Data Package Metadata   View Summary

Annual precipitation and photo-derived vegetation and litter cover (2013-2021) used for analysis in the manuscript “Growing grasses in the desert: cross-scale interactions LEAD TO STATE CHANGE REVERSAL in DRYLANDs”

General Information
Data Package:
Local Identifier:knb-lter-jrn.210413008.1
Title:Annual precipitation and photo-derived vegetation and litter cover (2013-2021) used for analysis in the manuscript “Growing grasses in the desert: cross-scale interactions LEAD TO STATE CHANGE REVERSAL in DRYLANDs”
Alternate Identifier:DOI PLACE HOLDER
Abstract:

This dataset contains annual precipitation collected from meterological stations and vegetation cover values derived from overhead photos of connectivity modifier treatments, or "Conmods," deployed in a long-term experiment at the Jornada Basin LTER site in southern New Mexico, U.S.A. Conmods were installed in 2013 at 15 experimental blocks, each with 4 plots under different landscape connectivity treatments. Litter, soil, and vegetation accumulation inside Conmods was monitored by taking repeat photographs and analyzing them to yield percentage cover of different cover and vegetation types. Daily precipitation data from 13 meterological stations were used to calculate annual, wateryear (october-september), and growing season precipitation from 2013 through 2021. These data are part of a larger experiment where vegetation cover was estimated on plots where shrubs were killed in-place using an herbicide or a combination of shrub mortality and ConMods was conducted. Control plots did not have manipulations.

Short Name:CSIS_Peters_et_al_2023_1
Publication Date:2023-09-20
Language:English
For more information:
Visit: https://jrn.lternet.edu
Visit: DOI PLACE HOLDER

Time Period
Begin:
2013
End:
2021

People and Organizations
Contact:Information Manager (Jornada Basin LTER Program) [  email ]
Creator:Peters, Debra C (USDA-ARS Jornada Experimental Range)
Creator:Burruss, Nathan D. (New Mexico State University, Jornada Basin LTER)
Creator:Anderson, John (New Mexico State University, Jornada Basin LTER, Jornada Research Site Manager)
Associate:Savoy, Heather (USDA-ARS Jornada Experimental Range, data analyst)
Associate:James, Darren (USDA-ARS Jornada Experimental Range, data analyst)
Associate:JRN field crew,  (Jornada Basin LTER, New Mexico State University, Jornada Basin LTER Field Crew, field data collection)
Associate:Campanella, Andrea (New Mexico State University, Jornada Basin LTER, field data collection)
Associate:Brennan, James (New Mexico State University, Jornada Basin LTER, field data collection)
Associate:Gename, Kyle (New Mexico State University, Jornada Basin LTER, field data collection)

Data Entities
Data Table Name:
Overhead photo cover estimates table
Description:
Data table used for the analyses in GROWING GRASSES IN THE DESERT: CROSS-SCALE INTERACTIONS LEAD TO STATE CHANGE REVERSAL IN DRYLANDS manuscript.
Detailed Metadata

Data Entities


Data Table

Data:https://pasta-s.lternet.edu/package/data/eml/knb-lter-jrn/210413008/1/651f76398d517f6a65515d9265720b86
Name:Overhead photo cover estimates table
Description:Data table used for the analyses in GROWING GRASSES IN THE DESERT: CROSS-SCALE INTERACTIONS LEAD TO STATE CHANGE REVERSAL IN DRYLANDS manuscript.
Number of Records:2160
Number of Columns:9

Table Structure
Object Name:jrn413008_OH_data_combined_block.csv
Size:145185 byte
Authentication:47c7abd216df9858bbc32abec756eb79 Calculated By MD5
Text Format:
Number of Header Lines:1
Number of Foot Lines:0
Record Delimiter:\n
Orientation:column
Simple Delimited:
Field Delimiter:,
Quote Character:"

