Assessing adaptation – Climate change and indigenous livelihood in the Andes of Bolivia

Based on a case study of Charazani – Bolivia, this article outlines the understanding of adaptive strategies to cope with climate change and its impact on environmental and socioeconomic conditions that are affecting rural livelihoods. Mainly qualitative methods were used to collect and analyze data following the framework for vulnerability assessments of a socio-ecological system. Climate data reveals an increase of precipitation and temperature during the last decades. Furthermore the occurrence of extreme weather events, particularly drought, frost, hailstorms and consequently landslides and fire are increasing. Local testimonies highlight these events as the principle reasons for agricultural losses. This climatic variability and simultaneous social changes were identified as the drivers of vulnerability. Yet, several adaptive measures were identified at household, community and external levels in order to cope with such vulnerability; e.g. traditional techniques in agriculture and risk management. Gradually, farmers complement these activities with contemporary practices in agriculture, like intensification of land use, diversification of irrigation system and use of artificial fertilizers. As part of a recent trend community members are forced to search for new off-farm alternatives beyond agriculture for subsistence. Despite there is a correspondingly large array of possible adaptation measures that families are implementing, local testimonies point out, that farmers often do not have the capacity and neither the economical resources to mitigate the risk in agricultural production. Although several actions are already considered to promote further adaptive capacity, the current target is to improve existing livelihood strategies by reducing vulnerability to hazards induced by climate change.

Konstruktive und funktionale Entwicklung eines selbststeuernden Unterflurbewässerungsverfahrens

Unter Einfluss des gegenwärtigen Klimawandels sowie dem Anstieg der Erdbevölkerung ist der effiziente Umgang mit den vorhandenen Wasserressourcen ein zentrales Thema in der Bewässerungslandwirtschaft. Die Unterflurbewässerung ist ein seit Jahrtausenden bekanntes Verfahren, bei dem das Bewässerungswasser unterhalb der Erdoberfläche aufgebracht wird und der Pflanze direkt im Wurzelraum zur Verfügung steht. Die Gefäßbewässerung ist ein selbststeuerndes Verfahren wobei die Wassergabe aus dem unglasierten Tongefäß aufgrund der im umgebenden Boden anliegenden Saugspannung erfolgt. Diese wassersparende und dem Wasserbedarf der Pflanze angepasste Bewässerungsweise ist Grundlage der Überlegungen und Untersuchungen der vorliegenden Arbeit. Ausgehend von dem Gedanken der Kombination der Vorteile der Gefäßbewässerung mit denen moderner Materialien, die eine maschinelle Installation ermöglichen und eine lange Lebensdauer aufweisen, wurde die Entwicklung einer selbststeuernden Bewässerung verfolgt. Materialrecherchen und eine Auswahl als geeignet identifizierter Materialien führten zu Laboruntersuchungen an Hand derer die Darcy-Eigenschaften (linearer Zusammenhang zwischen Volumenstrom und anliegendem Druck) überprüft wurden. Membranen erwiesen sich danach als geeignet, so dass an einer ausgewählten Schlauchmembran weitergehende Untersuchungen zum Einsatz für die Bewässerung vorgenommen wurden. Diese umfassten Langzeitlaborversuche im Boden zur Untersuchung der Entwicklung der Durchlässigkeit der Schlauchmembran über die Zeit, sowie zum Nachweis der Selbststeuerung des Systems. Mit den gewonnenen Ergebnissen war es möglich großmaßstäbliche Versuche im Gewächshaus zu realisieren, bei der die Schlauchmembran im Vergleich zur Tropfbewässerung hinsichtlich Wasserverbrauch und Ernteertrag an Standorten in Deutschland und Algerien getestet wurde. Diese Gewächshausversuche zeigten vielversprechende Ergebnisse für die Membranschlauchbewässerung mit im Vergleich zur Tropfbewässerung erhöhten Erträgen bei gleichzeitig geringerem Wasserverbrauch. Dies wurde besonders bei Verwendung von Bewässerungswasser mit erhöhtem Salzgehalt deutlich. Sorgfältiger Beachtung bedarf die Wasserqualität, da die Membranschlauchbewässerung auf Wasserverunreinigungen mit Durchflussverminderung reagiert, die sich nachteilig auf die Pflanzenentwicklung auswirkt. Aufgabe weiterer Forschungen muss es demnach sein, technische Verfahren zu entwickeln, die die langfristige Leistungsfähigkeit der Membran im Bewässerungsbetrieb aufrechterhalten.

