Temporary immersion system (TIS) has both advantages of maximum gas exchanges in solid culture media and increased nutrient up take in liquid culture. To increase the rate of multiplication and plant growth, effects of sucrose concentration, cultural system and photosynthetic photon flux (PPF) during ex vitro acclimatization on photosynthetic behaviors and growth were studied in micropropagated Calathea orbifolia. The objectives of this research were to determine the proper sucrose concentration, cultural system and ex vitro PPF during acclimatization that could promote the subsequent growth of plantlets after transfer. An addition of 80 mL culture medium per explant in TIS resulted in maximum shoot formation. Full MS medium supplemented with 4% sucrose, 2.2 μM NAA and 26.7 μM BA produced maximum shoot number. Shoot number increased with increasing TDZ concentration, while high TDZ concentrations of 2.73 and 3.64 µM resulted in shorter and rosetted shoots. Micropropagated Calathea orbifolia plantlets, cultured with 2%, 4% or 6% sucrose concentrations, were transplanted to a soilless mix and placed in a growth chamber to measure their photosynthetic capacity and growth. Plants cultured with 4% sucrose in vitro had greater growth. All the Fv/Fm values in the in vitro-formed leaves decreased in the early period after transfer. The Fv/Fm value reduced to 0.55 and recovered slower afterwards in plants at 2%. For all the plantlets tested, the stomatal conductance and transpiration rate in the in vitro-formed leaf were high at transfer and decreased dramatically on day one after transfer. Photosynthetic rate of in vitro-formed leaf was measured as 1.3-1.8 µmol CO2 m-2•s-1 at transfer, decreased after transferring for seven day, and then increased gradually. After having been acclimatized for 35 days in the growth chamber, the micropropagated Calathea orbifolia plantlets, cultured in solid medium or in a TIS, were then transferred to a shaded greenhouse for 65 days and their leaf anatomy, growth and photosynthetic capacity was determined. In vitro-formed leaves in TIS were thicker, had lower stomatal frequency and more surface wax, similar to the ex vitro-formed leaf. In TIS treatment, leaf Fv/Fm value recovered earlier and SPAD-502 reading increased during acclimatization, suggesting that plantlets could adapt to the changing environments. Micropropagated Calathea orbifolia plantlets were transplanted to a soilless mix and placed in a growth chamber under fluorescent lamp providing PPF of 40、120 0r 200 µmol•m-2•s-1. After having been acclimatized for 35 days in the growth chamber, the plantlets were then transferred to a shaded greenhouse for 65 days and their growth was measured. Plantlets under 40 µmol•m-2•s-1 had greater growth. All the Fv/Fm values in the in vitro-formed leaf decreased in the early period after transfer, and then increased thereafter. High PPF at 120 or 200 µmol•m-2•s-1 reduced the Fv/Fm value to 0.27 or 0.19, clearly exhibiting photo inhibition and a slow increase in the Fv/Fm value afterwards. For all the plantlets tested, the stomatal conductance and transpiration rate values in the in vitro-formed leaf were high at transfer and decreased dramatically on day one after transfer. Photosynthetic rate of in vitro-formed leaf was measured as 0.85 µmol CO2 m-2•s-1 at transfer, decreased after transferring for seven day, and then increased gradually.