Partial-area irrigation has been proposed for decreasing water use in field
-irrigated citrus. Since micro-irrigation wets only part of the soil surfac
e, it may not always meet citrus tree water needs and thus lead to water de
ficits. The purpose of this experiment was to determine the impact of parti
al rooting-volume irrigation (RVI) on gas exchange, biomass, and root hydra
ulic conductivity of young citrus trees. Sunlit, controlled-environment cha
mbers were used to measure evapotranspiration rate (ET), carbon dioxide exc
hange rate (CER), water-use efficiency (WUE = CER/ET), and biomass accumula
tion of trees exposed to partial RVI treatments. One-year old 'Hamlin' oran
ge scions [Citrus sinensis (L.) Osbeck] budded on either 'Carrizo' citrange
[Poncirus trifoliata Raf x C. sinensis (L.) Osbeck],'Swingle' citrumelo (E
i trifoliata Raf x C, paradisii Macf.), or sour orange [C. aurantium (L.)]
rootstocks were established in 4-compartment, split-root containers filled
with 6.8 L of coarse sand in each compartment. Trees with 1/4, 2/4, 3/4, or
4/4 RVI were grown in chambers from 15 June to 15 Sept. 1986 and were irri
gated at 2/3 depletion of available soil water (ASW). Maximum CERs occurred
before 1100 h EST in all treatments followed by mid-day depression of CER,
whereas daytime ET remained nearly constant. Typically, CER was highest fo
r 4/4 RVI and lowest for 1/4 RVI. Leaf area and dry-weight accumulations of
leaves and stems were positively related to the fraction RVI, whereas root
hydraulic conductivity did not differ among RVI. Growth limitations by 1/4
RVI were least for scions on Swingle citrumelo rootstock. These results in
dicate that, for citrus grown on a son with low water-holding capacity, a p
rogressive reduction of the irrigated portion of roots would likely lead to
increasingly severe water stresses and, furthermore, decrease CER, WUE, an
d growth more severely than it would decrease ET.