (Abies lasiocarpa (Dougl. ex Loud.) Forbes) and Engelmann spruce (Picea engelmannii Parry ex Engelmann) - two major timber crop species in the ESSF zone.

Classification

Engelmann spruce

Engelmann spruce - subalpine fir

Site index

Site quality

Soil nutrient regime

Soil nutrients

Subalpine fir

Quantitative characterization of field-estimated soil nutrient regimes in the subalpine coastal forest.

Klinka, Karel, Splechtna, Bernhard E., Chourmouzis, Christine

January 1999

Site classification in the biogeoclimatic ecosystem classification system is based on three differentiating properties: climatic regimes (expressed by biogeoclimatic subzones or variants), soil moisture regimes (SMRs), and soil nutrient regimes (SNRs). A SNR represents a segment of a regional soil nutrient gradient, i.e., soils which provide similar levels of plant-available nutrients over a long period. SNRs are identified in the field using a number of easily observable soil morphological properties and indicator plant species. However, we need to know to what extent soil nutrient properties support these indirect field-estimates. There have been several studies that quantitatively characterize regional soil nutrient gradients in different climatic regions, but no study has yet been done in the subalpine coastal forest (Mountain Hemlock zone). Influenced by a maritime subalpine boreal climate, high-elevation coastal soils differ from low-elevation soils by having a thicker forest floor and a higher organic matter content. In the study summarized here, relationships between soil chemical properties and field-estimated SNRs are examined and soil chemical properties and field-identified SNRs are related to the site index of Pacific silver fir (Abies amabilis (Dougl. ex Loud.) Forbes) - one of the major timber crop species in the Coastal Western Hemlock and Mountain Hemlock zones.

Classification

Elevation

Forest site quality

Mountain hemlock

Pacific silver fir

Site index

Soil moisture

Soil nutrient regime

Soil nutrients

Conversion of lowland forests to rubber and oil palm plantations changes nutrient leaching and nutrient retention efficiency in highly weathered soils of Sumatra, Indonesia

