(PDF) Table 4: List of Species Which Contribute Most to the

Table 4: List of Species Which Contribute Most to the Bray-Curtis Dissimilarity Matrices for the 2013 Mat Survey and the 2014 Natural Experiment.

doi 10.7717/peerj.3080/table-4

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Table 4: Summary of Similarity Percentage Analysis (SIMPER) Listing Species That Cumulatively Contribute 90% to the Dissimilarity (Bray Curtis) of the Two Underwater Visual Sampling Methods Based on Square-Root Transformed Density Data.

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Table 1: Dissimilarity Tests of Microbial Communities of Different Fish Species Eggs Based on Jaccard and Bray–Curtis Distance.

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Table 4: Bray–Curtis Dissimilarity Between Visit 1 and Visit 2, According to Socioeconomic Status and Antibiotic Exposures for Vaginal, Oral, and Gut Body Sites.

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Figure S3: Dendrogram Based on a Bray-Curtis Dissimilarity of Dinoflagellate Communities Along the Songhua River

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Figure 2: Bray–Curtis Dissimilarity Measure for Visit 1 and Visit 2 by Body Site.

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Figure 6: Relationship Between Troglobitic Community Dissimilarity (Bray–Curtis Distance) and Geographic Distance Resistance Distance.

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Which Horses Are Most Susceptible to the Initial Natural Training?

Annals of Animal Science

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Table 3: Dissimilarity Percentages (Lower Diagonal) and the Two Diet Items That Contributed the Most to the Dissimilarity in Diet Between Sites (Upper Diagonal).

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Which Extra-Tropical Cyclones Contribute Most to the Transport of Moisture in the Southern Hemisphere?

Journal of Geophysical Research: Atmospheres

2019

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Amanote Research

Table 4: List of Species Which Contribute Most to the Bray-Curtis Dissimilarity Matrices for the 2013 Mat Survey and the 2014 Natural Experiment.

doi 10.7717/peerj.3080/table-4

Full Text

Abstract

Date

Authors

Publisher

Related search

Table 4: Summary of Similarity Percentage Analysis (SIMPER) Listing Species That Cumulatively Contribute 90% to the Dissimilarity (Bray Curtis) of the Two Underwater Visual Sampling Methods Based on Square-Root Transformed Density Data.

Table 1: Dissimilarity Tests of Microbial Communities of Different Fish Species Eggs Based on Jaccard and Bray–Curtis Distance.

Table 4: Bray–Curtis Dissimilarity Between Visit 1 and Visit 2, According to Socioeconomic Status and Antibiotic Exposures for Vaginal, Oral, and Gut Body Sites.

Figure S3: Dendrogram Based on a Bray-Curtis Dissimilarity of Dinoflagellate Communities Along the Songhua River

Figure 2: Bray–Curtis Dissimilarity Measure for Visit 1 and Visit 2 by Body Site.

Figure 6: Relationship Between Troglobitic Community Dissimilarity (Bray–Curtis Distance) and Geographic Distance Resistance Distance.

Which Horses Are Most Susceptible to the Initial Natural Training?

Table 3: Dissimilarity Percentages (Lower Diagonal) and the Two Diet Items That Contributed the Most to the Dissimilarity in Diet Between Sites (Upper Diagonal).

Which Extra-Tropical Cyclones Contribute Most to the Transport of Moisture in the Southern Hemisphere?