In line with the 2015 Paris Agreement, the present study examines the efficiency of Iran’s electricity industry compared to world standards. In 2018, Iran is ranked second in the world in terms of direct subsidies to the electricity industry, while subsidies for fossil fuels as the main feedstock for power plants are also higher. The results of the study indicate that despite the privatization of the electric industry since 2005, centralized economic management and the provision of extensive direct and indirect subsidies have led to the expansion of inefficiencies in the production and consumption of electricity. Lack of cost-based pricing is a major factor in the production of inefficient units and the determination of electricity prices at very low levels (as a result of subsidies) is the main reason for the inefficient use of electricity in Iran. The undeniable role of fossil fuels in energy production has stabilized Iran’s second-largest power plant sector in CO2 emissions in the Middle East, and as a consequence of no noticeable changes in the energy production process, the carbon intensity index and carbon intensity for electricity consumption, have fluctuated slightly. However, the energy intensity and energy intensity for electricity consumption, unlike the developed countries, have shown an upward trend, indicating a decline in energy and electrical energy efficiency in the Iranian economy. The index of fundamental reforms in electricity production, exactly the reverse of the successes in Iceland, Switzerland, Norway, Sweden and Luxembourg, is less than 8%, which is against sustainable development goals. It is crucial to take advantage of countries’ successful experiences in electricity price reform and to address the four key components proposed.

The Himalayan region has been known as water abundant region in the form of innumerable natural water resources such as springs, streams, rivulets, etc. However, off late owing to climatic and anthropogenic reasons the entire region is soon turning into a water-deficit region leading to serious handicaps in undertaking the basic economic activities, affecting the diversity of livelihood and the drinking water sector. The problem becomes more acute in the dry season or non-monsoonal season.There seems to be a research void in the sustainable water resource planning of the Himalayan states. The present work is an attempt to study this research void through grass-root level analysis of the villages in Mizoram. Twelve villages of the Phullen RD block of Aizawl district, Mizoram were studied to understand the water supply and problems associated with water availability in the rural areas of Mizoram. In the villages of Mizoram, particularly the villages of the study area, Tuikhur or village spring source (VSS) and piped water supply constitute the main lifeline of water supply. Other sources of water include rainwater harvested and water taken from the stream or river. The springs which were once perennial have become seasonal owing to lack of spring shed management. Rainwater harvesting, barring inconsequential villages, is meagrely existent in this region of abundant rainfall with almost 130 days of rainfall. In the absence of proper water resource planning, there is a huge deficit of water every month with the average requirement of the study area being 2,49,148 gallons per month with a supply of just 2,14,248 gallons per month. However, water surplus was also observed in villages having a proper water management system in the form of rainwater harvesting and spring shed management.

The present study was designed to display the integrated model of nitrogen discharge process (i.e. nitrites and nitrates; ammonia; chlorophyll and dissolved nitrogen, dissolved oxygen) which is part of the complete model of shrimp aquaculture of an Integrated Shrimp Aquaculture Park (i-Sharp) ecosystem in System Dynamic Model Aquaculture-System Policy (SD-AQEP). This study offers a comprehensive elaboration concerning the long-term process of nitrogen accumulation, as well as its effects on shrimp activities. Furthermore, the analysis of the model and the simulation results also show the conditions of nitrogen with several strategies for control and manipulation. For example, in situations where mixing of stock density is high and providing feed into ponds supplies is excessive, the nitrogen dynamic rapidly hits alarming levels. Aforementioned, the typical strategy in this setting such as stocking density and the best time to harvest could be established. Additionally, the model structure represents the discharge derived from the nitrogen process on varied settings of variables in aquaculture development. In conclusion, this model provides an experimental simulation platform that can be implemented by policy makers on long-term strategic management for developing or maintaining large-scale aquaculture development projects in the future.