1. IntroductionBiochar application

1. Introduction
Biochar application (CA) has received a growing interest as a
sustainable technology to improve highly weathered or degraded
tropical soils (Lehmann and Rondon, 2006). CA can enhance plant
growth by improving soil chemical characteristics (i.e., nutrient
retention, nutrient availability), soil physical characteristics (i.e.,
bulk density, water holding capacity, permeability), and soil
biological properties, all contributing to an increased crop
productivity (Glaser et al., 2002; Lehmann and Rondon, 2006;
Yamato et al., 2006). In addition, biochar is highly recalcitrant to
microbial decomposition and thus guarantees a long term benefit
for soil fertility (Steiner et al., 2007). These actual effects of CA
application, however, depend on various factors such as the soil
fertility and the water balance at a given site, and possibly even the
cultivated genotype. Lehmann et al. (2002) argued that CA might
even limit soil N availability in N deficient soils due to the high C/N
ratio specific to biochar and, therefore, might reduce crop
productivity at least temporarily. Hence, it is necessary to assess
the effect of CA on crop productivity under field conditions and in
relation to agronomic practices and cultivars used at a given site.
However, such research is rare and little is known about possible
interaction effects. Therefore, we evaluated the effect of CA
techniques on the grain yield of upland rice, which is an important
staple food for Lao people. Our objectives were to characterize the
effect of CA on selected soil characteristics and crop parameters,
thereby evaluating the possible benefits of CA techniques in this
agro-ecological environment.