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Shrub Growth, NPP, and Nitrogen Assimilation for Two Years in an Alberta Peatland Subjected to Increasing Nitrogen Deposition, 2014-2015

General Information
Data Package:
Local Identifier:edi.259.1
Title:Shrub Growth, NPP, and Nitrogen Assimilation for Two Years in an Alberta Peatland Subjected to Increasing Nitrogen Deposition, 2014-2015
Alternate Identifier:DOI PLACE HOLDER
Abstract:

Development of the oil sands has led to increasing atmospheric N deposition, with values as high as 17 kg N ha-1 yr-1; regional background levels <2 kg N ha-1 yr-1. Bogs, being ombrotrophic, may be especially susceptible to increasing N deposition. To examine responses to N deposition, over five years, we experimentally applied N (as NH4NO3) to a bog near Mariana Lakes, Alberta, at rates of 0, 5, 10, 15, 20, and 25 kg N ha-1 yr-1, plus controls (no water or N addition). In July of each year, we collected new growth of the three shrub species, returned them to the lab, and analyzed them. Non-destructive measurement of aboveground NPP for the three dominant shrub species, Andromeda polifolia, Chamaedaphne calyculata, and Rhododendron groenlandicum was based on allometric equations developed. Results for species were varied, however, water addition alone had no significant effect on NPP for any of the species or for the dominant shrubs combined in either 2014 or 2015 (p >= 0.47).

The mass of newly produced shoot segments for Chamaedaphne calyculata, Andromeda polifolia, Rhododendron groenlandicum, and these three dominant shrubs combined all increased with increasing N input (Fig. 7A-D). As N input increased, the number of newly produced shoots (vegetative buds m-2) increased linearly for A. polifolia and the three shrub species combined. The number of newly produced shoots increased up to 16.6 ± 2.5 kg N ha-1 yr-1 and then decreased for C. calyculata and was unaffected for R. groenlandicum (Fig. 7E-H). Shrub growth response to increased N could lead to a shading out of the underlayer of mosses changing the bog and potentially compromising its structure and function.

Publication Date:2019-01-04

Time Period
Begin:
2014-07-01
End:
2015-07-01

People and Organizations
Contact:Wieder, Kelman R (Villanova University) [  email ]
Creator:Wieder, Kelman R (Villanova University)
Creator:Vitt, Dale H (Southern Illinois University)
Creator:Vile, Melanie A (Villanova University)
Creator:Graham, Jeremy A (Southern Illinois University)
Creator:Hartsock, Jeremy A (Southern Illinois University)
Creator:Fillingim, Hope (Villanova University)
Creator:House, Melissa (Southern Illinois University)
Creator:Quinn, James C (Villanova University)
Creator:Scott, Kimberli D (Villanova University)
Creator:Petix, Meaghan (Southern Illinois University)
Creator:McMillen, Kelly J (Villanova University)

Data Entities
Data Table Name:
Shrub_growth_data.csv
Description:
Shrub Growth Data
Detailed Metadata

Data Entities


Data Table

Data:https://pasta-s.lternet.edu/package/data/eml/edi/259/1/9c143c2a07426e102ba26cd90a56d09f
Name:Shrub_growth_data.csv
Description:Shrub Growth Data
Number of Records:42
Number of Columns:19

Table Structure
Object Name:Shrub_growth_data.csv
Size:4804 byte
Authentication:d9b15083d9ad6b778206aca73f9b6a20 Calculated By MD5
Text Format:
Number of Header Lines:1
Record Delimiter:\r
Orientation:column
Simple Delimited:
Field Delimiter:,

