Green hydrogen , often heralded as the fuel of the future, holds tremendous promise in the global transition towards sustainable energy systems. As the world grapples with the urgent need to reduce greenhouse gas emissions and mitigate climate change, green hydrogen emerges as a versatile and clean energy carrier with the potential to revolutionize various sectors, including transportation, industry, and electricity generation. This article explores the concept of green hydrogen, its production methods, applications, challenges, and future prospects in the quest for a decarbonized world. Understanding Green Hydrogen Hydrogen, the most abundant element in the universe, has long been recognized as a potential energy carrier due to its high energy density and clean combustion properties. However, the conventional methods of producing hydrogen, such as steam methane reforming (SMR) and coal gasification, rely on fossil fuels and emit significant amounts of carbon dioxide (CO2), contributin...

  Whether a reaction is product-favored, that is, whether the reactants are converted to products under standard-state conditions, is reflected in the sign of its Δ r G° . This equation Δ r G° =  Δ r H° − T Δ r S° shows that the sign of Δ r G°  depends on the signs of Δ r H°  and Δ r S° , and, in some cases, the absolute temperature (which can only have positive values). Four possibilities exist: Both Δ r H°  and Δ r S°  are positive —an endothermic process with an increase in system entropy. Δ r G°  is negative if  T Δ r S° >  Δ r H° , and positive if  T Δ r S°  < Δ r H° . Such a process is  product-favored at high temperatures and reactant-favored at low temperatures. Both Δ r H°  and Δ r S°  are negative —an exothermic process with a decrease in system entropy. Δ r G°  is negative if | T Δ r S °| < |Δ r H °| and positive if | T Δ r S °| > |Δ r H °|. Such a process is  product-favored at low te...

 Quickly revise about different types of enthalpies of reaction

  Isomerism in organic chemistry

Reaction Chart of Haloalkanes Reaction chart of Haloarenes E1 vs E2 Differences between SN1 and SN2 Haloalkanes and Haloarenes class notes