Table Column Descriptions
 YearBlockVeg typeTreatmentPercent coverWater year precipShrub cover 2011Litter areaVertical accumulation
Column Name:year  
block  
type  
treatment  
cover_pct  
ppt_cm_wy  
shrub_2011  
area_avg_cm2  
vert_acc_2017  
Definition:Year of observationExperimental block number (1-15)Vegetation cover typeTreatment levelCalculated cover value from overhead images of ConMods.Total wateryear (October - September) precipitationThe average shrub cover for each block prior to the study (2011)The area of accumulation of litter and soil in lateral images of ConMods.The 2017 average difference in vertical accumulation from initial values (2013) by block
Storage Type:date  
integer  
string  
string  
float  
float  
float  
float  
float  
Measurement Type:dateTimeintervalnominalnominalratioratioratioratioratio
Measurement Values Domain:
FormatYYYY
Precision1
Unitnumber
Typeinteger
Allowed Values and Definitions
Enumerated Domain 
Code Definition
Codepgrass_alive
DefinitionPerennial grass functional group - alive
Source
Code Definition
Codeagrass_alive
DefinitionAnnual grass functional group - alive
Source
Code Definition
Codelitter
DefinitionLitter cover
Source
Code Definition
Codeforb_alive
DefinitionForb/broadleaved herb functional group - alive
Source
Allowed Values and Definitions
Enumerated Domain 
Code Definition
Codecontrol
DefinitionControl (no treatments applied)
Source
Code Definition
Codeplant
DefinitionPlant-scale treatment - herbicide applied
Source
Code Definition
Codepatch
DefinitionPatch-scale treatment - ConMods added
Source
Code Definition
Codeplant&patch
DefinitionPlant- and patch-scale treatment - herbicide applied AND ConMods added
Source
Unitpercent
Typereal
Unitcentimeter
Typereal
Unitpercent
Typereal
UnitcentimeterSquared
Typereal
UnitcentimeterSquared
Typereal
Missing Value Code:              
CodeNA
ExplMissing value - data not collected or otherwise unavailable
 
Accuracy Report:                  
Accuracy Assessment:                  
Coverage:                  
Methods:                  

Data Package Usage Rights

This information is released under the Creative Commons license - Attribution - CC BY (https://creativecommons.org/licenses/by/4.0/). The consumer of these data ("Data User" herein) is required to cite it appropriately in any publication that results from its use. The Data User should realize that these data may be actively used by others for ongoing research and that coordination may be necessary to prevent duplicate publication. The Data User is urged to contact the authors of these data if any questions about methodology or results occur. Where appropriate, the Data User is encouraged to consider collaboration or co-authorship with the authors. The Data User should realize that misinterpretation of data may occur if used out of context of the original study. While substantial efforts are made to ensure the accuracy of data and associated documentation, complete accuracy of data sets cannot be guaranteed. All data are made available "as is." The Data User should be aware, however, that data are updated periodically and it is the responsibility of the Data User to check for new versions of the data. The data authors and the repository where these data were obtained shall not be liable for damages resulting from any use or misinterpretation of the data. Thank you.

Keywords

By Thesaurus:
LTER Core Research Areasland use and land cover change
LTER Controlled Vocabulary v1deserts, land cover, landscape change, plant cover, precipitation, wind
noneJRN LTER, Jornada Basin LTER, connectivity
Jornada Basin project namesCSIS, Cross Scale Interactions Study, LTER, study 413
Jornada Basin place namesCSIS, Pasture 9

Methods and Protocols

These methods, instrumentation and/or protocols apply to all data in this dataset:

Methods and protocols used in the collection of this data package
Description:

