The real solution to Carbon problem

The real solution for Carbon problem:

When mother nature buried Carbon under the ground by way of fossil, we human beings mined them at enormous cost and added further value by combustion with air converting it into CO2 (carbon dioxide). In fact, we human beings added enormous value to carbon that remained buried (with zero value) for millennia. We were interested in the heat of combustion but forgotten about the CO2 emission. This is the fundamental flaw in the commercialization of thermal power using fossil fuels. Now there is a price to pay. There are only 2 options to overcome this problem.

1    We can completely ignore and ban fossil fuel all together at enormous cost (we have already invested in trillions in mining, processing, transporting and storing) and seek completely a new solution without any Carbon at all. This is unlikely to happen.

2      We can continue to use fossil fuel and generate base load power as we have been doing for decades but capture CO2 and convert it back into fuel so that it can be recycled with Zero CO2 emission. This is certainly feasible.

Many “so called innovators” are suggesting alternatives to fossil power generation using renewable source of energy. These sources were available with us from the beginning of the world as we know it, but they are intermittent. We are used to 24

x7 base load power using fossil fuels.

The real solution lies in using intermittent renewable energy to generate base load power (24 x 7) with zero Carbon emission. Renewable Hydrogen can achieve this goal. In doing so battery can also play a small role but not a major role. Couple of things should happen to achieve this goal.

1.     Capturing CO2 at the lowest cost. It can be best achieved using Oxy combustion of fossil fuel such as LNG (because it is a purified form of natural gas) using Brayton cycle with 100 % CO2 capture.

2.     Generate renewable Hydrogen (RH) using electrolysis using renewable energy source such as solar and wind etc. Technology is well proven and commercially available.

3.     Convert captured CO2 into CH4 using methanation reaction (which is already commercially practised) and recycling CH4 as a fuel to continue the base load power generation as usual. The newly generated CH4 becomes a renewable natural gas (RNG) by substituting fossil Hydrogen with renewable Hydrogen (RH). This technology developed by CEWT is known as Carbon Recycling Technology (CRT). It is a perfect example of a circular economy. Governments around the world should scrap fossil subsidies, tax Carbon @ $100.Mt ( at least) and offer liberal subsidies to renewable energy so that the cost of renewable hydrogen (RH) is at the lowest. CRT will allow Carbon to remain below ground as nature has done for several years. CRT will allow to run base load power (24 x 7) using RNG with ZERO CARBON EMISSION.

The above process is the only economical, commercial and environmental solution to the problem of global warming and climate change. All other methods will be expensive, time consuming with no guaranteed results and are unlikely to happen in the shortest time we have.

We at CEWT have the solution (not just theoretical but practically and commercially implementable immediately) and we seek like-minded partners and investors to team up with us so that we can show case the technology and implement them worldwide.

Renewable Hydrogen, an emerging alternative to fossil fuel

Fossil fuels such as coal, oil and gas have helped transformed our power and transport industries for decades till now. But recent geo-political situations, depleting fossil sources and Carbon pollution, global warming and climate change have raised serious questions about the future of fossil fuels. However, countries who have massively invested in fossil fuel infrastructure and who have been heavily relying on supply of fossil fuels have started realizing an inescapable truth that they are running out of time to find an alternative to fossil fuels. Recently Hydrogen has been suggested as an alternative source of energy and many countries are gearing up to promote Hydrogen on a massive scale. The countries who have been traditionally using fossil fuels are now focussing on generating hydrogen from fossil fuels as an easier option. But the basic problem with this approach is they still depend on fossil fuels which means they still contribute to Carbon emission and climate change. They can conveniently dispute or deny the fact that man-made Carbon emissions cause global warming in order to score political points among the ‘gullible public’. Democracy is all about numbers and as along as these number stack up the political parties will take advantage of the system and try to push their agenda. But all these efforts are only short term and they still cannot escape the truth that man made Carbon emission is transforming our world for the worst and the future looks bleak. However, there is a silver lining in the dark clouds of global warming and climate change in the form of renewable Hydrogen. It is now possible to generate Hydrogen using renewable energy sources such as Hydro, solar, wind, geothermal and OTEC (ocean thermal energy conversion systems) that can used not only decarbonize our present economy and also has the capacity to transform future energy and to a cleaner and more sustainable environment. It is now possible to achieve a circular economy in energy sector which means the CO2 emission from existing and operating power plants using fossil fuels can be reversed using renewable Hydrogen so that one can continue to generate power but with Zero Carbon emission. This is a huge transformation. However, the usage of fossil fuels will continue in other industries such as petrochemicals, polymers and additives, and other synthetic materials. But one can take advantage of using renewable Hydrogen even in such industries using Green Chemistry initiatives so that they can become more sustainable. However Renewable Hydrogen is currently very expensive though it is generated from abundantly available natural resources such as sun, wind and water because PV solar panels are made from high purity silicon material again made from simple sand. We cannot afford to take natural resources lightly because they are precious commodities. With limited usage of renewable energy at current levels the cost of PV solar panels is still very expensive but likely to come down as we deploy more and more solar panels in the future. We should also be careful how we use renewable Hydrogen. Our first and foremost usage of renewable Hydrogen should be to decarbonize the fossil economy and achieve a circular economy. It means we must convert CO2 emissions into renewable natural gas (RNG) using renewable Hydrogen so that the Carbon can be recycled indefinitely with Zero Carbon emission while power plants using fossil fuels can continue to generate a base load power. By this way we will be able to address two issues namely meeting the rising energy demand at a cheaper price while eliminating global warming and climate change. All other use of renewable hydrogen such as Hydrogen vehicles for transportation using fuel cell etc will be secondary because they are not our priority. If we can generate a base load power (24 x7) using renewable Hydrogen with zero Carbon emission, then that should be our focus whether we believe it climate science or not. This will also help us conserve fossil fuels that may be rarely used to meet certain critical needs while substantially reducing the carbon emission. Renewable hydrogen will require massive deployment of renewable energy projects all over the world. One can generate renewable energy and use it directly for domestic or commercial use. But they are intermittent and require large scale energy storage. Moreover, all HT transmission lines are old and designed for transmitting base load power. Such an approach will not help decarbonizing fossil economy currently widely used. That is why renewable Hydrogen will have to play a key role in the future energy mix. Renewable hydrogen can be used as a fuel for transport industries using fuel cell and Japan is leading the way in this field. But such an application has along way to go and it requires massive investment and creation of infrastructure by way of filling stations. Countries like Japan do not have vast land area for solar industries, and they are likely to use cheap nuclear power and sea water to generate large scale hydrogen infrastructure. By this way they can supply power to both hydrogen as well as electric (battery) vehicles. Alternatively, they are looking to import liquified hydrogen (LH2) from countries like Australia who are ready to use cheap brown coal to generate Hydrogen by gasification despite CO2 emissions. Currently Australian government is very keen to encourage LH2 from cheap coal. They have already approved a pilot plant in the state of Victoria and only future can tell whether such a decision is prudent or not. Japanese companies may prefer to invest in Australia to generate and export clean liquid hydrogen leaving behind all emissions including CO2 in Australia. They may generate LH2 from natural gas and export it to Japan, but it may not be acceptable by Japanese companies because it has a potential to poison the Platinum catalyst used in their Fuel cell cars. In fact, Australia has an enormous potential to generate renewable hydrogen and then use it locally as well as to export. This will be more sustainable in the long run.