Table Column Descriptions
 
Column Name:YEAR  
NOMINAL_N_TREATMENT  
ARM  
Andromeda_polifolia_new_segment_mass  
Andromeda_polifolia_new_segment_density  
Andromeda_polifolia_net_primary_production  
Andromeda_polifolia_N_assimilation  
Chamaedaphne_calyculata_new_segment_mass  
Chamaedaphne_calyculata_new_segment_density  
Chamaedaphne_calyculata_net_primary_production  
Chamaedaphne_calyculata_N_assimilation  
Rhododendron_groenlandicum_new_segment_mass  
Rhododendron_groenlandicum_new_segment_density  
Rhododendron_groenlandicum_net_primary_production  
Rhododendron_groenlandicum_N_assimilation  
A_polifolia_and_C_calyculata_R_groenlandicum_new_segment_mass  
A_polifolia_and_C_calyculata_and_R_groenlandicum_new_segment_density  
A_polifolia_and_C_calyculata_and_R_groenlandicum_net_primary_production  
A_polifolia_and_C_calyculata_and_R_groenlandicum_N_assimilation  
Definition:Year of growth: 2011-2015Field experimental N treatments were made with 8 applications per plot per year between mid May and mid August of each yearExperimental plots were located along 3 arms; each arm had one replicate each of 8 N treatmentsDried mass of new growth segments of Andromeda polifoliaNumber of new growth segments of A. polifolia counted in each plot per meter squaredPlot level net primary production calculated as the product of the mean mass per growth segment and average number of segments per areaNitrogen assimilated into plant tissue on a per area, per year basisDried mass of new growth segments of C. CalyculataAll new growth segments of C. Calyculata counted in plot and reported as per meterPlot level net primary production calculated as the product of the mean mass per growth segment and average number of segments per area production calculated as the product of the mean mass per growth segment and average number of segments per areaNitrogen assimilated into plant tissue on a per area, per year basisDried mass of new growth segments of R. groenlandicumAll new growth segments of R. groenlandicum counted in plot and reported as per meterPlot level net primary production of R. groenlandicum calculated as the product of the mean mass per growth segment and average number of segments per areaNitrogen assimilated into plant tissue of R. groenlandicum on a per area, per year basisDried mass of new growth segments of A. polifolia, C. calyculata, and R. groenlandicumAll new growth segments of A. polifolia, C. calyculata, and R. groenlandicum counted in plot and reported as per meterPlot level net primary production of A. polifolia, C. calyculata, and R. groenlandicum calculated as the product of the mean mass per growth segment and average number of segments per areaSum of Nitrogen assimilated into plant tissue of A. polifolia, C. calyculata, and R. groenlandicum on a per area, per year basis
Storage Type:date  
string  
string  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
float  
Measurement Type:dateTimenominalnominalratioratioratioratioratioratioratioratioratioratioratioratioratioratioratioratio
Measurement Values Domain:
FormatYYYY
Precision
Allowed Values and Definitions
Enumerated Domain 
Code Definition
CodeC
DefinitionControl, no water, no N added
Source
Code Definition
Code0
Definition0 kg N/ha/yr added as NH4NO3
Source
Code Definition
Code10
Definition10 kg N/ha/yr added as NH4NO3
Source
Code Definition
Code15
Definition15 kg N/ha/yr added as NH4NO3
Source
Code Definition
Code20
Definition20 kg N/ha/yr added as NH4NO3
Source
Code Definition
Code25
Definition25 kg N/ha/yr added as NH4NO3
Source
Code Definition
Code5
Definition5 kg N/ha/yr added as NH4NO3
Source
Allowed Values and Definitions
Enumerated Domain 
Code Definition
Code1
DefinitionArm 1
Source
Code Definition
Code2
DefinitionArm 2
Source
Code Definition
Code3
DefinitionArm 3
Source
Unitgram
Typereal
Min0.06 
Max0.2 
UnitnumberPerMeterSquared
Typereal
Min14.9 
Max134.7 
UnitgramsPerMeterSquaredPerYear
Typereal
Min1.09 
Max20.2 
UnitgramsPerMeterSquaredPerYear
Typereal
Min0.18 
Max3.01 
Unitgram
Typereal
Min0.08 
Max0.24 
UnitnumberPerMeterSquared
Typereal
Min
Max172.1 
UnitgramsPerMeterSquaredPerYear
Typereal
Min1.56 
Max19.16 
UnitgramsPerMeterSquaredPerYear
Typereal
Min0.29 
Max3.56 
Unitgram
Typereal
Min0.06 
Max0.19 
UnitnumberPerMeterSquared
Typereal
Min11.3 
Max162.8 
UnitgramsPerMeterSquaredPerYear
Typereal
Min1.49 
Max24.83 
UnitgramsPerMeterSquaredPerYear
Typereal
Min0.21 
Max4.13 
Unitgram
Typereal
Min0.23 
Max0.51 
UnitnumberPerMeterSquared
Typereal
Min118.2 
Max333.5 
UnitgramsPerMeterSquaredPerYear
Typereal
Min11.14 
Max50.48 
UnitgramsPerMeterSquaredPerYear
Typereal
Min1.64 
Max8.74 
Missing Value Code:
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Code-99999
ExplMissing value
Accuracy Report:                                      
Accuracy Assessment:                                      
Coverage:                                      
Methods:                                      

