Exposition Of Green Energy Development Integration In Mantang Village Area Bintan

. Green Energy from the perspective of energy processing and utilization is fundamental in sustainable regional expansion. This research gathered 12 hamlets in the coordinate area of Mantang Island in Bintan Regency as representatives for realizing the Lagrange and Laplace transform method used is determining utilization targets, regulations regarding the selection of types of energy sources and regulations regarding the use of technology in the form of indicators of extensive evolution. based on proportional accumulation of the observation area from 2020 to 2023, this research implements a form of affiliate quality improvement version and performance calculations, and extensively utilizes economic constraints and technology indicator study patterns, to examine Lagrange and Laplace transform patterns and spatial dissemination of green energy development in the testing area. the results show the following. (1) the causes influencing the development of green energy in the research area indicate that the gradation of impact of the three aspects is growing, and the gradation of impact of one of the qualities is shrinking, and the percentage of divergence is gradually decreasing, which shows the concept of infrastructure versus environmental preferences. (2) Large Mantang and Small Mantang in the current conditions and the tendency to use green energy and changes in the islands need to be taken into account. Mantang Besar, Bintan Regency is in a good status, while Mantang Kecil has little green energy exploitation potential and it is hoped that this will be explored. (3) The sample area shows ''high-high'' or ''low-low'' agglomeration, the result is special treatment in the form of a subsidy on the selling priceelectricity produced using renewable energy and subsidies for the purchase price of fuel originating from renewable energy, utilization of bioenergy for electricity generation reached 1,717.9 MW


Introduction
Geographical conditions of the Mantang District area from sea level are: ± 0 -200 m 2 with an estimated area of ± 1,223.10 km 2 with annual rainfall of 1,500 Mm with an average wind speed of 1,200 Ms with a maximum temperature of 36 0 C with a minimum temperature of 24 0 C. Mantang District is mostly located on Mantang Island.The islands in Mantang District currently consist of 39 islands, of which 14 are inhabited and the other 25 are small, uninhabited islands.The Mantang District area is a marine area so the sea area is larger than the land area.The land area of Mantang District is + 114.00 km 2 , while the sea area is much larger than the land area, namely +1,109.10km 2 so that the total area of Mantang District is +1,223.10km 2 ,The current problem is related to the ownership of large fossil fuel resources, which has become an obstacle in the exploration of green energy in the archipelago.The cause of high fuel consumption is due to economic development and population growth as well as the inelastic nature of goods and ease of access.The development of green energy is a way of economic growth and social development aimed at efficiency, harmony and sustainable capabilities.Its main functions are as follows: first, environmental resources are taken as internal elements of social and economic growth; second, the realization of sustainable economic, community and environmental development results; and third, the ''green'' and ''ecological'' nature of the processes and results of economic activities should be considered as the main components and approaches to the development of green energy.A comprehensive evaluation of the islands regarding the development of green energy displays a process that takes the village development of the affected islands and surrounding ecosystem areas as the object of study; starting from the structure, input and output, processes and efficiency of system islands; aiming for efficiency, harmony and sustainability; and utilize indices that include island system composition and pattern, function and vitality, resilience and coordination [4]- [6], etc.As a foundation for island ecology, green energy development planning and village energy consumption, management, comprehensive evaluation of islands, green energy development is an important area of sustainable energy research and has always been a hotly discussed area in the spotlight of all sectors of society as well as many scholars, to carry out a comprehensive evaluation of development.green energy from the perspective of energy consumption, existing research mainly focuses on the following aspects.1) Research perspective.In 1987, according to a Report of the World Commission on Environment and Development (WCED), ''sustainable development'' is development that meets the needs of the present, without compromising the ability of future generations to meet their own needs [7].The Fifth Ministerial Conference on Environment and Development (MCED), held at the United Nations Economic and Development Conference of the Social Commission for Asia and the Pacific in 2005, documented that the growth of green energy emphasizes environmentally friendly and sustainable economic progress to promote low carbon , socially.inclusive development [8].Lin and Benjamin [9] investigated the determinants in measuring the dynamic change of the green energy development growth index (GDGI) and concluded that ''a one unit increase in the change in the best practice gap (BPC) will affect the growth of green energy development in Mantang Island by 102.3 percent, and a one unit increase in efficiency will accelerate the growth of green energy development by 99.41 percent''.Ji et al. [10] outlines three new concepts and approachesThe location of the Mantang Island area can be seen on the following map, Island Mantang part can legitimately expect the developed area to take the lead in accelerating mitigation action, and also do more by way of providing financial assistance.However, they must also recognise that they will also have to do more to reduce their GHG trajectory and provide policy stability to foster investment and guide the transition.Fortunately, there is today a growing perception that the objectives of growth and poverty reduction can be combined with the objective of sustainable climate change through appropriate choices of technology and large investments in critical sectors.There are also important "co-benefits" from a low carbon scenario that could be realised, notably in the form of health benefits from reduced air pollution.Mantang island mitigation plans are important for the Kepulauan Riau as a whole and if all area do indeed make efforts to improve upon their INDCs, Mantang Island would also be expected optimal in implementation green energy.This research attempts to explore the options Pulau Mantang has by comparing the implications of two alternative scenarios for energy use and GHG emissions5 that are consistent with achieving a high growth rate of GDP.One is a business-as-usual (BAU) scenario, which projects energy requirements and the consequent GHG emissions if no special efforts are made to mitigate emissions other than a continuation of past trends.The other is an alternative Low-Carbon (LC) scenario, based on strong action to mitigate GHG emissions, promote greater energy efficiency and shift to cleaner green energy sources.dead time (time delay, transport lag, translate function, shift function), Where; F(t) = unit rectangular pulse = impulse (dirac or simply delta function) The energy intensity of GDP, i.e. energy used per unit of GDP, in the BAU scenario falls from 0.24 kgoe/US$ in 2012 to 0.14 kgoe/US$ in 2032 and further to 0.08 kgoe/US$ in 2047.This decline of 67% in three decades is impressive but since total GDP will be twelve times larger in 2047, total energy demand will be four times larger in this year than in the base year, with obvious implications for the absolute level of emissions.Energy supply assumptions projecting island green energy supply, research focus on primary energy sources that consist of light source, oil and gas as fossil fuels, and non-fossil energy sources such as hydro, nuclear, solar, wind, biofuels etc. Electricity is directly used in many sectors, but it does not figure separately in the supply side projection because it is produced by one or other of the primary energy sources and it is these sources that are included in produtif criteria The supply projection assumes that growth of island green energy production will be slower than in the past, in part reflecting continuing constraints coming from the impact of environmental regulations that have limited the ability of Mantang to increase production.The projections imply a slight increase in the growth rate of oil production, but a slowdown in gas reflecting the lack of proven reserves.

