Spatial Variability of Biofuel Production Potential and Hydrologic Fluxes of Land Use Change from Cotton (Gossypium hirsutum L.) to Alamo Switchgrass (Panicum virgatum L.) in the Texas High Plains

Наведено особливості формування врожайності фітомаси світчграсу – проса лозовидного за вирощування його на деградованих ґрунтах із метою отримання сировини для виробництва біопалива. Подано фенологічні спостереження – тривалість міжфазних періодів під час веґетації культури другого року життя. Встановлено кількісні показники веґетативної частини рослин, подано їх взаємозв’язок та влив на формування врожайності культури. Визначена продуктивність фітомаси світчграсу досліджуваних сортів за різної ширина міжрядь. Peculiarities of forming switch-grass phytomass productivityduring growing on the degraded soils for obtaining raw material for biofuel production are given.Phenologicalobservations such asinterphase perioddurationduring the second year crop vegetation are made. The quantitative indexes of plantvegetative part,correlation of these indexes and influence on crop productivity are established. Switch-grass phytomass productivity of the experimentedvarietieswith different space width between rows is defined.

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A hydrochemical modelling framework for combined assessment of spatial and temporal variability in stream chemistry: application to Plynlimon, Wales

Hydrology and Earth System Sciences ◽

10.5194/hess-5-49-2001 ◽

2001 ◽

Vol 5 (1) ◽

pp. 49-58 ◽

Cited By ~ 10

Author(s):

H.J. Foster ◽

M.J. Lees ◽

H.S. Wheater ◽

C. Neal ◽

B. Reynolds

Keyword(s):

Land Use ◽

Land Use Change ◽

Spatial Variability ◽

Temporal Variability ◽

Biological Diversity ◽

Spatial And Temporal Variability ◽

Stream Chemistry ◽

Two Component ◽

End Members

Abstract. Recent concern about the risk to biota from acidification in upland areas, due to air pollution and land-use change (such as the planting of coniferous forests), has generated a need to model catchment hydro-chemistry to assess environmental risk and define protection strategies. Previous approaches have tended to concentrate on quantifying either spatial variability at a regional scale or temporal variability at a given location. However, to protect biota from ‘acid episodes’, an assessment of both temporal and spatial variability of stream chemistry is required at a catchment scale. In addition, quantification of temporal variability needs to represent both episodic event response and long term variability caused by deposition and/or land-use change. Both spatial and temporal variability in streamwater chemistry are considered in a new modelling methodology based on application to the Plynlimon catchments, central Wales. A two-component End-Member Mixing Analysis (EMMA) is used whereby low and high flow chemistry are taken to represent ‘groundwater’ and ‘soil water’ end-members. The conventional EMMA method is extended to incorporate spatial variability in the two end-members across the catchments by quantifying the Acid Neutralisation Capacity (ANC) of each in terms of a statistical distribution. These are then input as stochastic variables to a two-component mixing model, thereby accounting for variability of ANC both spatially and temporally. The model is coupled to a long-term acidification model (MAGIC) to predict the evolution of the end members and, hence, the response to future scenarios. The results can be plotted as a function of time and space, which enables better assessment of the likely effects of pollution deposition or land-use changes in the future on the stream chemistry than current methods which use catchment average values. The model is also a useful basis for further research into linkage between hydrochemistry and intra-catchment biological diversity. Keywords: hydrochemistry, End-Member Mixing Analysis (EMMA), uplands, acidification

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Biofuels and land-use changes: searching for the top model

Interface Focus ◽

10.1098/rsfs.2010.0043 ◽

2011 ◽

Vol 1 (2) ◽

pp. 224-232 ◽

Cited By ~ 41

Author(s):

Andre M. Nassar ◽

Leila Harfuch ◽

Luciane C. Bachion ◽

Marcelo R. Moreira

Keyword(s):

Land Use ◽

Land Use Change ◽

Policy Making ◽

Agricultural Sector ◽

Land Use Changes ◽

Ghg Emissions ◽

Biofuel Production ◽

Policy Makers ◽

Green House Gas ◽

Biofuel Policies

The use of agricultural-based biofuels has expanded. Discussions on how to assess green house gas (GHG) emissions from biofuel policies, specifically on (non-observed) land-use change (LUC) effects involve two main topics: (i) the limitations on the existing methodologies, and (ii) how to isolate the effects of biofuels. This paper discusses the main methodologies currently used by policy-makers to take decisions on how to quantify LUCs owing to biofuel production expansion. It is our opinion that the concerns regarding GHG emissions associated with LUCs should focus on the agricultural sector as a whole rather than concentrating on biofuel production. Actually, there are several limitations of economic models and deterministic methodologies for simulating and explaining LUCs resulting from the expansion of the agricultural sector. However, it is equally true that there are avenues of possibilities to improve models and make them more accurate and precise in order to be used for policy-making. Models available need several improvements to reach perfection. Any top model requires a concentration of interdisciplinary designers in order to replicate empirical evidence and capture correctly the agricultural sector dynamics for different countries and regions. Forgetting those limitations means that models will be used for the wrong purposes.

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