Plot selection and manipulations

Our experimental design consisted of 15 - 1 ha blocks spatially distributed across the study area selected to have similar total percentage vegetation cover within a block, but to vary in the proportion of perennial grass and mesquite cover among blocks. Potential experimental block locations were identified using two approaches that used either percentage bare ground or change in vegetation through time; we then combined the two approaches for final plot selection. First, percentage bare ground across the grassland-shrubland gradient was estimated for contiguous 20 m x 20 m grid cells using an NDVI analysis of a 2003 QuickBird imagery. Each grid cell was classified into one of five classes of bare ground cover (0 to <20%, 20 to <40%, 40 to <60%, 60 to <80%, 80 to 100%) used to delineate contiguous 1-ha regions for each class. Thirty grid cells from each class (30 cells x 5 classes = 150 cells) were randomly selected as the preliminary pool of block locations. These grid cells were then reclassified as either low (0 to 30%), medium (33 to 67%), or high (67 to 100%) bare ground. Second, the change in NDVI from 2003 to 2010 from another Quickbird image was used to capture vegetation change following a series of years with above-average precipitation (2004 to 2010; (52)). The 2010 Quickbird image was separated into the same 20 m x 20 m grid cells as the 2003 image used for bare ground classes, and NDVI was calculated for each grid cell. The difference in NDVI from 2003 to 2010 was used to classify each cell into either low (0-33%), medium (33-67%), or high percentage vegetation cover (67-100%). Ten potential locations were randomly identified for each of the nine combinations of percentage bare ground and change in NDVI classes. Four grid cells were selected in each of the nine classes for a total of 36 locations to ensure that candidate block locations were arrayed across the study area. Ground-truthing of bare gap size distribution using a standard gap intercept method was conducted for the final pool of 30 candidate block locations (44). The final 15 block locations were chosen to characterize a gradient in grass and mesquite shrub cover. At each block location, four 15m x 25m plots were identified with similar percentage grass and shrub cover with a focal patch in the center. Plots were arrayed perpendicular lengthwise to the dominant southwest to northeast wind direction, and were >15 m apart to minimize between-plot treatment effects.

Experimental design

Each plot within a block was randomly assigned to one of four connectivity treatments: (1) plant scale where all mesquite plants within and surrounding the focal patch were killed in place to modify competitive interactions between woody plants and recovery of perennial grasses and other herbaceous plants with no direct effects on horizontal transport by wind and water, (2) patch scale where ConMods were located in bare soil interspaces between plants in the focal patch to reduce gap size and to modify transport of water, soil, nutrients, litter, and herbaceous seeds, (3) both patch- and plant-scale manipulations were conducted in each focal patch, and (4) no manipulations [controls].

Block and plot selection were completed in June 2012 followed by the characterization of initial vegetation cover in all plots in June 2013 when treatments were initiated. For plant-scale manipulations, mesquite plants were killed using a direct application of a clopyralid herbicide (Reclaim; Dow AgroSciences) in early summer 2013 ca. one month after leaf out (53). This herbicide was chosen because it does not affect herbaceous plants, is relatively nontoxic to wildlife (see MSDS D03-106-606), and readily biodegradable with a half-life of 1.4 days. Effects of dead mesquite roots on soil moisture and soil organic matter were temporary because decomposition rates of roots in arid systems are equal to or faster than mesic systems (54). Herbicide reapplication was conducted in August 2013 to ensure the mortality of mesquite plants surrounding the focal patch as well as woody plants within a larger area were treated (ca. 15m x 15m) because mesquite plants have an extensive horizontal rooting system (55). Herbicide spot treatment of mesquite was done annually where needed; there were few plants with regrowth and all basal; none after 2017.

