Evaluation of the dry weight rank method for botanical analysis of grassland by means of simulation

Neuteboom, J.H.; Lantinga, E.A.; Struik, P.C.

doi:10.18174/njas.v46i3.484

Cited by 7 publications

(12 citation statements)

References 13 publications

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“…This is because the probability of a species being assigned the first rank is small if it has only a small part in the mixture (0% of dominance may be compatible with 15% of weight, but 0% of weight is not compatible with 15% of dominance). So in Figure 1 a sigmoid relationship, resembling the theoretical relationship reported by Neuteboom et al . (1998) between (1:0:0) EDW and ODW, may be drawn.…”

Section: Resultssupporting

confidence: 86%

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A variant of the dry‐weight rank method for botanical analysis of grassland with dominance‐based multipliers

Nijland

2000

Grass and Forage Science

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A new variant of the dry‐weight rank method for botanical investigation of grassland is described and its usefulness evaluated. Multipliers proportional to the dominance percentages of the three species with the highest dominance percentages are used instead of fixed multipliers. The method is theoretically more valid and applicable to a broader range of grasslands than the variants with fixed multipliers. It does not involve more costs and gives as good or better predictions of the dry‐weight percentages than the variants with fixed multipliers.

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Section: Resultssupporting

confidence: 86%

“…A compromise between subjectively estimating and objective measuring is the dry‐weight rank method ( Mannetje and Haydock, 1963; Kruijne et al ., 1967 ; Neuteboom et al ., 1998 ). It uses ranking of species according to the biomass occupied per species.…”

Section: Introductionmentioning

confidence: 99%

A variant of the dry‐weight rank method for botanical analysis of grassland with dominance‐based multipliers

Nijland

2000

Grass and Forage Science

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“…These proportions are multiplied by 0.702, 0.211 and 0.87, respectively, culminating in the following equation: DWA% = 0.702 (A1%) + 0.211 (A2%) + 0.087 (A3%). This method was tested with different sampling methods, including small samples, and it was concluded that the DWR method is well suited for studying vegetation changes in old, floristically diverse grasslands 36 , such as ours. For each plant species, the functional classification was noted (grass, herb, legume or forb).…”

Section: Methodsmentioning

confidence: 99%

Plant and soil fungal but not soil bacterial communities are linked in long-term fertilized grassland

Cassman

Leite

Pan

et al. 2016

Sci Rep

114

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Inorganic fertilization and mowing alter soil factors with subsequent effects–direct and indirect - on above- and below-ground communities. We explored direct and indirect effects of long-term fertilization (N, P, NPK, Liming) and twice yearly mowing on the plant, bacterial and fungal communities and soil factors. We analyzed co-variation using 16S and 18S rRNA genes surveys, and plant frequency and edaphic factors across treatments. The plant and fungal communities were distinct in the NPK and L treatments, while the bacterial communities and soil factors were distinct in the N and L treatments. Plant community diversity and evenness had low diversity in the NPK and high diversity in the liming treatment, while the diversity and evenness of the bacterial and fungal communities did not differ across treatments, except of higher diversity and evenness in the liming treatment for the bacteria. We found significant co-structures between communities based on plant and fungal comparisons but not between plant and bacterial nor bacterial and fungal comparisons. Our results suggested that the plant and fungal communities are more tightly linked than either community with the bacterial community in fertilized soils. We found co-varying plant, bacterial and fungal taxa in different treatments that may indicate ecological interactions.

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“…Data were collected from 50 randomly located circular quadrats (3 dm 2 ) per pasture, using the dry‐weight‐rank (DWR) method (‘t Mannetje & Haydock 1963) with yield correction (Jones & Hargreaves 1979). This method was developed to provide a rapid and accurate estimate of the botanical composition of heterogeneous agricultural grassland swards on a dry‐weight basis, without requiring the clipping and hand sorting of constituent species (‘t Mannetje & Haydock 1963; Neuteboom, Lantinga & Struik 1998). The DWR method assumes that when a large number of samples are taken, the dominant species will on average account for 0·702, the second for 0·211 and the third for 0·087 of total herbage mass.…”

Section: Methodsmentioning

confidence: 99%

“…Species were identified according to Stace (1997). Further details on the DWR method of botanical assessment are provided in ‘t Mannetje & Haydock (1963) and Neuteboom, Lantinga & Struik (1998). Mean vegetation height was estimated within each sampled sward by recording height measurements at 50 randomly selected locations using a Filips Folding Plate Pasture Meter (http://www.jenquip.co.nz).…”

Section: Methodsmentioning

confidence: 99%

The potential of parasitoid Hymenoptera as bioindicators of arthropod diversity in agricultural grasslands

Anderson

McCormack

Helden

et al. 2010

Journal of Applied Ecology

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Summary 1.As measuring biodiversity in its entirety is impractical, there is a need for bioindicators. This study tested the hypothesis that parasitoid Hymenoptera are potential bioindicators that provide a useful means to assess the wider biodiversity of arthropod populations in agro-ecosystems. There are a range of theoretical arguments to support such a claim, including the high trophic position of these taxa within the arthropod communities in which they occur, and the unique nature of their biological relationships with the majority of terrestrial arthropod groups. 2. A survey of 48 commercial farms was conducted and Generalized Linear Models used to investigate relationships between six taxa-parasitoid Hymenoptera, Coleoptera, Hemiptera, Diptera, Araneae and plants (species richness and sward height)-in agricultural grasslands. As well as relationships between these groups, the relationship of each individual group to the overall biodiversity of all other arthropod groups was explored. 3. Both abundance (r 2 = 0AE58) and taxon richness (r 2 = 0AE54) of parasitoid Hymenoptera had stronger relationships with overall arthropod taxon richness than any other arthropod group investigated. Parasitoid abundance also had a positive relationship with species richness of Coleoptera (r 2 = 0AE23) and Hemiptera (r 2 = 0AE47).4. An historical data set demonstrated how the relationship between parasitoid abundance and overall arthropod taxon richness changes over the growing season. July, when the relationship was strongest, is potentially the most useful time to sample. 5. For use in routine monitoring, it is important that an effort be made to understand the seasonal influence on the relationship in the context being studied. Equal sampling effort must be made for all sites being compared and sites should be sampled as close together in the season as is possible. 6. Synthesis and applications. We show that, within agricultural grasslands, both the abundance and taxon richness of parasitoid Hymenoptera are more closely related with overall arthropod diversity than any other arthropod group investigated. The use of parasitoid abundance provides a simple and practicable monitoring tool for tracking change in wider arthropod diversity in agroecosystems.

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Evaluation of the dry weight rank method for botanical analysis of grassland by means of simulation

Cited by 7 publications

References 13 publications

A variant of the dry‐weight rank method for botanical analysis of grassland with dominance‐based multipliers

A variant of the dry‐weight rank method for botanical analysis of grassland with dominance‐based multipliers

Plant and soil fungal but not soil bacterial communities are linked in long-term fertilized grassland

The potential of parasitoid Hymenoptera as bioindicators of arthropod diversity in agricultural grasslands

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