Seedling establishment and physiological responses to temporal and spatial soil moisture changes

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• 作者：Jeremiah R. Pinto ; John D. Marshall ; R. Kasten Dumroese ; Anthony S. Davis…
• 关键词：Ponderosa pine ; Soil water potential ; Container seedlings ; Stocktype ; Volumetric water content
• 刊名：New Forests
• 出版年：2016
• 出版时间：March 2016
• 年：2016
• 卷：47
• 期：2
• 页码：223-241
• 全文大小：1,423 KB
• 参考文献：Anderson CP, Hogsett WE, Plocher M, Rodecap K, Lee EH (2001) Blue wild-rye grass competition increases the effect of ozone on ponderosa pine seedlings. Tree Physiol 21:319–327CrossRef
  Blake GR, Hartge KH (1986) Bulk density. In: Klute A (ed) Methods of soil analysis, part I. Physical and mineralogical methods: agronomy monograph no. 9 (2nd ed.). American Society of Agronomy, Madison, pp 363–375
  Burdett AN (1990) Physiological processes in plantation establishment and the development of specifications for forest planting stock. Can J For Res 20:415–427CrossRef
  Burdett AN, Herring LJ, Thompson CF (1984) Early growth of planted spruce. Can J For Res 14:644–651CrossRef
  Burr KE (1990) The target seedling concepts: bud dormancy and cold hardiness. In: Rose R, Campbell SJ, Landis TD (eds) Target seedling symposium: proceedings, combined meeting of the western forest nursery associations. Gen. Tech. Rep. RM-200, USDA Forest Service, Rocky Mountain Forest and Range Experiment Station, pp 1–8
  Burr KE, Tinus RW, Wallner SJ, King RM (1989) Relationship among cold hardiness, root growth potential and bud dormancy in three conifers. Tree Physiol 5:291–306CrossRef PubMed
  Campbell GS, Norman JM (1998) An introduction to environmental biophysics, 2nd edn. Springer, New YorkCrossRef
  Chirino E, Vilagrosa A, Hernández EI, Matos A, Vallejo VR (2008) Effects of a deep container on morpho-functional characteristics and root colonization in Quercus suber L. seedlings for reforestation in Mediterranean climate. For Ecol Manage 256:779–785CrossRef
  Chirino E, Vilagrosa A, Cortina J, Valdecantos A, Fuentes D, Trubat R, Luis VC, Puértolas J, Bautista S, Baeza MJ, Peñuelas JL, Vallejo VR (2009) Ecological restoration in degraded drylands: the need to improve the seedling quality and site conditions in the field. In: Grossberg SP (ed) Forest management. Nova Publisher, New York, pp 85–158
  Cobos DR (2007) Calibrating ECH2O soil moisture sensors. Application Note. Decagon Devices. http://​www.​decagon.​com/​appnotes/​soil_​moisture/​ . Accessed October 2008
  Craig H (1957) Isotopic standards for carbon and oxygen and correction factors for mass spectrometric analysis of carbon dioxide. Geochim Cosmochim Acta 12:133–149CrossRef
  Cuesta B, Villar-Salvador P, Puértolas J, Jacobs DF, Benayas JMR (2010) Why do large, nitrogen rich seedlings better resist stressful transplanting conditions? A physiological analysis in two functionally contrasting Mediterranean forest species. For Ecol Manage 260:71–78CrossRef
  Dawson TE, Mambelli S, Plamboeck AH, Templer PH, Tu KP (2002) Stable isotopes in plant ecology. Annu Rev Ecol Syst 33:507–559CrossRef
  Decagon Devices (2006) Generating a soil moisture characteristic using the WP4. Application Note. Decagon Devices. http://​www.​decagon.​com/​appnotes/​soil_​moisture/​ . Accessed Sept 2008
  Dingman SL (2002) Physical hydrology, 2nd edn. Prentice Hall, New Jersey
  Ehleringer JR, Osmond CB (1989) Stable isotopes. In: Pearcy RW, Ehleringer JR, Mooney HA, Rundel PW (eds) Plant physiological ecology. Chapman and Hall, New York, pp 281–300CrossRef
  Elliot KJ, White AS (1987) Competitive effects of various grasses and forbs on ponderosa pine seedlings. For Sci 33:356–366