Kurniawan, Syahrul

07 March 2016

In den letzten zwei Jahrzehnten wurden in Sumatra (Indonesien) große Regenwaldflächen für den Anbau von Kautschuk- und Palmölplantagen zerstört. Dies zeigt sich in der Abnahme Waldfläche in dieser Region um 36% zwischen 1990-2010. Eine solch schnelle Landnutzungsänderung hat Auswirkungen auf die Umwelt: Es ist davon auszugehen, dass die Zerstörung von Regenwald und die Etablierung von Kautschuk- und Palmölplantagen aufgrund von Einflüssen auf die Bodenoberfläche, Veränderungen von Streufall, Nährstoffverfügbarkeit und Management in den Plantagen zu erhöhter Nährstoffauswaschung und einer verminderten Nährstoffretentionseffizienz führt. Diese Arbeit stellt zwei Studien vor, die sich mit den Auswirkungen der Regenwaldzerstörung - und der einhergehenden Kultivierung von Kautschuk und Ölpalmenbäumen - auf Nährstoffauswaschung und Nährstoffretentionseffizienz beschäftigt. Außerdem untersucht sie Unterschiede in der Nährstoffauswaschung zwischen gedüngten und mit Palmwedeln bedeckten Bereichen in Palmölplantagen. Beide Studien wurden in zwei Landschaften der Provinz Jambi (Sumatra, Indonesien) mit stark verwitterten Acrisol-Böden durchgeführt, die sich in der Bodenart unterscheiden (lehm- bzw. tonhaltiger Acrisol). Die Nährstoffauswaschung im Boden wurde mit Saugkerzen-Lysimetern gemessen, die in 1,5m Tiefe im Boden installiert wurden. Beprobt wurde von Februar bis Dezember 2013 zweiwöchentlich bis monatlich. Die erste Studie beschäftigt sich mit der Nährstoffauswaschung und Nährstoffretentionseffizienz im Boden vierer verschiedener Landnutzungsarten. Dabei handelt es sich um die zwei Referenznutzungsformen Tieflandregenwald sowie Sekundärwald durchsetzt mit Kautschukbäumen, als auch um die veränderten Landnutzungsformen kleinbäuerlicher Kautschuk- und Ölpalmplantagen. Jede Landnutzung, ausgenommen der Palmölplantagen mit drei Wiederholungen, wurde durch vier Wiederholungsflächen innerhalb jeder Landschaft repräsentiert. Somit wurde die Studie auf insgesamt 30 Flächen durchgeführt. Die Ergebnisse zeigen für den lehmigen Acrisol-Boden der Referenzflächen eine höhere Auswaschung und eine niedrigere N-Retentionseffizienz für Stickstoff (N) und basische Kationen, verglichen mit dem tonigen Acrisol-Boden bestanden. In den Palmölplantagen zeigte sich, dass Düngung und Kalkung zu erhöhter Auswaschung von gelöstem N, gelöstem organischen Kohlenstoff (DOC) und basischen Kationen führte, sowie zu einer geringeren Retentionseffizienz von N und basischen Kationen im Boden. In den ungedüngten Kautschukplantagen dagegen waren die Auswaschungsverluste von gelöstem N, DOC und basischen Kationen geringer als in den Palmölplantagen. Zusammenfassend zeigten die Ergebnisse, dass Nährstoffverluste und Nährstoffretentionseffizienz in Kautschuk- und Palmölplantagen auf stark verwitterten Acrisolen primär von Tongehalt und Management abhängen. In der zweiten Studie wurde die Nährstoffauswaschung in den gedüngten und mit Palmwedeln bedeckten Bereichen in Palmölplantagen von Kleinbauern in lehm- bzw. tonhaltigen Acrisolen gemessen. Die Ergebnisse zeigten höhere Auswaschverluste (d.h. N, basische Kationen, Gesamt-Aluminium, Gesamt-Mangan, Gesamt-Schwefel und Chlor) in den gedüngten Bereichen als in den mit Palmwedeln bedeckten Bereichen aufgrund der Frequenz des Mineraldünger- und Kalkeinsatzes. Auf Landschaftsebene wurden die höheren Bodennährstoffvorräte und eine niedrigere Nährstoffauswaschung im Ton-Acrisol im Vergleich zum Lehm-Acrisol sowohl in den gedüngten als auch in den mit Palmwedeln bedeckten Bereichen durch die höhere Nährstoffretention (als Ergebnis höheren Tongehaltes) verursacht. Die Kombination von Nährstoffauswaschung und Nährstoffeintrag (d.h. Gesamtniederschlag und Dünger) mit zusätzlichen Informationen über den Nährstoffaustrag durch die Ernte, geben uns umfassendere Informationen über die Veränderungen im partiellen Nährstoffhaushalt von N, Phosphor (P), und basischen Kationen bei Waldumwandlung zu Palmöl- und Kautschukplantagen. Gedüngte Palmölplantagen hatten aufgrund der hohen jährlichen Nährstoffauswaschung und des Ernteexports das niedrigste jährliche Teilbudget an N, Kalzium (Ca) und Magnesium (Mg). Dennoch verringerten die hohen negativen Teilbudgets von N, Ca und Mg in den Palmölplantagen nicht deren Vorräte in 1m Bodentiefe verglichen mit den anderen Landnutzungsformen - außer für austauschbares Mg im Lehm-Acrisol. Obwohl ungedüngte Kautschukplantagen geringere Auswaschung zeigen als der Wald (z.B. für P), führte der Ernteexport zu einem geringeren jährlichen P-Teilbudget. Insgesamt implizieren die Ergebnisse der beiden Studien folgende verbesserte Managementverfahren für diese hochverwitterten Böden: eine Synchronisation der Düngermenge mit der Pflanzenaufnahme sowie eine Anpassung der Düngungshӓufigkeit.

634

Forstwirtschaft (PPN621305413)