Fitz Booker
USDA-ARS Plant Physiologist and Associate Professor of Crop Science
CROP SCIENCE
PERSONNEL
USDA-ARS Plant Science Research Unit
3908 Inwood Road
Raleigh, NC 27603
NCSU Personal Web Page
fbooker@mindspring.com
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COLLEGE OF AGRICULTURE AND LIFE SCIENCES | ||
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Fitz BookerUSDA-ARS Plant Physiologist and Associate Professor of Crop Science |
CROP SCIENCE
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USDA Facility (Non-NCSU Bldg.) 14,CB 7631 USDA-ARS Plant Science Research Unit 3908 Inwood Road Raleigh, NC 27603 |
CURRICULUM VITAE | ||
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NCSU Personal Web Page fbooker@mindspring.com |
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Dr. Booker’s graduate training was in plant physiological ecology. As a member of the Plant Science Research Unit he has investigated the effects of UV-B radiation, elevated atmospheric CO2 and pollutant ozone (O3) on soybean, cotton and loblolly pine growth and secondary metabolism. Dr. Booker is currently conducting field studies on the individual and combined effects of elevated atmospheric CO2 and O3 on gas-exchange, growth, and decomposition of soybean and peanut.
Current projects (see Fig. 1) involve a 5-year study that examines the effects of elevated CO2 and ozone on crop physiology and soil C & N dynamics in a no-till, soybean-wheat cropping system using open-top field chambers. We are also conducting experiments that
Previous studies conducted by our Unit and others (NCLAN) showed that ambient O3 pollution can suppress soybean, cotton, wheat and peanut yields by 5 to 15% (Fig.2). However, elevated atmospheric CO2 ameliorates O3 effects (Fig. 3).
Studies to determine the sources of these interactions are underway. Experiments in progress are examining elevated CO2and O3 effects on stomatal conductance, O3 uptake, photosynthesis, transpiration and oxidative injury in soybean (Fig. 4). We are also investigating the effects of elevated CO2 and O3 on crop residue chemistry and decomposition (Fig. 5).
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| Fig. 4 | Fig. 5 |
Increased biomass production with elevated while CO2 increased residue inputs (Fig. 6), while O3-treated soybean leaf residues decomposed more slowly than residues from plants grown in clean air (Fig. 7).
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| Fig. 6. Aboveground soybean residue biomass remaining after harvest. Growth treatments: clean-air, ambient CO2 control (CF-370); elevated CO2 (CF-714); O3 (OZ-370); CO2 + O3 (OZ-714). | Fig. 7. Decomposition of soybean leaf residues after incubation in soil for 20 wks. Growth treatments: clean-air, ambient CO2 control (CF-370); elevated CO2 (CF-714); O3 (OZ-370); CO2 + O3 (OZ-714). |
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O3-induced decreases in carbohydrates and increases in phenolic polymers were associated with slower decomposition rates. Both elevated CO2 and O3 are expected to influence soil carbon sequestration and nitrogen mineralization rates.
A new project in our laboratory involves the use of snap bean and Arabidopsis mutants with differential sensitivity to O3 injury. Experiments conducted in O3 exposure chambers in the NC State Phytotron (Fig. 8) examine genotype sensitivity to O3 in conjunction with gas-exchange, antioxidant metabolism and ethylene measurements to identify possible mechanisms to improve plant tolerance to ambient O3 pollution. |
 Fig. 8 |
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| POB 7620 Williams Hall NCSU, Raleigh, North Carolina, 27695 |
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(919)515-2647 MAIN OFFICE (919)515-7959 FAX contact_cropsci@ncsu.edu |