For patch-scale manipulations, each focal patch was divided into 1m2 grid cells, and ConMods (Connectivity Modifiers; (23)) were spatially distributed in grid cells to reduce gap sizes between live perennial plants to < 0.5 m. The minimum number of ConMods was added to a patch to meet this criterion. This size is sufficient to minimize erosional losses across a patch (43). Reducing bare gap size in a patch below this threshold allows the accumulation of litter, seeds, and soil to stabilize the soil surface and improves soil water conditions sufficiently to allow herbaceous plant establishment within ConMod structures (23). These fine-mesh (1 cm2), 50 cm wide x 20 cm tall obstructions reduce horizontal transport of material by wind and water, yet they do not influence cover of living plants outside of a patch (22, 51). For plots examining the combined effects of plant- and patch-scale treatments, mesquite plants were killed in place by the herbicide and ConMods were located inside the focal patch. For Control plots, mesquite plants were not treated by herbicide and ConMods were not placed inside the focal patch. A similar array of 1 m2 contiguous grid cells was located across each focal patch. Sampling locations were selected to reduce gap sizes between live plants to <0.5 m.

Plant-scale manipulations (+WPI)

At the plant scale, repeat photos of ten randomly selected ConMods and ten randomly selected control points were taken annually at peak growing season (September) from 2013 to 2021. Standardized overhead photos were used to estimate perennial grass cover as our response variable, and cover of forbs (annual and perennial), annual grasses, and litter as fine-scale factors that could influence grass cover by providing favorable microhabitats for grass seedlings (litter) or by competing with perennial grass plants (forbs, annual grasses). Overhead photos were collected from 2013 to 2021, and image analysis software was used to classify 100 random points by species, soil or litter (USDA SamplePoint software; (56)). Species cover in each year was summed to obtain functional group cover: annual grasses or forbs. For perennial grasses, we analyzed each species separately and the total. Rain use efficiency was calculated as the amount of perennial grass cover produced per unit of rainfall (26).

Patch-scale manipulations (+WPa)

Lateral photos obtained from the same locations as overhead photos were used to show the redistribution of soil and litter by wind and water from bare interspaces to ConMods or to herbaceous plant canopies. Lateral imagery was collected from 2013 to 2017 at ground level from each cardinal direction to estimate the vertical accumulation of soil and litter (hereafter "litter"). The area between the tops and sides of each ConMod’s outer rods and the top contour of the combined litter and soil surface was determined (methods described in (23) (SimgaScan pro 5.0: Systat Software, Inc. San Jose, CA USA) using Trace Measurement Mode with Area and Distance measurement options. The area difference between years for the same ConMod was a measure of the change in vertical accumulation of litter or soil. Lateral photos were discontinued after 2017 when density and cover of herbaceous plants made the analysis of litter and soil accumulation difficult and prone to error.

Landscape-scale factors

Factors at the landscape scale were initial shrub cover based on the 2011 Quickbird image (described above), and annual precipitation. Daily precipitation data from 13 weather stations spatially distributed throughout the study area were summed for the water year (1 October to 31 September) preceding vegetation and material accumulation measurements, and used as the precipitation variable. For each block, precipitation from the nearest weather station was used in the analysis.

Statistical analyses

To examine both the within- and across-block (site) effects of treatment on perennial grass, RUE, Bouteloua eriopoda, and Sporobolus flexuosus cover, we constructed two mixed-effects ANOVA models (nlme R package; (57)). Across-site differences in treatment effects were tested by including site and treatment as fixed effects, and time and block as random effects. Within-site differences in treatment effects were tested using only treatment as a fixed effect. To determine which treatment differences are statistically significant, a post-hoc comparison of significant mixed-effects ANOVA was conducted using the lsmeans R package (58).

Models of perennial grass cover through time were compared using simple linear models, logistic models, and split linear models. Logistic models were fit using the drc package in R (59) and the pseudo r-squared was calculated as the squared correlation of fitted values to observed values. For split line regressions, the breakpoint was determined for each treatment set using the segmented function of base R. Psuedo r-squared was used to assess how well each model explains the observed data and, following the approach described in (27), AIC was used to assess each model’s predictive ability and characterize perennial grass response to treatment. AIC support for linear models (lowest value) was interpreted as evidence for linear internal dynamics (20), support for logistic models as evidence for logistic growth associated with a rapidly changing driver (60), and support for split line models as evidence of alternative attractors (61).