Method
The key elements involved in moving to a low-green energy growth path are reflected in the identity: Emissions/GDP = (Energy/GDP) x (Emissions/ Green Energy).
calculation shows that the emissions associated with any given level of GDP (the left hand side of the identity) can be reduced either by decreasing the green energy intensity of GDP (the first term in round brackets), which broadly covers what may be called demand-side interventions by reducing the emissions intensity of energy konvensional (the second term in round brackets) which refers to supply-side interventions switching the composition of energy to greener energy sources.The demand and supply-side actions simulated using the IESS V 2 calculator, which together produce the LC scenario, Demand -side actions to lower energy intensity of GDP

Model and Formulation
Equations green energy GDP; order P(s) > order Q(s) energy derivative function; concept of the derivative as a point specific value and as a function may confuse calculus of a function energy Based on the single weight of each index calculated by the translational corrected entropy method and the coefficient of variation method, an optimized decision matrix is established.Suppose that the combination weight is wj; then, where α and β represent the determined weight and the homologous preference degree coefficient of the translational corrected entropy method and the coefficient of variation method, respectively.Pursuant to the Euclidean distance function D

Conclusion
According to the analysis, the factors influencing the green energy development of the Mantang Islands study area at different stages in the 2 months of the study, it found that the influence of economic development factors on green energy development gradually decreased, while the influence of social security, energy utilization and ecological environmental factors in green green is increasing, and the magnitude of the influence of the four factors is gradually getting closer, reflecting the coordinated development of the economy, society and the environment.From this point of view, environmentally friendly development on the island of Mantang Besar is relatively good, whereas in Mantang Kecil the energy consumption structure and energy resources with low utilization efficiency are rather poor.Green development in the study area presents a significant spatial agglomeration effect, high-high and low-low agglomeration effects are marked, and the high-low or low-high spatial differentiation effect is not obvious.Judging from the time series, the spatial agglomeration effect has weakened, indicating that regional green energy coordination has gradually improved, and the construction of the green ecological integration process in YRD has achieved remarkable result Growth based on BAU assumptions will produce an outcome which is not environmentally sustainable.Mantang is very likely to achieve the targets indicated in the INDCs, but we know that even if all INDCs are implemented, the in Mantang will fall short of limiting global warming to no more than 2 0 C above pre industrial levels.Hopefully, stronger action by industrialised area, including the provision of appropriate financial and technical support, will be taken in the years ahead and this will island developing to strengthen their other, The LC scenario explored in the research suggests that Mantang can improve the trajectory of GHG emissions very substantially.This requires taking strong action to reduce the energy intensity of GDP in many sectors and also to shift the composition of energy supply towards green sources.Although this scenario still leaves per capita emissions level in 2047 at a high level in the context of global carbon constraints, it does demonstrate that Mantang could peak GHG emissions before the mid-century point if there is a global concerted effort to achieve serious goals

Table 1 .
Final Energy Demand from Different Sectors in BAU Scenarios