BCO-DMO | ERDDAP - bcodmo_dataset_894169_v1

Row Type	Variable Name	Attribute Name	Data Type	Value
attribute	NC_GLOBAL	cdm_data_type	String	Other
attribute	NC_GLOBAL	Conventions	String	COARDS, CF-1.6, ACDD-1.3
attribute	NC_GLOBAL	creator_email	String	info at bco-dmo.org
attribute	NC_GLOBAL	creator_name	String	BCO-DMO
attribute	NC_GLOBAL	creator_url	String	https://www.bco-dmo.org/
attribute	NC_GLOBAL	doi	String	10.26008/1912/bco-dmo.894169.1
attribute	NC_GLOBAL	infoUrl	String	https://www.bco-dmo.org/dataset/894169
attribute	NC_GLOBAL	institution	String	BCO-DMO
attribute	NC_GLOBAL	license	String	The data may be used and redistributed for free but is not intended\nfor legal use, since it may contain inaccuracies. Neither the data\nContributor, ERD, NOAA, nor the United States Government, nor any\nof their employees or contractors, makes any warranty, express or\nimplied, including warranties of merchantability and fitness for a\nparticular purpose, or assumes any legal liability for the accuracy,\ncompleteness, or usefulness, of this information.
attribute	NC_GLOBAL	sourceUrl	String	(local files)
attribute	NC_GLOBAL	summary	String	Increased standing macroalgal biomass in upwelling zones is generally assumed to be the result of higher nutrient flux due to upwelled waters. However, other factors can strongly impact macroalgal communities. For example, herbivory and temperature, via their effects on primary producers and the metabolic demands of consumers, can also influence macroalgal biomass and productivity, respectively. Although there are a fair number of studies looking at the interactive effects of herbivores and nutrients in both tropical and temperate regions, there is a lack of studies looking at these effects in tropical or subtropical upwelling regions. The purpose of this study was to measure the effects that herbivores, temperature, and nutrient availability have on standing macroalgal biomass. We manipulated nutrient availability and herbivory in six field experiments during contrasting productivity and thermal regimes (cool-upwelling and warm, non-upwelling season) on a subtidal nearshore rocky reef.\n\nHere, we present the macroalgal biomass raw data (Preburn, Postburn, and Ash-Free Dry Weight) collected in the nearshore shallow subtidal during the six field experiments.
attribute	NC_GLOBAL	title	String	[Cerro Mundo Algal Ash-Free Dry Weight] - Macroalgal biomass data (Preburn, Postburn, and Ash-Free Dry Weight) collected in the nearshore shallow subtidal during six field experiments conducted at Cerro Mundo Bay in the Galapagos Islands between July 2021 and May 2022 (The Role of Temperature in Regulating Herbivory and Algal Biomass in Upwelling Systems)
variable	Trial		String
attribute	Trial	long_name	String	Trial
attribute	Trial	units	String	unitless
variable	Cage		int
attribute	Cage	actual_range	int	1, 64
attribute	Cage	long_name	String	Cage
attribute	Cage	units	String	unitless
variable	Treatment		String
attribute	Treatment	long_name	String	Treatment
attribute	Treatment	units	String	unitless
variable	N		String
attribute	N	long_name	String	N
attribute	N	units	String	unitless
variable	Algae_Type		String
attribute	Algae_Type	long_name	String	Algae_type
attribute	Algae_Type	units	String	unitless
variable	Foil_cup_weight		float
attribute	Foil_cup_weight	actual_range	float	0.0, 135.415
attribute	Foil_cup_weight	long_name	String	Foil_cup_weight
attribute	Foil_cup_weight	units	String	grams (g)
variable	Sample_and_foil_cup_weight		float
attribute	Sample_and_foil_cup_weight	actual_range	float	0.0, 140.976
attribute	Sample_and_foil_cup_weight	long_name	String	Sample_and_foil_cup_weight
attribute	Sample_and_foil_cup_weight	units	String	grams (g)
variable	Preburn_weight		float
attribute	Preburn_weight	actual_range	float	0.0, 28.715
attribute	Preburn_weight	long_name	String	Preburn_weight
attribute	Preburn_weight	units	String	grams (g)
variable	Ceramic_cup_weight		float
attribute	Ceramic_cup_weight	actual_range	float	0.0, 399.557
attribute	Ceramic_cup_weight	long_name	String	Ceramic_cup_weight
attribute	Ceramic_cup_weight	units	String	grams (g)
variable	Sample_and_ceramic_cup_weight		float
attribute	Sample_and_ceramic_cup_weight	actual_range	float	0.0, 412.863
attribute	Sample_and_ceramic_cup_weight	long_name	String	Sample_and_ceramic_cup_weight
attribute	Sample_and_ceramic_cup_weight	units	String	grams (g)
variable	Postburn_weight		float
attribute	Postburn_weight	actual_range	float	0.0, 22.58
attribute	Postburn_weight	long_name	String	Postburn_weight
attribute	Postburn_weight	units	String	grams (g)
variable	AFDW		float
attribute	AFDW	actual_range	float	0.0, 16.267
attribute	AFDW	long_name	String	Afdw
attribute	AFDW	units	String	grams (g)