Covariates assessed in this study were examined across three distinct temporal (initial, lagged 1-year, and current) and spatial (plant, patch, and landscape) scales. Initial conditions included: the plant-scale effects of the 2017 perennial grass cover (%) measured from overhead imagery of ConMods, patch-scale influences of vertical accumulation of soil and litter (cm2) estimated from lateral photos, and landscape-scale processes represented by estimating the percentage of shrub cover in each block during 2011. Lagged relationships at the plant scale were represented using the percent cover of annual grasses, forbs, and litter estimated from overhead imagery in the previous year. Current conditions at the plant scale were reflected through annual grass cover, forb cover, and litter cover in the current year. For landscape-scale factors, we considered total water year precipitation (cm). Univariate relationships between perennial grass cover and covariates were assessed by fitting separate linear regression models for each year and treatment. The model-based slopes and standard errors of the slopes were then plotted to illustrate changes in univariate relationships through time.

To examine which factors were important in predicting perennial grass cover through time, we compared repeated-measures regression models that estimated cover for each treatment using the MuMIn package (62). Competing models were constructed by assembling unique combinations of 8 explanatory variables with different characteristic spatial and temporal scales (initial conditions: plant scale (perennial grass cover in 2017), patch scale (soil and litter accumulation in 2017), landscape-scale (woody plant cover 2011); current conditions: plant scale (litter) and landscape scale (precipitation), and time lag variables (t-1): plant scale (annual grass cover, forb cover, litter cover). For each model, the additive effects of variables were fixed effects, and time|block were treated as random effects. Additionally, a null model with zero slope for each treatment was included in each suite of competing model to establish a baseline for comparisons. We used Akiake’s information criterion (AIC) to compare models estimating grass cover through time, and because this approach balances parsimony against model fit and complexity, models with lower AIC can typically be regarded as more reflective of the underlying internal dynamics (27). For each treatment, the best-performing models were selected (ΔAIC < 2 indicating a high degree of empirical support (63)). From those, models with infrequently occurring variables (occurring in < 30% of subset) were removed and the model with the lowest AIC was selected. For each selected model, the estimated relative importance of each variable was calculated by summing the AIC weights across all models containing variable x (64). All analyses were conducted in R (version 4.2.2: R Core Team 2022). We interpreted the strength of evidence using p ≤ 0.05 (65).

People and Organizations

Publishers:
Organization:Environmental Data Initiative
Email Address:
info@edirepository.org
Web Address:
https://edirepository.org
Id:https://ror.org/0330j0z60
Creators:
Individual: Debra C Peters
Organization:USDA-ARS Jornada Experimental Range
Email Address:
deb.peters@usda.gov
Id:https://orcid.org/0000-0002-5842-8099
Individual: Nathan D. Burruss
Organization:New Mexico State University, Jornada Basin LTER
Email Address:
dylanb@nmsu.edu
Id:https://orcid.org/0000-0002-7682-2401
Individual: John Anderson
Organization:New Mexico State University, Jornada Basin LTER
Position:Jornada Research Site Manager
Email Address:
janderso@jornada.nmsu.edu
Id:https://orcid.org/0000-0002-6417-8022
Contacts:
Organization:Jornada Basin LTER Program
Position:Information Manager
Address:
P.O. Box 30003; MSC 3JER New Mexico State University,
Las Cruces, NM 88003-8003 U.S.A.
Phone:
575-322-2430
Email Address:
jornada.data@nmsu.edu
Web Address:
https://lter.jornada.nmsu.edu/information-management/
Associated Parties:
Individual: Heather Savoy
Organization:USDA-ARS Jornada Experimental Range
Id:https://orcid.org/0000-0002-2032-4868
Role:data analyst
Individual: Darren James
Organization:USDA-ARS Jornada Experimental Range
Email Address:
darren.james@usda.gov
Id:https://orcid.org/0000-0002-9936-5549
Role:data analyst
Individual: JRN field crew
Organization:Jornada Basin LTER, New Mexico State University
Position:Jornada Basin LTER Field Crew
Address:
P.O. Box 30003; MSC 3JER New Mexico State University,
Las Cruces, NM 88003-8003 U.S.A.
Role:field data collection
Individual: Andrea Campanella
Organization:New Mexico State University, Jornada Basin LTER
Role:field data collection
Individual: James Brennan
Organization:New Mexico State University, Jornada Basin LTER
Role:field data collection
Individual: Kyle Gename
Organization:New Mexico State University, Jornada Basin LTER
Role:field data collection
Metadata Providers:
Organization:Jornada Basin LTER Program
Position:Jornada Basin LTER program
Address:
P.O. Box 30003; MSC 3JER New Mexico State University,
Las Cruces, NM 88003-8003 USA
Email Address:
jornada.lter@nmsu.edu
Web Address:
https://lter.jornada.nmsu.edu
Id:https://ror.org/05976ta47

