Search Results (4)

Ma bamboo (Dendrocalamus latiflorus Munro) is a fast-growing woody grass that offers significant economic benefits, including materials for construction, furniture, biofuel, food, and handicrafts. It also provides ecological benefits like soil conservation, wildlife habitats, and carbon sequestration. However, its species distribution patterns are influenced by various factors, including climate (mainly temperature and precipitation), soil attributes, and landscape characteristics such as topography, land use, and vegetation. Understanding these impacts is essential for the sustainable management of D. latiflorus resources and fostering related economic activities. To address these challenges, we developed a comprehensive habitat suitability (CHS) model that integrates climate, soil, and landscape variables to simulate the distribution dynamics of D. latiflorus under different shared socio-economic pathway (SSP) scenarios. An ensemble model (EM) strategy was applied to each variable set to ensure robust predictions. The results show that the current potential distribution of D. latiflorus spans 28.95 × 10⁴ km², primarily located in South China and the Sichuan Basin. Its distribution is most influenced by the annual mean temperature (Bio1), the cation exchange capacity of soil clay particles in the 20–40 cm soil layer (CECc 20–40 cm), vegetation, and elevation. Under future climate scenarios, these habitats are projected to initially expand slightly and then contract, with a northward shift in latitude and migration to higher elevations. Additionally, the Sichuan Basin (Sichuan–Chongqing border) is identified as a climatically stable area suitable for germplasm development and conservation. To conclude, our findings shed light on how climate change impacts the geographic distribution of D. latiflorus, providing key theoretical foundations for its sustainable cultivation and conservation strategies. Full article

Sustainable materials and their potential application in building industries are gaining attention; however, there is still largely unexplored floating biomass, notably “Phumdi”, as a sustainable floating building material. Phumdi, a distinctive floating biomass, is observed in specific wetland habitats in the Loktak Lake located in Manipur, India. This heterogeneous mass of vegetation, organic matter, and soil has been utilised by several communities for various purposes, such as medicine, food, forage, and material for building houses, handicrafts, and aquaculture activities. Such floating bodies serve as a sanctuary for a wide range of flora and fauna. The study aims to conduct a comprehensive comparative analysis of phumdi as a sustainable floating material in comparison with other widely recognized construction materials such as recycled plastics, bamboo, corrugated metal sheets, and wood by evaluating the “green feature” chart. The research and experiments carried out on phumdi have underscored the highest sustainability level for its use, i.e., 15 green features, followed by wood and bamboo with 14 features, and the other two materials with low sustainability performance: plastic barrels with seven features and corrugated zinc metal sheets with eight features. Further investigation is necessary for the advancement of this material as a viable alternative for biomass-based building materials. Full article

During the growth of biomass, there are two carbon storage paths for plant-derived fibers. One path is to assimilate carbon dioxide (CO₂) from the atmosphere through photosynthesis and temporarily store it in textile plants. Besides, the carbon can be captured and stored in soil. The carbon storage capacity of textile products made from plant-derived fibers such as cotton, flax, hemp, kenaf and bamboo fiber, etc., is a non-negligible part of greenhouse gas (GHG) accounting and reporting. However, there is a lack of systematic methods to evaluate carbon storage and the delayed emission effect of plant-derived fibers. In this study, the carbon storage and emission times of 100% hemp T-shirt, 100% hemp slipcover, and 100% hemp fiber handicraft were evaluated by using the soil organic carbon method, dry weight biomass method, and modeling method. The results revealed that the CO₂ storage of 1 kg hemp fiber is 1.833 kg. Meanwhile, the delayed emission effects of carbon temporarily stored in the 3 kinds of hemp fiber products are 3.83%, 19.68%, and 41.12% at different lifespans (i.e., 5, 25, or 50 years), in which case the landfill option for hemp fiber products may be preferable from carbon storage effect perspective. The results suggest that plant-derived fibers have a positive impact on climate change due to CO₂ storage, and that the carbon storage effect improves with the continued lifespan of the product. By quantifying carbon storage and the delayed emission effect of plant-derived fibers, it is beneficial to understand the potential for reducing carbon emissions, which in turn helps to promote and develop more environmentally friendly and low-carbon production processes and products. Full article

Many bamboo species are well suited for agroforestry as they are more versatile and rapidly renewable than trees. Bamboo is an important income source for rural villagers around the world, especially in tropical developing countries, such as Lao PDR (Lao People’s Democratic Republic). This study applied a value chain approach to compare potential incomes from different bamboo utilization models: (1) existing model of selling semi-processed raw materials (bamboo splits), and (2) new model of producing handcraft products locally. Using a rural village in eastern Lao PDR (Nongboua village in Vientiane Capital province) as a case study, we provided empirical assessments of two bamboo value chains. Based on interviews with the villagers and stakeholders and government statistical data from 2017 to 2019, existing and new bamboo production chains were evaluated. In the existing value chain, the final products, bamboo chopsticks, are worth $6.74/kg. The value chain starts with bamboo harvesting, collection, and management, which are done by villagers in Lao PDR and taxed by the Lao PDR government. Bamboo splits are then transported to Vietnam to make the final products to sell. Local villagers received only 4.9% of the total value. The new bamboo handicraft model could produce 9 bamboo cups and 60 medals from one bamboo stem worth $52.6–61.7 and $343.8. In this value chain, bamboo harvesting, management, and processing to final products are done by villagers. The handcrafts were collected by traders to be sold at souvenir shops. Local villagers could capture 29.4%–42.3% of the total values. Producing bamboo cup and medal could generate 1.12–2.17 and 234.8–244.6 times higher income for villagers per labor hour and per bamboo stem, respectively, and allow them to use more bamboo resource than producing bamboo splits to export to Vietnam. If applied to other rural areas in Lao PDR, the new bamboo product model for handicrafts can be a better income source for local villagers in Lao PDR with sustainable use of bamboo resources than the existing model. However, it requires extensive bamboo handicrafts training over a year. Although alternative uses of bamboo would be different depending on social, economic, and market contexts, the value chain analysis demonstrated in this study can be applied elsewhere to increase local retention of economic values generated from agroforestry. Full article