Data Package Usage Rights

This data package is released to the “public domain” under Creative Commons CC0 1.0 “No Rights Reserved” (see: https://creativecommons.org/publicdomain/zero/1.0/). It is considered professional etiquette to provide attribution of the original work if this data package is shared in whole or by individual components. A generic citation is provided for this data package on the website https://portal.edirepository.org (herein “website”) in the summary metadata page. Communication (and collaboration) with the creators of this data package is recommended to prevent duplicate research or publication. This data package (and its components) is made available “as is” and with no warranty of accuracy or fitness for use. The creators of this data package and the website shall not be liable for any damages resulting from misinterpretation or misuse of the data package or its components. Periodic updates of this data package may be available from the website. Thank you.

Keywords

By Thesaurus:
(No thesaurus)Villanova Peatland Biogeochemistry Group, bog, shrub, vascular, shoot growth, nitrogen, NPP

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:

Non-destructive measurement of aboveground NPP for the three dominant shrub species, Andromeda polifolia, Chamaedaphne calyculata, and Rhododendron groenlandicum was based on allometric equations developed after destructively sampling 50 new growth segments (shoots with leaves), thereby collecting all mass from the most recent bud scar collected in late July 2014, for each of the three species. For each growth segment, we measured total length (mm), counted the number of leaves, measured the length and width of each leaf (mm), and dried each of the growth segments at 55 C for 5 days before weighing. From these measurements, for each species, we developed an allometric equation that gave the best linear fit to the measured mass per growth segment (MPS; mg segment-1). These allometric equations (all significant, p < 0.01) are for A. polifolia:

MPS = 0.646xSqrt(0.5xLLAx0.5xLLWxπxSLxLPS) - 17.2; R2 = 0.86,

for C. calyculata:

MPS = 0.523xSqrt(0.5xLLAx0.5xLLWxπxSLxLPS) - 20.0; R2 = 0.92,

and for R. groenlandicum:

MPS = 0.712xSqrt(0.5xLLAx0.5xLLWxπxSLxLPS) - 10.0; R2 = 0.85,

where LLA is the average length of leaves per segment (mm), LLW is the average width of leaves per segment (mm), SL is segment length (cm), and LPS is the number of leaves per segment.

In the second week of June 2014, we determined the density of the new growth segments (segments m-2) by counting all the new growth segments for each of the selected species in each 7.2 m2 plot. In the last week of July 2014, we measured new growth segment lengths, number of leaves, and leaf dimensions for 5 individual segments of each of the species per plot, and calculated MPS. We calculated plot-level aboveground NPP (g m-2 yr-1) for each species as the product of the mean MPS (g segment-1 yr-1) and the density of new growth segments (segments m-2).

In 2015, we revised the allometric growth metrics to allow for more shoots per plot to be measured by overcoming the time constraints imposed by measuring the dimensions of each leaf per shoot. Using the average leaf area (calculated as the area of an ellipse using the leaf dimensions) of all measured leaves for each species per plot, the revised allometric equations (all significant, p < 0.01) for mass per growth segment (MPSb, mg segment-1) are for A. polifolia:

MPSb = 0.3xSqrt((ALA+LLA)2xSLxLPS)+0.2; R2 = 0.85,

for C. calyculata:

MPSb = 0.01xSqrt((ALA+LLA)2xSLxLPS)+8.3; R2 = 0.91,

and for R. groenlandicum:

MPSb = 0.002xSqrt((ALA+LLA)2xSLxLPS)+4.3; R2 = 0.85,

where ALA is the average leaf area for a new growth segment (mm2), LLA is the area of the largest leaf on a segment (mm2), SL is segment length (cm), and LPS is the number of leaves per segment.

In late July 2015, we measured five plants of each species per plot as in 2014, in addition to 15 new growth segments per species measuring length of the new shoot, number of leaves, and dimensions of the largest leaf. In the second week of June 2015, we counted shoot densities in the same manner as 2014. We found no significant differences in predicted new growth segment masses between the original and revised models. In 2015, we calculated aboveground NPP for each species as the product of shoot density and the mean of the 20 derived new shoot masses.

We collected samples of new vascular plant growth in 2011-2015 (current year growth leaves or needles). We marked individuals from which leaves were collected to avoid resampling in subsequent years. All samples for N analysis were sorted for removal of debris, dried for a minimum of 6 days at 55 C, homogenized in a Thomas Wiley Mini-Mill, and analyzed on a Flash EA 1112 Series CN Soil Analyzer.