Temporal, Geographic and Taxonomic Coverage

Temporal, Geographic and/or Taxonomic information that applies to all data in this dataset:

Time Period
Begin:
2013
End:
2021
Geographic Region:
Description:CSIS in Pasture 9: Bounding box for the Cross-scale Interactions Study in Pasture 9 on the Jornada Experimental Range
Bounding Coordinates:
Northern:  32.604900Southern:  32.559300
Western:  -106.848400Eastern:  -106.762000
Taxonomic Range:
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:phylum
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:order
Rank Value:Fabales
Classification:
Rank Name:family
Rank Value:Fabaceae
Classification:
Rank Name:genus
Rank Value:Prosopis
Classification:
Rank Name:specificEpithet
Rank Value:glandulosa
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:phylum
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:order
Rank Value:Poales
Classification:
Rank Name:family
Rank Value:Poaceae
Classification:
Rank Name:genus
Rank Value:Bouteloua
Classification:
Rank Name:specificEpithet
Rank Value:eriopoda
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:phylum
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:order
Rank Value:Poales
Classification:
Rank Name:family
Rank Value:Poaceae
Classification:
Rank Name:genus
Rank Value:Sporobolus
Classification:
Rank Name:specificEpithet
Rank Value:flexuosus

Project

Parent Project Information:

Title:Jornada Basin LTER
Personnel:
Individual:Dr. Niall Hanan
Address:
P.O. Box 30003, MSC 3JER,
New Mexico State University,
Las Cruces, NM 88003-8003 United States
Phone:
575-646-3335 (voice)
Email Address:
nhanan@nmsu.edu
Role:Principal Investigator
Abstract:

Dryland ecosystems occupy nearly half of the Earth's land surface and provide goods and services for more than 1 billion people. The goal of the Jornada Basin Long Term Ecological Research (LTER) program is to understand what factors determine the structure and function of drylands, and to develop general principles governing changes between grassland and shrubland ecosystems. This research is based on long-term data collected in the Chihuahuan Desert. We translate our findings to dryland ecosystems around the world, and forecast the dynamics of future ecosystem states in response to changing climate and land use.

Funding:

The Jornada LTER program has been continuously funded by the U.S. National Science Foundation since 1982 (Current NSF award: DEB-2025166)