  Escudero A, Mediavilla S (2003) Decline in photosynthetic nitrogen use efficiency with leaf age and nitrogen resorption as determinants of leaf life span. J Ecol 91:880–889CrossRef
  Gardiner DT, Miller RW (2004) Soils in our environment, 10th edn. Prentice Hall, New Jersey
  Grossnickle SC (2005) Importance of root growth in overcoming planting stress. New For 30:273–294CrossRef
  Grossnickle SC (2012) Why seedlings survive: importance of plant attributes. New For 43:711–738CrossRef
  Hubbard RM, Bond BJ, Ryan MG (1999) Evidence that hydraulic conductance limits photosynthesis in old Pinus ponderosa trees. Tree Physiol 19:165–172CrossRef PubMed
  Hultine KR, Marshall JD (2001) A comparison of three methods for determining the stomatal density of pine needles. J Exp Bot 52:369–373CrossRef PubMed
  Irvine J, Law BE, Anthoni PM, Meinzer FC (2002) Water limitations to carbon exchange in old-growth and young ponderosa pine stands. Tree Physiol 22:189–196CrossRef PubMed
  Jackson RB, Canadell J, Ehleringer JR, Mooney HA, Sala OE, Schulze ED (1996) A global analysis of root distributions for terrestrial biomes. Oecologia 108:389–411CrossRef
  Johnson JD (1984) A rapid technique for estimating total surface area of pine needles. For Sci 30:913–921
  Kavanagh KL, Zaerr JB (1997) Xylem cavitation and loss of hydraulic conductance in western hemlock following planting. Tree Physiol 17:59–63CrossRef PubMed
  Kavanagh KL, Pangle R, Schotzko AD (2007) Nocturnal transpiration causing disequilibrium between soil and stem predawn water potential in mixed conifer forests of Idaho. Tree Physiol 27:621–629CrossRef PubMed
  Kolb PF, Robberecht R (1996a) High temperature and drought stress effects on survival of Pinus ponderosa seedlings. Tree Physiol 16:665–672CrossRef PubMed
  Kolb PF, Robberecht R (1996b) Pinus ponderosa seedling establishment and the influence of competition with the bunchgrass Agropyron spicatum. Int J Plant Sci 157:509–515CrossRef
  Larson MM (1967) Effect of temperature on initial development of ponderosa pine seedlings from three sources. For Sci 13:286–294
  Lopushinsky W, Max TA (1990) Effect of soil temperature on root and shoot growth and on budburst timing in conifer seedling transplants. New For 4:107–124CrossRef
  Maherali H, DeLucia EH (2000) Xylem conductivity and vulnerability to cavitation of ponderosa pine in contrasting climates. Tree Physiol 20:859–867CrossRef PubMed
  Marshall JD, Waring RH (1984) Conifers and broadleaf species: stomatal sensitivity differs in western Oregon. Can J For Res 14:905–908CrossRef
  Marshall JD, Rehfeldt GE, Monserud RA (2001) Family differences in height growth and photosynthetic traits in three conifers. Tree Physiol 21:727–734CrossRef PubMed
  McMillin JD, Wagner MR (1995) Effects of water stress on biomass partitioning of ponderosa pine seedlings during primary root growth and shoot growth periods. For Sci 41:594–610
  Meinzer FC (1982) The effect of vapor pressure on stomatal control of gas exchange in Douglas-fir (Pseudotsuga menziesii) saplings. Oecologia 54:236–242CrossRef
  Meinzer FC, Brooks JR, Bucci S, Goldstein G, Scholz FG, Warren JM (2004) Converging patterns of uptake and hydraulic redistribution of soil water in contrasting woody vegetation types. Tree Physiol 24:919–928CrossRef PubMed
  Natural Resources Conservation Service (NRCS) (2009) Soil Survey Staff. United States Department of Agriculture. Web Soil Survey. http://​websoilsurvey.​nrcs.​usda.​gov/​ . Accessed Feb 2009
  Olivas-Garcia JM, Cregg BM, Hennessey TC (2000) Genotypic variation in carbon isotope discrimination and gas exchange of ponderosa pine seedlings under two levels of water stress. Can J For Res 30:1581–1590CrossRef
