Given wide ecological amplitudes, h

Given wide ecological amplitudes, high growth rates and multipurpose use, bamboo species have always been important resources in those parts of the world they abundantly occur in (e.g. China, India and Brazil) [1]. In recent decades, bamboo has turned into a globally important biomass resource [2], partially owing to the rate of economic development in these regions. Besides being a traditional source of energy and other uses, electric valorization of bamboo biomass through gasification has been pioneered recently [3]. Additionally, the acceptance of bamboo in volunteer carbon finance mechanisms amplified its attractiveness as plantation species. These developments have recently led to the expansion of bamboo plantations also in Thailand, even though specific experience on biomass yield, as well as energetic and alternative utilization options are still limited.
Allometric functions have been developed for a number of bamboo species in order to estimate above-ground biomass stocks using easy-to-assess proxy variables, such as culm DBH [4, 5]. These allometric functions usually describe culm biomass with very high coefficients of determination. Above-ground biomass stocks of bamboo plantations show a large variation world-wide, with highest stockings around 300 t*ha-1 [6] and the lowest around 25 t*ha-1 [7], respectively. Plantation choices in terms of species, propagation stock, spacing, fertilization, irrigation and harvesting techniques lead to large differences in biomass yield [1]. Intensive plantation management may result in nutrient loss, which can be minimized by restricting biomass removal to culms with nutrients concentration lower than other biomass compartments [8]. K concentrations in bamboo culms, however, are not markedly lower compared to other biomass compartments, and therefore intensively managed bamboo plantations may lead to considerable nutrient loss of especially K [8].
A detailed characterization of biomass feedstock is essential for successful energetic valorization [9], and consists of determination of moisture content, proximate (thermo-chemical reaction) and ultimate (elemental content) analyses, as well as heat of combustion and ash analyses [10]. Primarily the high moisture content, and to a minor extent the K, Si and Cl contents of the ash represent the limiting factors in the utility of bamboo biomass as energy feedstock, while other characteristics are comparable to those of wood [11]. The moisture content of bamboo culms declines as culms mature and a gradient of moisture content exists between lower and upper culm sections [12], in addition to differences in moisture contents between nodes and internodes. This variation in moisture content along culms, as well as with culm age opens up possibilities to optimize the use of different biomass compartments and age cohorts for different purposes, given adequate knowledge on their properties and on alternative utilization options, such as fiber extraction.