Patrick J. Temple
University of California, Riverside
23 Papers
492 Citations
Patrick J. Temple is an academic researcher from University of California, Riverside. The author has contributed to research in topics: Stomatal conductance & Yield (engineering). The author has an hindex of 15, co-authored 23 publications.
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Papers
Effects of long‐term ozone exposure and drought on the photosynthetic capacity of ponderosa pine (Pinus ponderosa Laws.)
TL;DR: Current-year needles of NF150 trees had higher photosynthetic capacity than NF and CF trees during late summer, an effect due to greatly enhanced photosynthesis in well-watered plants that had lost older needles as a result of ozone damage.
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Foliar injury responses of ponderosa pine seedlings to ozone, wet and dry acidic deposition, and drought
TL;DR: A 3-year field study of the potential interactions of ozone (O3), wet and dry acidic deposition, and soil water availability on foliar injury responses of 18 ponderosa pine (Pinus ponderosa Laws.) families was conducted in the Sierra Nevadas of California.
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Growth responses of ponderosa pine to long-term exposure to ozone, wet and dry acidic deposition, and drought
TL;DR: A 3-year field study of the cumulative effects of ozone (O3), wet and dry acidic deposition, and soil water availability was conducted on ponderosa pine (Pinusponderosa Laws.) in the Sierra Nevada of California from 1988 to 1990, finding low soilWater availability was the only stress factor to significantly affect growth following the first exposure season.
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Injury and growth of Jeffrey pine and giant sequoia in response to ozone and acidic mist.
TL;DR: A 2-year study of the interactive effect of sequential exposures of Jeffrey pine (P. Jeffreyi ) and giant sequoia (S. giganteum ) to simulated acidic mist and ozone (O 3 ) was conducted in 1985 and 1986 as mentioned in this paper.
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Nitrogen allocation in ponderosa pine seedlings exposed to interacting ozone and drought stresses
TL;DR: O3-injured ponderosa pine seedlings increased resorption of N from older needles and increased partitioning of N to current-year foliage, thus partly compensating for the O3-induced loss of older leaves.
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