Row Type

Variable Name

Attribute Name

Data Type

Value

attribute

NC_GLOBAL

cdm_data_type

String

Other

attribute

NC_GLOBAL

Conventions

String

COARDS, CF-1.6, ACDD-1.3

attribute

NC_GLOBAL

creator_email

String

info at bco-dmo.org

attribute

NC_GLOBAL

creator_name

String

BCO-DMO

attribute

NC_GLOBAL

creator_url

String

https://www.bco-dmo.org/ (external link)

attribute

NC_GLOBAL

doi

String

10.26008/1912/bco-dmo.894169.1

attribute

NC_GLOBAL

infoUrl

String

https://www.bco-dmo.org/dataset/894169 (external link)

attribute

NC_GLOBAL

institution

String

BCO-DMO

attribute

NC_GLOBAL

license

String

The data may be used and redistributed for free but is not intended\nfor legal use, since it may contain inaccuracies. Neither the data\nContributor, ERD, NOAA, nor the United States Government, nor any\nof their employees or contractors, makes any warranty, express or\nimplied, including warranties of merchantability and fitness for a\nparticular purpose, or assumes any legal liability for the accuracy,\ncompleteness, or usefulness, of this information.

attribute

NC_GLOBAL

sourceUrl

String

(local files)

attribute

NC_GLOBAL

summary

String

Increased standing macroalgal biomass in upwelling zones is generally assumed to be the result of higher nutrient flux due to upwelled waters. However, other factors can strongly impact macroalgal communities. For example, herbivory and temperature, via their effects on primary producers and the metabolic demands of consumers, can also influence macroalgal biomass and productivity, respectively. Although there are a fair number of studies looking at the interactive effects of herbivores and nutrients in both tropical and temperate regions, there is a lack of studies looking at these effects in tropical or subtropical upwelling regions. The purpose of this study was to measure the effects that herbivores, temperature, and nutrient availability have on standing macroalgal biomass. We manipulated nutrient availability and herbivory in six field experiments during contrasting productivity and thermal regimes (cool-upwelling and warm, non-upwelling season) on a subtidal nearshore rocky reef.\n\nHere, we present the macroalgal biomass raw data (Preburn, Postburn, and Ash-Free Dry Weight) collected in the nearshore shallow subtidal during the six field experiments.

attribute

NC_GLOBAL

title

String

[Cerro Mundo Algal Ash-Free Dry Weight] - Macroalgal biomass data (Preburn, Postburn, and Ash-Free Dry Weight) collected in the nearshore shallow subtidal during six field experiments conducted at Cerro Mundo Bay in the Galapagos Islands between July 2021 and May 2022 (The Role of Temperature in Regulating Herbivory and Algal Biomass in Upwelling Systems)

variable

Trial

String

attribute

Trial

long_name

String

Trial

attribute

Trial

units

String

unitless

variable

Cage

int

attribute

Cage

actual_range

int

1, 64

attribute

Cage

long_name

String

Cage

attribute

Cage

units

String

unitless

variable

Treatment

String

attribute

Treatment

long_name

String

Treatment

attribute

Treatment

units

String

unitless

variable

String

attribute

long_name

String

attribute

units

String

unitless

variable

Algae_Type

String

attribute

Algae_Type

long_name

String

Algae_type

attribute

Algae_Type

units

String

unitless

variable

Foil_cup_weight

float

attribute

Foil_cup_weight

actual_range

float

0.0, 135.415

attribute

Foil_cup_weight

long_name

String

Foil_cup_weight

attribute

Foil_cup_weight

units

String

grams (g)

variable

Sample_and_foil_cup_weight

float

attribute

Sample_and_foil_cup_weight

actual_range

float

0.0, 140.976

attribute

Sample_and_foil_cup_weight

long_name

String

Sample_and_foil_cup_weight

attribute

Sample_and_foil_cup_weight

units

String

grams (g)

variable

Preburn_weight

float

attribute

Preburn_weight

actual_range

float

0.0, 28.715

attribute

Preburn_weight

long_name

String

Preburn_weight

attribute

Preburn_weight

units

String

grams (g)

variable

Ceramic_cup_weight

float

attribute

Ceramic_cup_weight

actual_range

float

0.0, 399.557

attribute

Ceramic_cup_weight

long_name

String

Ceramic_cup_weight

attribute

Ceramic_cup_weight

units

String

grams (g)

variable

Sample_and_ceramic_cup_weight

float

attribute

Sample_and_ceramic_cup_weight

actual_range

float

0.0, 412.863

attribute

Sample_and_ceramic_cup_weight

long_name

String

Sample_and_ceramic_cup_weight

attribute

Sample_and_ceramic_cup_weight

units

String

grams (g)

variable

Postburn_weight

float

attribute

Postburn_weight

actual_range

float

0.0, 22.58

attribute

Postburn_weight

long_name

String

Postburn_weight

attribute

Postburn_weight

units

String

grams (g)

variable

AFDW

float

attribute

AFDW

actual_range

float

0.0, 16.267

attribute

AFDW

long_name

String

Afdw

attribute

AFDW

units

String

grams (g)

ERDDAP, Version 2.22
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