Handbook of Plant and Crop Physiology

(Steven Felgate) #1

  1. RM Wheeler. Gas balance in a plant-based CELSS. In: H Suge, ed. Plants in Space Biology. Tohoku: Institute
    of Genetic Ecology, Tohoku University Press, 1996, pp 207–216.

  2. RM Wheeler, CL Mackowiak, GW Stutte, JC Sager, NC Yorio. LM Ruffe, RE Fortson, TW Dreschel, WM
    Knott, KA Corey. NASA’s Biomass Production Chamber: a testbed for bioregenerative life support studies.
    Adv Space Res 18:215–224, 1996.

  3. DJ Barta, K Henderson. Performance of wheat for air revitalization and food production during the lunar-Mars
    life support test project phase III test. SAE Technical Paper Series, 981704, 1998.

  4. AE Drysdale. The effect of resource cost on life support selection. SAE Technical Paper 951492, 1995.

  5. J Hunter. Engineering concepts for food processing in bioregenerative life support systems. Life Support Bio-
    sphere Sci 6:53–60, 1999.

  6. KL Mitchell, RM Bagdigian, RL Carrasquillo, DL Carter, GD Franks, DW Holder, CF Hutchens, KY Ogle, JL
    Perry, CD Ray. Technical assessment of Mir-1 life support hardware for the International Space Station. NASA
    Technical Memorandum 108441, Marshall Space Flight Center, 1994.

  7. RD MacElroy, M Kliss, C Straight. Life support systems for Mars transit. Adv Space Res 12:159–166, 1992.

  8. VI Lohr. Quantifying the intangible. Interior Landscape. August:32–39, 1992.

  9. TW Tibbitts, DK Alford. Controlled ecological life support system. Use of higher plants. Ames Research Cen-
    ter, Moffett Field, CA, NASA Conference Publication 2231, 1982.

  10. JE Hoff, JM Howe, CA Mitchell. Nutritional and cultural aspects of plant species selection for a regenerative
    life support system. Report to NASA Ames Research Center, NSG2401 and NSG 2404, 1982.

  11. FB Salisbury, MAZ Clark. Choosing plants to be grown in a controlled environment life support system
    (CELSS) based upon attractive vegetarian diets. Life Support Biosphere Sci 2:169–179, 1996.

  12. CA Mitchell, TAO Dougher, SS Nielsen, MA Belury, RM Wheeler. Costs of providing edible biomass for a
    balanced vegetarian diet in a controlled ecological life support system. In: H Suge, ed. Plants in Space Biol-
    ogy. Tohoku: Institute of Genetic Ecology, Tohoku University, 1996, pp 245–254.

  13. FB Salisbury. Some challenges in designing a lunar, Martian, or microgravity CELSS. Acta Astronaut
    27:211–217, 1992.

  14. B Bugbee, G Koerner. Yield comparisons and unique characteristics of the dwarf wheat cultivar ‘USU
    Apogee’. Adv Space Res 20:1891–1894, 1997.

  15. C McKay. A short guide to Mars. In: PJ Boston, ed. The Case for Mars. Vol 57, Science and Technology Se-
    ries, San Diego: American Astronautical Society Publishers, 1984, pp 303–310.

  16. W Mendell, J Plescia, AC Tribble. Surface environments. Physiology of spaceflight. In: WJ Larson, LK
    Pranke, eds. Human Spaceflight: Mission Analysis and Design. New York: McGraw-Hill, 1999, pp 77–101.

  17. AD Krikorian, HG Levine. Development and growth in space. In: RGS Bidwell, ed. Plant Physiology: A Trea-
    tise. Orlando, FL: Academic Press, 1991, pp 491–555.

  18. FB Salisbury. Growing super-dwarf wheat in space station Mir. Life Support Biosphere Sci 4:155–166, 1997.

  19. J Croxdale, M Cook, TW Tibbitts, CS Brown, RM Wheeler. Structure of potato tubers formed during space-
    flight. J Exp Bot 48:2037–2043, 1997.

  20. CS Brown, TW Tibbitts, JG Croxdale, RM Wheeler. Potato tuber formation in the spaceflight environment.
    Life Support Biosphere Sci 4:71–76, 1997.

  21. BD Wright, WC Bausch, WM Knott. A hydroponic system for microgravity plant experiments. Tran ASAE
    31:440 – 446, 1988.

  22. TW Dreschel, JC Sager. Control of water and nutrient using a porous tube: A method for growth plants in
    space. HortScience 24:944–947, 1989.

  23. BG Bubgee, FB Salisbury. Exploring the limits of crop productivity. Photosynthetic efficiency of wheat in high
    irradiance environments. Plant Physiol 88:869–878, 1988.

  24. E Heuvelink. Growth, development and yield of a tomato crop: periodic destructive measurements in a green-
    house. Sci Hortic 61:77–99, 1995.

  25. RM Wheeler, TW Tibbitts, AH Fitzpatrick. Carbon dioxide effects on potato growth under different photope-
    riods and irradiance. Crop Sci 31:1209–1213, 1991.

  26. TAO Dougher, BG Bugbee. Blue light and temperature effects on internode elongation, growth and yield. Adv
    Space Res 20:1895–1899, 1997.

  27. GF Collier, TW Tibbitts. Tipburn of lettuce. Hortic Rev 4:49–65, 1982.

  28. AV Barker, KA Corey, LE Craker. Nutritional stresses in tomato genotypes grown under high-pressure sodium
    vapor lamps. HortScience 24:255–258, 1989.

  29. K Mori, H Ohya, K Matsumoto, H Furune. Sunlight supply and gas exchange systems in microalgal bioreac-
    tor. In: RD MacElroy, DT Smernoff, eds. Controlled Ecological Life Support Systems, Regenerative Life Sup-
    port System in Space. NASA Conf Publ 2480, Ames Research Center, Moffett Field, CA, 1987, pp 45–50.

  30. JL Cuello, P Sadler, D Jack, E Ono, KA Jordan. Evaluation of light transmission and distribution materials for
    lunar and Martian bioregenerative life support. Life Support Biosphere Sci 5:389 – 402, 1998.

  31. RC Morrow. RJ Bula, TW Tibbitts. Orbital light:dark cycle effects on potato productivity. American Society
    for Gravitational and Space Biology, 3rd Annual Meeting, Logan, UT, 1997, p 30.

  32. GA Landis. Dust obscuration of Mars solar arrays. Acta Astronaut 38:885–891, 1996.

  33. JC Sager, JL Edwards, WH Klein. Light energy utilization efficiency for photosynthesis. Trans ASAE
    25:1737–1746, 1982.


938 WHEELER ET AL.

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