Talom Rukbo and the Donyipolo Yelam Kebang: restructuring Adi religious practices in Arunachal Pradesh, Northeast India

The purpose of this dissertation is to examine and contextualize the recent changes in the articulation of Donyipolo faith among the indigenous community of the Adi from the 1980s until the present. This is achieved by documenting both ‘non-formalized’ and ‘formalized’ belief and ritual within this Eastern Himalayan community. Since the mid-1980s, the Adi – led by indigenous activist Talom Rukbo and the Donyipolo Yelam Kebang (Donyipolo Faith Council) – have been restructuring Donyipolo to fit the model of more mainstream religions via a series of processes that could be called ‘formalization’ or ‘institutionalization’, a reformation blueprint that has subsequently spread to neighboring ethnic groups. This ethnography, exploring both folk practice and the modern reformation, is rooted in radical empiricism – in this context, meaning to collect data and allow analysis to arise organically. Radical empiricism is employed alongside vernacular theorizing to allow for the acknowledgement of indigenous theory through which we can trace indigenous agencies and the construction of indigenous lifeworlds. Facilitating this space for the acknowledgement of ‘religious re-imaginings’ as a means of cultural preservation – and as a representation of creativity – is significant particularly when viewed in the context of contemporary research on similar movements in Northeast India, which sometimes tends toward the negation of indigenous innovation by representing such religious revivals as conversion tools attributed to the Hindu right. It is hoped that the reader will come away from this dissertation with an understanding of the ‘constellations of faith’ that comprise ‘traditional’ Donyipolo and a comprehension of the innovative institutionalization processes that have shaped the new Adi praxis. Donyipolo should be viewed as a complex, nuanced, and independent indigenous faith, whether in its forms of folk expressions or in its new structure as expressed through the Donyipolo Yelam Kebang.

A comparative study of the structural, mechanical and tribological characteristics of TiSiC-Cr coatings prepared in CH4 and C2H2 reactive atmosphere by cathodic vacuum arc

TiSiC-Cr coatings, with Cr and Si as additional elements, were deposited on Si, C 45 and 316 L steel substrates via cathodic arc evaporation. Two series of coatings with thicknesses in the range of 3.6–3.9 μm were produced, using either CH4 or C2H2 as carbon containing gas. For each series, different coatings were prepared by varying the carbon rich gas flow rate between 90 and 130 sccm, while maintaining constant cathode currents (110 and 100 A at TiSi and Cr cathodes, respectively), substrate bias (–200 V) and substrate temperature (∼320 °C). The coatings were analyzed for their mechanical characteristics (hardness, adhesion) and tribological performance (friction, wear), along with their elemental and phase composition, chemical bonds, crystalline structure and cross-sectional morphology. The coatings were found to be formed with nano-scale composite structures consisting of carbide crystallites (grain size of 3.1–8.2 nm) and amorphous hydrogenated carbon. The experimental results showed significant differences between the two coating series, where the films formed from C2H2 exhibited markedly superior characteristics in terms of microstructure, morphology, hardness, friction behaviour and wear resistance. For the coatings prepared using CH4, the measured values of crystallite size, hardness, friction coefficient and wear rate were in the ranges of 7.2–8.2 nm, 26–30 GPa, 0.3–0.4 and 2.1–4.8 × 10−6 mm3 N−1 m−1, respectively, while for the coatings grown in C2H2, the values of these characteristics were found to be in the ranges of 3.1–3.7 nm, 41–45 GPa, 0.1–0.2 and 1.4–3.0 × 10−6 mm3 N−1 m−1, respectively. Among the investigated coatings, the one produced using C2H2 at the highest flow rate (130 sccm) exhibited the highest hardness (45.1 GPa), the lowest friction coefficient (0.10) and the best wear resistance (wear rate of 1.4 × 10−6 mm3 N−1 m−1).