FOOD CONSUMPTION AND PREFERENCES OF THE BONGANDO PEOPLE IN THE DEMOCRATIC REPUBLIC OF THE CONGO

People living in the Congo basin forest have developed a variety of ways to use natural resources. Thus, the increase in conservation projects must be accompanied by efforts to clarify the livelihood-related conditions of local people. This paper provided a detailed investigation of the utilization of natural resources by the Bongando people living in the great ape habitat of the Democratic Republic of the Congo (DRC). Specifically, the paper examined food acquisition and consumption based on direct observations and measurements, and also discussed the adequacy of food assessment approaches. Quantitative data on food acquisition and consumption at the study site showed that the amount of carbohydrates consumed was adequate; however, less animal protein was consumed by those living at the study site than by people living in great ape habitats in Africa. This suggests that availability of animal protein fluctuates, and that the Bongando people follow a dual village/forest lifestyle. Cassava leaves and other vegetables are also important protein sources. Data on the food preferences of the Bongando indicate that they strongly prefer cassava as their staple, and that they engage in sophisticated ways of cultivating leaves for consumption as food. The data also reflect the Bongando people’s strong preference for wild animals, and the fact that some people avoid eating livestock. Food preferences are important factors in the success of conservation projects, as it is crucial to find ways for local people to maintain adequate caloric and protein intake that are acceptable to the people themselves and to the projects. Therefore, research based on a food assessment approach should occur in parallel with research based on direct observations. Quantitative food assessment is useful because it provides data for an entire year for a large-scale population. However, it is also necessary to conduct preliminary research to obtain basic information about a population and its use of natural resources. Research designs must be developed based on the analysis, screening, and correction of data by researchers with a deep knowledge about the local livelihoods to prevent human error

Enhanced Performance of Sn4P3 Electrode Cycled in Ionic Liquid Electrolyte at Intermediate Temperature as Na‐Ion Battery Anode

Charge-discharge performances of Sn4P3 anodes for Na‐ion battery were evaluated in an ionic liquid electrolyte using N‐methyl‐N‐propylpyrrolidinium bis(fluorosulfonyl)amide at intermediate temperatures of 60 and 90 oC. At these temperatures, the anode showed extra capacities based on the full sodiation of Sn in a potential range below 0.2 V vs. Na+/Na because its slow kinetics was improved by elevating operation temperature. Under the current density of 0.1 A g-1 (0.08 C), the Sn4P3 anode at 60 oC exhibited a large capacity of 750 mA h g-1 at the 120th cycle and high Coulombic efficiencies above 99% after the 5th cycle. On the other hand, the efficiency degraded at 90 oC by the electrolyte decomposition. At 60 oC, the anode attained an excellent rate performance with capacity of 250 mA h g-1 even at 3 A g-1 (2.65 C). These results demonstrated the promising operation at intermediate temperature at around 60 oC for Sn4P3 anode in ionic liquid electrolyte

Bridging Pico-to-Nanonewtons with a Ratiometric Force Probe for Monitoring Nanoscale Polymer Physics Before Damage

Understanding the transmission of nanoscale forces in the pico-to-nanonewton range is important in polymer physics. While physical approaches have limitations in analyzing the local force distribution in condensed environments, chemical analysis using force probes is promising. However, there are stringent requirements for probing the local forces generated before structural damage. The magnitude of those forces corresponds to the range below covalent bond scission (from 200 pN to several nN) and above thermal fluctuation (several pN). Here, we report a conformationally flexible dual-fluorescence force probe with a theoretically estimated threshold of approximately 100 pN. This probe enables ratiometric analysis of the distribution of local forces in a stretched polymer chain network. Without changing the intrinsic properties of the polymer, the force distribution was reversibly monitored in real time. Chemical control of the probe location demonstrated that the local stress concentration is twice as biased at crosslinkers than at main chains, particularly in a strain-hardening region. Due to the high sensitivity, the percentage of stressed force probes was estimated to be more than 1000 times higher than the activation rate of a conventional mechanophore.Comment: 21 pages and 5 figures in the main text, and 73 pages and 68 figures in the supplementary material

Bridging pico-to-nanonewtons with a ratiometric force probe for monitoring nanoscale polymer physics before damage

ピンと張られた分子鎖を定量する「羽ばたき型蛍光Force Probe」の開発 --高分子材料の中で力のかかった分子鎖の比率を蛍光イメージングで計測する--. 京都大学プレスリリース. 2022-01-14.Understanding the transmission of nanoscale forces in the pico-to-nanonewton range is important in polymer physics. While physical approaches have limitations in analyzing the local force distribution in condensed environments, chemical analysis using force probes is promising. However, there are stringent requirements for probing the local forces generated before structural damage. The magnitude of those forces corresponds to the range below covalent bond scission (from 200 pN to several nN) and above thermal fluctuation (several pN). Here, we report a conformationally flexible dual-fluorescence force probe with a theoretically estimated threshold of approximately 100 pN. This probe enables ratiometric analysis of the distribution of local forces in a stretched polymer chain network. Without changing the intrinsic properties of the polymer, the force distribution was reversibly monitored in real time. Chemical control of the probe location demonstrated that the local stress concentration is twice as biased at crosslinkers than at main chains, particularly in a strain-hardening region. Due to the high sensitivity, the percentage of the stressed force probes was estimated to be more than 1000 times higher than the activation rate of a conventional mechanophore