Additional Award Information:
Funder:National Science Foundation
Funder ID:https://ror.org/021nxhr62
Number:DEB 2025166
Title:LTER: Long –Term Research at the Jornada Basin (LTER VII)
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=2025166
Additional Award Information:
Funder:National Science Foundation
Number:DEB 1832194
Title:Prior award: LTER: Long - Term Research at the Jornada Basin (LTER VII)
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=1832194
Additional Award Information:
Funder:National Science Foundation
Number:DEB 1235828
Title:Prior award: LTER: Long-Term Research at the Jornada Basin (LTER-VI)
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=1235828
Additional Award Information:
Funder:National Science Foundation
Number:DEB 0618210
Title:Prior award: Jornada Basin LTER V: Landscape Linkages in Arid and Semiarid Ecosystems
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=0618210
Additional Award Information:
Funder:National Science Foundation
Number:DEB 0080412
Title:Prior award: LTER IV: Jornada Basin: Linkages in Semi-arid Landscapes
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=0080412
Additional Award Information:
Funder:National Science Foundation
Number:DEB 9411971
Title:Prior award: LTER: The Chihuahuan Desert (The Jornada LTER III Consortium)
URL:https://www.nsf.gov/awardsearch/showAward?AWD_ID=9411971
Additional Award Information:
Funder:National Science Foundation
Number:DEB 8811160, 9240261
Title:Prior award: Interactions in Time and Space Variability in a Chihuahuan Desert Ecosystem: Jornada LTER (II)
Additional Award Information:
Funder:National Science Foundation
Number:DEB 8114466, 8612106
Title:Prior award: Interactions of Time and Space Variability in a Chihuahuan Desert Ecosystem in New Mexico (Jornada LTER I)

Maintenance

Maintenance:
Description:complete
Frequency:annually
Other Metadata

Additional Metadata

additionalMetadata
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        |___element 'metadata'
        |     |___text '\n      '
        |     |___element 'unitList'
        |     |     |___text '\n        '
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        |     |     |     |  \___attribute 'abbreviation' = 'cm'
        |     |     |     |  \___attribute 'id' = 'centimeter'
        |     |     |     |  \___attribute 'multiplierToSI' = '0.01'
        |     |     |     |  \___attribute 'name' = 'centimeter'
        |     |     |     |  \___attribute 'parentSI' = 'meter'
        |     |     |     |___text '\n          '
        |     |     |     |___element 'description'
        |     |     |     |     |___text '.01 meters'
        |     |     |     |___text '\n        '
        |     |     |___text '\n        '
        |     |     |___element 'unit'
        |     |     |     |  \___attribute 'abbreviation' = 'cm²'
        |     |     |     |  \___attribute 'id' = 'centimeterSquared'
        |     |     |     |  \___attribute 'multiplierToSI' = '0.0001'
        |     |     |     |  \___attribute 'name' = 'centimeterSquared'
        |     |     |     |  \___attribute 'parentSI' = 'meterSquared'
        |     |     |     |  \___attribute 'unitType' = 'area'
        |     |     |     |___text '\n          '
        |     |     |     |___element 'description'
        |     |     |     |     |___text 'square centimeter'
        |     |     |     |___text '\n        '
        |     |     |___text '\n        '
        |     |     |___element 'unit'
        |     |     |     |  \___attribute 'id' = 'number'
        |     |     |     |  \___attribute 'name' = 'number'
        |     |     |     |  \___attribute 'unitType' = 'dimensionless'
        |     |     |     |___text '\n          '
        |     |     |     |___element 'description'
        |     |     |     |     |___text 'a quantity or amount'
        |     |     |     |___text '\n        '
        |     |     |___text '\n        '
        |     |     |___element 'unit'
        |     |     |     |  \___attribute 'abbreviation' = '%'
        |     |     |     |  \___attribute 'id' = 'percent'
        |     |     |     |  \___attribute 'multiplierToSI' = '1'
        |     |     |     |  \___attribute 'name' = 'percent'
        |     |     |     |  \___attribute 'parentSI' = 'dimensionless'
        |     |     |     |  \___attribute 'unitType' = 'dimensionless'
        |     |     |     |___text '\n          '
        |     |     |     |___element 'description'
        |     |     |     |     |___text 'percent, one part per hundred parts. a decimal ratio multipled by 100'
        |     |     |     |___text '\n        '
        |     |     |___text '\n      '
        |     |___text '\n    '
        |___text '\n  '

EDI is a collaboration between the University of New Mexico and the University of Wisconsin – Madison, Center for Limnology:

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