CO2 Science

Percent Dry Weight (Biomass) Increases for
300, 600 and 900 ppm Increases in the Air's CO2 Concentration:

For a more detailed description of this table, click here.

Arachis hypogaea L. [Peanut]

Statistics

	300 ppm	600 ppm	900 ppm
Number of Results	46		1
Arithmetic Mean	53%		35%
Standard Error	13.6%		0%

Individual Experiment Results

Journal References	Experimental Conditions	300 ppm	600 ppm	900 ppm
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 33/21°C; cv. Georgia Green	20%
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 35.5/23.5°C; cv. Georgia Green	29%
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 38/26°C; cv. Georgia Green	34%
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 33/21°C; cv. Pronto	63%
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 35.5/23.5°C; cv. Pronto	52%
Bannayan et al. (2009)	Total biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at day/night temperatures of: 38/26°C; cv. Pronto	70%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 33/21°C	-53%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 35.5/23.5°C	-11%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 38/26°C	55%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 33/21°C; cv. Pronto	-24%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 35.5/23.5°C; cv. Pronto	-14%
Bannayan et al. (2009)	Seed biomass of well watered and fertilized plants grown from seed to maturity in 20-L pots filled with sand within controlled environment chambers in the University of Georgia Envirotron at a day/night temperature of 38/26°C; cv. Pronto	-73%
Booker et al. (2007)	Plants grown in the field for two years using standard agricultural practices within open-top chambers maintained at ambient (46 ppb) O3 concentrations	32%
Bookeret al. (2007)	Plants grown in the field for two years using standard agricultural practices within open-top chambers maintained at elevated (75 ppb) O3 concentrations	82%
Clifford et al. (1993)	controlled environment glasshouse, yield, 1991 wet	22%
Clifford et al. (1993)	controlled environment glasshouse, yield, 1992 wet	22%
Clifford et al. (1993)	controlled environment glasshouse, yield, 1992 dry	401%
Clifford et al. (1993)	controlled environment glasshouse, yield, 1992 dry	471%
Clifford et al. (2000)	controlled environment glasshouse, above-ground biomass, 28 °C, irrigated	19%
Clifford et al. (2000)	controlled environment glasshouse, above-ground biomass, 28 °C, droughted	-5%
Clifford et al. (2000)	controlled environment glasshouse, total pod biomass, 28 °C, irrigated	5%
Clifford et al. (2000)	controlled environment glasshouse, total pod biomass, 28 °C, droughted	102%
Clifford et al. (2000)	controlled environment glasshouse, above-ground biomass, 32 °C, irrigated	41%
Clifford et al. (2000)	controlled environment glasshouse, above-ground biomass, 32 °C, droughted	29%
Clifford et al. (2000)	controlled environment glasshouse, total pod biomass, 32 °C, irrigated	94%
Clifford et al. (2000)	controlled environment glasshouse, total pod biomass, 32 °C, droughted	115%
Mortley et al. (1997)	growth chamber, Florunner cultivar	73%
Mortley et al. (1997)	growth chamber, Georgia Red cultivar	71%
Mortley et al. (1997)	growth chamber, New Mexico cultivar	100%
Prasad et al. (2003)	Vegetative biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 32/22?C	35%
Prasad et al. (2003)	Vegetative biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 40/30?C	38%
Prasad et al. (2003)	Vegetative biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 44/34?C	62%
Prasad et al. (2003)	Seed biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 32/22?C	23%
Prasad et al. (2003)	Seed biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 40/30?C	29%
Prasad et al. (2003)	Seed biomass of plants grown from seed to maturity in sunlit controlled-environment chambers at daytime-maximum/nighttime-minimum air temperatures of 44/34?C	146%
Stanciel et al. (2000)	hydroponic chamber	14%		35%
Tu et al. (2009)	Total aboveground biomass of plants grown from seed to maturity out-of-doors in open-top chambers under well watered and fertilized conditions in air of unaltered ozone (O3) concentration	35%
Tu et al. (2009)	Total aboveground biomass of plants grown from seed to maturity out-of-doors in open-top chambers under well watered and fertilized conditions in air containing 1.6 times the normal O3 concentration	89%
Ziska et al. (2016)	Above-ground biomass at harvest in 2012 of plants grown outdoors in slope-top acrylic chambers; cv Georgia Green	-12%
Ziska et al. (2016)	Above-ground biomass at harvest in 2012 of plants grown outdoors in slope-top acrylic chambers; cv Virginia Jumbo	15%
Ziska et al. (2016)	Above-ground biomass at harvest in 2013 of plants grown outdoors in slope-top acrylic chambers; cv Georgia Green	19%
Ziska et al. (2016)	Above-ground biomass at harvest in 2013 of plants grown outdoors in slope-top acrylic chambers; cv Virginia Jumbo	53%
Ziska et al. (2016)	Seed yield at harvest in 2012 of plants grown outdoors in slope-top acrylic chambers; cv Georgia Green	-23%
Ziska et al. (2016)	Seed yield at harvest in 2012 of plants grown outdoors in slope-top acrylic chambers; cv Virginia Jumbo	23%
Ziska et al. (2016)	Seed yield at harvest in 2013 of plants grown outdoors in slope-top acrylic chambers; cv Georgia Green	27%
Ziska et al. (2016)	Seed yield at harvest in 2013 of plants grown outdoors in slope-top acrylic chambers; cv Virginia Jumbo	41%

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