  Padilla FM, Pugnaire FI (2007) Rooting depth and soil moisture control Mediterranean woody seedling survival during drought. Funct Ecol 21:489–495CrossRef
  Panek JA, Goldstein AH (2001) Response of stomatal conductance to drought in ponderosa pine: implications for carbon and ozone uptake. Tree Physiol 21:337–344CrossRef PubMed
  Pearson GA (1930) Light and moisture in forestry. Ecology 11:145–160CrossRef
  Pinol J, Sala A (2000) Ecological implications of xylem cavitation for several Pinaceae in the Pacific Northern USA. Funct Ecol 14:538–545CrossRef
  Pinto JR, Dumroese RK, Davis AS, Landis TD (2011a) Conducting seedling stocktype trials: a new approach to an old question. J For 109:293–299
  Pinto JR, Marshall JD, Dumroese RK, Davis AS, Cobos DR (2011b) Establishment and growth of container seedlings for reforestation: a function of stock-type and edaphic conditions. For Ecol Manage 261:1876–1884CrossRef
  Pinto JR, Marshall JD, Dumroese RK, Davis AS, Cobos DR (2012) Photosynthetic response, carbon isotopic composition, survival, and growth of three stocktypes under water stress enhanced by vegetative competition. Can J For Res 42:333–344CrossRef
  Rietveld WJ (1989) Transplanting stress in bareroot conifer seedlings: its development and progression to establishment. North J Appl For 6:99–107
  Robert JA, Lindgren BS (2006) Relationships between root form and growth, stability, and mortality in planted versus naturally regenerated lodgepole pine in north-central British Columbia. Can J For Res 36:2642–2653CrossRef
  Running SW (1976) Environmental control of leaf water conductance in conifers. Can J For Res 6:104–112CrossRef
  Scagel R, Bowden R, Madill M, Kooistra C (1998) Provincial seedling stock type selection and ordering guidelines. B.C. Ministry of Forests, Victoria, pp 16–19
  South DB, Mitchell RJ (1999) Determining the “optimum” slash pine seedling size for use with four levels of vegetation management on a flatwoods site in Georgia, USA. Can J For Res 29:1030–1046CrossRef
  Starr JL, Paltineanu IC (2002) Methods for measurement of soil water content: capacitance devices. In: Dane JH, Topp GC (eds) Methods of soil analysis: part 4 physical methods. Soil Science Society of America, Inc., Madison, pp 463–474
  Svenson SE, Davies FT Jr (1992) Comparison of methods for estimating surface area of water-stressed and fully hydrated pine needle segments for gas exchange analysis. Tree Physiol 10:417–421CrossRef PubMed
  van den Driessche R (1987) Importance of current photosynthesis to new root growth in planted conifer seedlings. Can J For Res 17:776–782CrossRef
  Van Haverbeke DF (1963) Root development of ponderosa pine seedlings in the Black Hills. Ecology 44:161–165CrossRef
  VanderSchaaf CL, South DB (2003) Effect of planting depth on growth of open-rooted Pinus elliottii and Pinus taeda seedlings in the United States. S Afr For J 198:63–73
  Wang K, Kellomäki S, Laitinen K (1995) Effects of needle age, long-term temperature and CO2 treatments on the photosynthesis of Scots pine. Tree Physiol 15:211–218CrossRef PubMed
  Waring RH, Franklin JF (1979) Evergreen coniferous forests of the Pacific Northwest. Science 204:1380–1386CrossRef PubMed
  Warren CR, McGrath JF, Adams MA (2001) Water availability and carbon isotope discrimination in conifers. Oecologia 127:476–486CrossRef
  Warren JM, Meinzer FC, Brooks JR, Domec JC (2005) Vertical stratification of soil water storage and release dynamics in Pacific Northwest coniferous forests. Agric For Meteorol 130:39–58CrossRef
