Tree crop interactions, productivity and physiological efficiency of understory crops in Alnus nepalensis and Gmelina arborea based agroforestry systems in Eastern Himalayas

Krishnappa Rangappa Nongmaithem Raju Singh ^* Rajappa J.J K.P. Mohapatra ^* Puran Chandra Burhan U. Choudhury Moirangthem Prabha Supriya Debnath L Joymati Chanu Ningthoujam Peetambari Devi Samarendra Hazarika Yengkhom Bijen Kumar Vinay Kumar Mishra

• The ICAR Research Complex for North Eastern Hill Region (ICAR RC NEH), Umiam, India

Climate change, land degradation, and shrinking land resources are major limitations for increasing crop productivity in the East Himalayan Region (EHR). Agroforestry having a plethora of complementarities is a preferable land-use option for improving agricultural productivity while conserving the natural resources. The effects of agroforestry systems with Gamhari (Gmelina arborea) (GAFS) and Alder (Alnus nepalensis) (AAFS) as tree components, on the soil nutrients, physiological characteristics, and productivity of turmeric (Curcuma longa L), elephant foot yam (Amorphophallus paeoniifolius), and colocasia (Colocasia esculenta), were assessed in a split plot design with trees in the main plots and understorey crops in sub-plots. The hypothesis of the study was the tree components had enriched the soils and favorably influenced physiological attributes of the understorey crops, enhancing the yields and maximising systems productivities. AAFS canopy had a higher (p< 0.05) leaf area index (LAI = 2.19) than the GAFS (LAI = 1.01). AAFS recorded 32% lower (p<0.05) photosynthetically active radiation (PAR) than sole crops under treeless conditions (TLS). ANOVA revealed significant interactions (p<0.01) between tree systems and the understorey crops with their influence on chlorophyll content (SCMR), leaf thickness (LT), stomatal size (SS), stomatal frequency (SF), stomatal conductance (gs), photosynthetic rates (A), transpiration rates (E), intercellular CO2 concentration (Ci), instantaneous water use efficiency (iWUE) and crop yields (YLD). SCMR, SS, SF, gs, iWUE, and YLD in GAFS and AAFS increased significantly (p<0.05) over TLS, whereas, SF and E significantly decreased (p<0.05). Regression of physiological traits on yields showed SS (b=0.0884, p=0.002), gs (b=0.00934, p=0.018), and iWUE (b=0.2981, p=0.008) influenced positively, whereas SF (b=-0.0381, p=0.019) and E (b=-2.304, p=0.02) negatively impacted the YLD of understory crops. Alder-turmeric system harnessed the attenuated light with better soil fertility most favorably, supporting high SCMR, low E, high A, high gs to produce higher YLD. Turmeric achieved the highest system productivity (USD 4281 ha-1 yr-1) under the AAFS. Soil pH, organic carbon and nitrogen were significantly enriched (p<0.05) after 14 years of converting the lands to agroforestry systems. Alder-Turmeric was the most effective tree-crop pairing delivering enhanced productivity, soil health and economic returns for sustainable agriculture in the EHR.