blue or red light. Blue light suppr

blue or red light. Blue light suppresses hypocotyl elongation and
induces biomass production, and red light induces hypocotyl elongation and expansion in leaf area (McNellis and Deng, 1995; Johkan
et al., 2010). Green light also affects plant morphology and physiology, including leaf growth, stomatal conductance and early stem
elongation (Folta, 2004; Kim et al., 2004a,b).
Plant growth under the combination of blue and red light has
been studied in lettuce, spinach, komatsuna (Japanese mustard
spinach) and radish (Yorio et al., 2001; Hanyu and Shoji, 2002;
Ohasi-Kaneko et al., 2007). The combination of red and blue light
was an effective lighting source to produce plant biomass, and
the addition of green light with blue and red light was also effective (Kim et al., 2004a,b). Green light can penetrate into the plant
canopy better than blue or red light (Klein, 1992). Leaves in the
lower canopy would be able to use the transmitted green light in
photosynthesis (Nishio, 2000), so plant growth is promoted by the
addition of green light with blue and red light (Kim et al., 2004a,b).
However, the growth of plants irradiated with green light decreases
as the proportion of green light increases (Kim et al., 2004a,b).
Plant physiological reactions to green light and the effects of
green light on plant growth have been investigated, but there is no
report of plants being cultivated under green light only. Hence, the
question arises whether the plants could be grown under green
light only. Major previous reports showed that green light was
not active for plant growth (Van et al., 1977; Kim et al., 2004a,b),
and some previous reports showed that green light was active for
plant growth when the proportion of green light to photosynthetic