More than irrigation - The Balinese Subak system as a unique form of cooperative water resource management in Indonesia

For over 1,000 years, the Balinese have developed a unique system of democratic and sustainable water irrigation. It has shaped the cultural landscapes of Bali and enables local communities to manage the ecology of terraced rice fields at the scale of whole watersheds. The Subak system has made the Balinese the most productive rice growers in Indonesia and ensures a high level of food sovereignty for a dense population on the volcanic island. The Subak system provides a vibrant example of a diverse, ecologically sustainable, economically productive and democratic water management system that is also characterized by its nonreliance on fossil fuel derivatives or heavy machinery. In 2012, UNESCO has recognized five rice terraces and their water temples as World Heritage site and supports its conservation and protection. However, the fragile Subak system is threatened for its complexity and interconnectedness by new agricultural practices and increasing tourism on the island.

Field measurements of the CO2 evolution rate under different crops during an irrigation cycle in a mountain oasis of Oman

For millennia oasis agriculture has been the backbone of rural livelihood in the desertic Sultanate of Oman. However, little is known about the functioning of these oasis systems, in particular with respect to the C turnover. The objective was to determine the effects of crop, i.e. alfalfa, wheat and bare fallow on the CO2 evolution rate during an irrigation cycle in relation to changes in soil water content and soil temperature. The gravimetric soil water content decreased from initially 24% to approximately 16% within 7 days after irrigation. The mean CO2 evolution rates increased significantly in the order fallow (27.4 mg C m^−2 h^−1) < wheat (45.5 mg C m^−2 h^−1) < alfalfa (97.5 mg C m^−2 h^−1). It can be calculated from these data that the CO2 evolution rate of the alfalfa root system was nearly four times higher than the corresponding rate in the wheat root system. The decline in CO2 evolution rate, especially during the first 4 days after irrigation, was significantly related to the decline in the gravimetric water content, with r = 0.70. CO2 evolution rate and soil temperature at 5 cm depth were negatively correlated (r = -0.56,n = 261) due to increasing soil temperature with decreasing gravimetric water content.

Plant genetic diversity, irrigation and nutrient cycling in traditional mountain oases of northern Oman

Little is known about plant biodiversity, irrigation management and nutrient fluxes as criteria to assess the sustainability of traditional irrigation agriculture in eastern Arabia. Therefore interdisciplinary studies were conducted over 4 yrs on flood-irrigated fields dominated by wheat (Triticum spp.), alfalfa (Medicago sativa L.) and date palm (Phoenix dactylifera L.) in two mountain oases of northern Oman. In both oases wheat landraces consisted of varietal mixtures comprising T. aestivum and T. durum of which at least two botanical varieties were new to science. During irrigation cycles of 6-9 days on an alfalfa-planted soil, volumetric water contents ranged from 30-13%. For cropland, partial oasis balances (comprising inputs of manure, mineral fertilizers, N2-fixation and irrigation water, and outputs of harvested products) were similar for both oases, with per hectare annual surpluses of 131 kg N, 37 kg P and 84 kg K at Balad Seet and of 136 kg N, 16 kg P and 66 kg K at Maqta. Respective palm grove surpluses, in contrast were with 303 kg N, 38 kg P, and 173 kg K ha^-1 yr^-1 much higher at Balad Seet than with 84 kg N, 14 kg P and 91 kg K ha^-1 yr^-1 at Maqta. The results show that the sustainability of these irrigated landuse systems depends on a high quality of the irrigation water with low Na but high CaCO3, intensive recycling of manure and an elaborate terrace structure with a well tailored water management system that allows adequate drainage.