People and Organizations

Creators:
Individual: Kelman R Wieder
Organization:Villanova University
Email Address:
kelman.wieder@villanova.edu
Id:https://orcid.org/0000-0001-5856-8473
Individual: Dale H Vitt
Organization:Southern Illinois University
Individual: Melanie A Vile
Organization:Villanova University
Email Address:
mvile@villanova.edu
Individual: Jeremy A Graham
Organization:Southern Illinois University
Email Address:
jeremyg@mtu.edu
Individual: Jeremy A Hartsock
Organization:Southern Illinois University
Email Address:
hartsock@siu.edu
Individual: Hope Fillingim
Organization:Villanova University
Email Address:
fillingimhope@gmail.com
Individual: Melissa House
Organization:Southern Illinois University
Email Address:
mhouse@siu.edu
Individual: James C Quinn
Organization:Villanova University
Email Address:
jcqui03@gmail.com
Individual: Kimberli D Scott
Organization:Villanova University
Email Address:
kscott@villanova.edu
Individual: Meaghan Petix
Organization:Southern Illinois University
Email Address:
meaghan.petix@wsu.edu
Individual: Kelly J McMillen
Organization:Villanova University
Email Address:
Kelly.Mcmillen@ttu.edu
Contacts:
Individual: Kelman R Wieder
Organization:Villanova University
Email Address:
kelman.wieder@villanova.edu
Id:https://orcid.org/0000-0001-5856-8473

Temporal, Geographic and Taxonomic Coverage

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

Time Period
Begin:
2014-07-01
End:
2015-07-01
Sampling Site: 
Description:Alberta, Canada, 100 km south of Fort McMurray, Canada
Site Coordinates:
Longitude (degree): 112.094Latitude (degree): 55.895
Taxonomic Range:
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:subkingdom
Rank Value:Viridiplantae
Classification:
Rank Name:infrakingdom
Rank Value:Streptophyta
Classification:
Rank Name:superdivision
Rank Value:Embryophyta
Classification:
Rank Name:division
Rank Value:Tracheophyta
Classification:
Rank Name:subdivision
Rank Value:Spermatophytina
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:superorder
Rank Value:Asteranae
Classification:
Rank Name:order
Rank Value:Ericales
Classification:
Rank Name:family
Rank Value:Ericaceae
Classification:
Rank Name:genus
Rank Value:Rhododendron
Classification:
Rank Name:species
Rank Value:Rhododendron groenlandicum
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:subkingdom
Rank Value:Viridiplantae
Classification:
Rank Name:infrakingdom
Rank Value:Streptophyta
Classification:
Rank Name:superdivision
Rank Value:Embryophyta
Classification:
Rank Name:division
Rank Value:Tracheophyta
Classification:
Rank Name:subdivision
Rank Value:Spermatophytina
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:superorder
Rank Value:Asteranae
Classification:
Rank Name:order
Rank Value:Ericales
Classification:
Rank Name:family
Rank Value:Ericaceae
Classification:
Rank Name:genus
Rank Value:Andromeda
Classification:
Rank Name:species
Rank Value:Andromeda polifolia
Classification:
Rank Name:kingdom
Rank Value:Plantae
Classification:
Rank Name:subkingdom
Rank Value:Viridiplantae
Classification:
Rank Name:infrakingdom
Rank Value:Streptophyta
Classification:
Rank Name:superdivision
Rank Value:Embryophyta
Classification:
Rank Name:division
Rank Value:Tracheophyta
Classification:
Rank Name:subdivision
Rank Value:Spermatophytina
Classification:
Rank Name:class
Rank Value:Magnoliopsida
Classification:
Rank Name:superorder
Rank Value:Asteranae
Classification:
Rank Name:order
Rank Value:Ericales
Classification:
Rank Name:family
Rank Value:Ericaceae
Classification:
Rank Name:genus
Rank Value:Chamaedaphne
Classification:
Rank Name:species
Rank Value:Chamaedaphne calyculata

Project

Parent Project Information:

Title:Nitrogen Addition Experiments in Boreal Ecosystems: Understanding the Fate of Atmospherically Deposited Nitrogen in order to Determine Nitrogen Critical Loads
Personnel:
Individual: Kelman Wieder
Email Address:
kelman.wieder@villanova.edu
Id:https://orcid.org/0000-0001-5856-8473
Role:Principal Investigator
Funding: Cumulative Environmental Management Association (CEMA): 2011-0003

Maintenance

Maintenance:
Description:completed
Frequency:
Other Metadata

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

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