  Weltzin JF, McPherson GR (1997) Spatial and temporal moisture resource partitioning by trees and grasses in a temperate savanna, Arizona, USA. Oecologia 112:156–164CrossRef
  Wykoff WR (2002) Measuring and modeling surface area of ponderosa pine needles. Can J For Res 32:1–8CrossRef
  Zhang JW, Marshall JD (1995) Variation in carbon isotope discrimination and photosynthetic gas exchange among populations of Pseudotsuga menziesii and Pinus ponderosa in different environments. Funct Ecol 9:402–412CrossRef
  Zhang JW, Feng Z, Cregg BM, Schumann CM (1997) Carbon isotopic composition, gas exchange, and growth of three populations of ponderosa pine differing in drought tolerance. Tree Physiol 17:461–466CrossRef PubMed
  Zwieniecki MA, Newton M (1994) Root distribution of 12-year-old forests at rocky sites in southwestern Oregon: effects of rock physical properties. Can J For Res 24:1791–1796CrossRef
  
• 作者单位：Jeremiah R. Pinto (1)
  John D. Marshall (2)
  R. Kasten Dumroese (1)
  Anthony S. Davis (2)
  Douglas R. Cobos (3)
  
  1. US Department of Agriculture Forest Service, Rocky Mountain Research Station, 1221 S Main St, Moscow, ID, 83843, USA
  2. Department of Forest, Range, and Fire Sciences, University of Idaho, Moscow, ID, 83843, USA
  3. Decagon Devices, 2365 NE Hopkins Ct., Pullman, WA, 99163, USA
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Forestry
  
• 出版者：Springer Netherlands
• ISSN：1573-5095

文摘

In many forests of the world, the summer season (temporal element) brings drought conditions causing low soil moisture in the upper soil profile (spatial element)—a potentially large barrier to seedling establishment. We evaluated the relationship between initial seedling root depth, temporal and spatial changes in soil moisture during drought after outplanting, and subsequent seedling performance using seedlings of Pinus ponderosa Laws. var. ponderosa grown in three containers similar in dimension except for depth (i.e. three stocktypes). Soil moisture patterns were quantified and growth, gas exchange, and carbon isotope analysis were used as metrics for stocktype evaluation. Soil moisture reached minimum volumetric soil moisture contents (θ) of 0.078 m3 m−3 at a 15 cm depth and 0.15 m3 m−3 at 90 cm by late summer, which also translated to estimated soil water potential (Ψ _soil) values of −2.29 and −0.02 MPa, respectively. Seedling photosynthesis (A) and transpiration (E) rates followed soil moisture trends, also reaching seasonal lows in late summer. In early fall, gas exchange rates nearly doubled following a replenishment of upper-profile soil moisture by precipitation. Over the course of the growing season, stocktypes did not differ in gas exchange rates (P ≥ 0.15), biomass (P ≥ 0.45), root penetration depth (P = 0.60), or carbon isotope signature (P ≥ 0.60). For all seedlings, current-year needles showed greater capacity for A than previous-year needles (P ≤ 0.01), and A was only significantly correlated with soil moisture in the upper soil profile (15 cm; P ≤ 0.03). In this study, stocktype was not a significant factor, suggesting that seedling access to soil moisture was not different among them. The temporal and spatial variation observed in soil moisture availability, however, provides critical biophysical information on outplanting timing as it relates to subsequent seedling establishment and potential root growth. As well, needle formation, carbon gain, and the relationship to soil water depth further indicate the importance for managing soil water or seedling stocktype for successful seedling survival and growth. Keywords Ponderosa pine Soil water potential Container seedlings Stocktype Volumetric water content