Engineering Game Theory of Green Hydrogen towards Energy Transition using Shariah Jurisprudence Developmental Framework based on Ethical Decision-making from Philosophy of Technology
DOI:
https://doi.org/10.47672/ejt.1412Keywords:
Green hydrogen, renewable energies, game theory, energy transition, solar energyAbstract
Purpose: This paper is designed to address problems on commercial laws and illustrate sustainable development modellings of ethical decision-making and shariah jurisprudence method to interpret the statutory laws for renewable energies and develop an equation for exhibition of its economic impacts along with the 2050 planning of storage capacity for renewable power percentage of energy transition in relation to service of electricity demands.
Methodology: Hamburg to Rotterdam Rules are legal instruments of commercial transactions pertaining to transportation laws of goods under agreements. Meanwhile, statutory interpretation serves as an illustration of legislative framework formulated for public welfare and safety, in harmony with constitutional laws. Electricity regulations are statutory laws for reflexive judgement of the laws of thermodynamics pertaining to mass conservation, momentum theorem, and energy equation concerning economics of the business environment.
Findings: Green hydrogen is a technical product of concession for renewable energies. The paradigm shift to solar power is a form of energy transition to target carbon emission towards zero level through reduction of greenhouse gases. Sustainable development is a monetary framework of business innovations and marketing of goods and services. However, there are apparent limitations on these contract laws, hence, issues can be raised concerning environmental laws of business transactions pertaining to technological services.
Recommendation: If green economy is the 2050 plan of energy transition, the pressure relative to viscosity of hydrogen power of solar energy must be developed congruent to Ideal Gas Law, exhibiting relativity to Euler and Lorenz number in connection with thermal conductivity and its resistance akin to viscosity.
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Copyright (c) 2023 Zharama M. Llarena
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