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Italy’s and EU’s natural gas imports from the United States

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Currently natural gas is one of the most important US assets in its relations with the European Union.

In fact, President Trump and President Jean Claude Juncker spoke at length about it during their last meeting at the White House at the end of July 2018.

Obviously the issue of the US natural gas sales is linked to a broader strategic theme for President Trump.

He wants to redesign – especially with the EU – the system of tariffs and rebalance world trade.

He also wants to recreate a commercial and economic hegemony between the United States and the EU – a hegemony that had tarnished over the last decade.

With the EU, the United States has already achieved a zero-tariff regime for most of the goods traded, also removing non-tariff barriers and all the subsidies to non-automotive goods.

Moreover, since late July last, both sides have decided to increase inter-Atlantic trade in services, chemicals, pharmaceuticals, medical products and – as a central issue in their relations with China – soybeans.

What China no longer buys – since it has been burdened with tariffs and duties – is resold to the European Union.

In fact, soy was bought massively by European consumers, as Jean Claude Juncker later added.

The demand for natural gas, however, is on the rise all over the world.

Currently Europe is in difficulty for this specific energy sector, considering that the large gas extraction field in Groningen, Netherlands, suffered an earthquake at the beginning of January 2018.

The Dutch extraction area, however, is managed jointly by both Royal Dutch Shell and Exxon-Mobil.

The North American analysts think that, for the whole EU, the other natural gas sources are at their peak of exploitation.

Gas sources such as Russia, Turkey, Central Asia and the Maghreb region are supposed to be soon saturated as a result of the growth in EU gas consumption and, therefore, the United States is thinking to sell much of its LNG to Europe as well.

With an obvious strategic and geopolitical pendant.

This holds particularly true – at least for the time being – for the Algerian gas, while the United States is currently pressing for a diversification from the Russian pipelines, offering its liquefied natural gas (LNG) for ships to   Northern Europe’s terminals and, recently, also to the Italian ones.

Across the European Union, the natural gas terminals are 28, including Turkey.

There are also eight other small natural gas terminals in Finland, Sweden, Germany, Norway and Gibraltar.

Said terminals are 23 in the EU and 4 in Turkey; 23 are land-based and 4 are at sea for storage and regasification, and the Malta terminal includes both a ground base and a maritime unit.

Italy, one of the largest LNG consumers in Europe, produces a good share of natural gas internally, but it still imports 90% of the gas it consumes, while 60% of Italy’s LNG consumption is divided almost equally between two suppliers, Algeria and the Russian Federation.

By way of comparison, France extracts domestically only 1% of the natural gas it consumes every year.

Also Germany, like Italy, imports much gas from Russia – about 50% of its yearly consumption.

From where, however, does Italy import its natural gas? From Russia, as already seen, as well as from Algeria, Libya, Holland and Norway.

Then there is the Trans Austria Gas (TAG), a network which, again from Russia, brings gas to the Slovakian-Austrian border (precisely to Baumgarten an der March up to Arnoldstein in Southern Austria) with a maximum capacity of 107 million cubic meters per day.

There is also Transitgas, crossing Wallbach, Switzerland, up to Passo Gries, where it intersects with the SNAM network.

It is also connected to Gaz de France and has a maximum capacity of 59 million cubic meters per day.

A significant role is also played by the Trans Tunisian Pipeline Company (TTPC), a network with a capacity of 108 million cubic meters per day, stretching from Oued al Saf, between Tunisia and Algeria, to Cape Bon, where it connects with the Trans-Mediterranean Pipeline Company (TMPC). The network reaches Mazara del Vallo, where it enters the SNAM system.

The security of this line was a factor considered in the decision taken by the Italian intelligence services to participate actively in the struggle for succession in Tunisia, after Habib Bourghiba’s political end.

The Greenstream pipeline connects Libya to Italy, with a maximum capacity of 46.7 million cubic meters per day, with regasifiers located in Panigaglia and off Leghorn’s coast (OLT), as well as off Rovigo’s coast.

It should be recalled that, in July 2018, ENI opened production in the offshore plant of Bar Essalam, a site 120 kilometres off Tripoli’s coast, which could contain 260 billion cubic meters of gas, while the French company Total paid 450 million dollars to buy – from the United States -16% of the oil concession in Waha, Libya.

As is well known, the TAP is under construction.

With a maximum capacity of 24.6 million cubic meters per day, it stretches from Greece to Italy through Albania.

There is also the IGI Poseidon, again between Greece and Italy, as well as the regasification terminal of Porto Empedocle, and the other terminals of Gioia Tauro and Falconara Marittima.

Shortly the pipelines from Algeria to Sardinia could be operational, with a terminal in Piombino, as well as the one in Zaule, and the regasification plant in Monfalcone.

Hence if all these networks are already operational or will be so in the near future, Italy alone could shift the axis of the natural gas transport from the North (namely Great Britain and Holland) to the South (namely Italy and Greece).

If this operation is successful, Italy could become the future natural gas energy hub, thus making it turn from a mere consumer to an exporter of natural gas.

In 2020, SNAM plans to bring 4.5 billion cubic meters of gas from the Trans-Adriatic Pipeline, which transports Azerbaijan’s LNG, jointly with BP.

This is a further phase of reduction of the EU dependence on Russian gas.

But also the purchase of LNG from the United States could undermine the Italian plan of becoming the European natural gas hub, as against the Dutch-British system.

Obviously the liquefied natural gas is sold by the United States mainly as an operation against Russia.

Currently, the American LNG has prices that are approximately 50% lower than the Russian gas prices.

As pointed out by one of the major Italian energy experts, Davide tabarelli, the price is 8 euros per megawatt / hour as against 22 euros of the LNG coming from Russia.

For the time being, however, China is the world’s top LNG buyer, with a 40% increase in its consumption.

Nevertheless, while China’s gas consumption is booming, the ships carrying natural gas from the United States tend to go right to Asia, where, inter alia, a much higher price than the European average can be charged.

In the EU, however, the Russian gas can be bought at 3.5-4 dollars per Mega British Thermal Unit (MBtu) while the break-even price of the US gas, which is much more expensive to produce, is around 6-7.5 MBtu, including transport.

Competition, however, is still fierce, given that the EU regasifiers are used at 27% of their potential, and considering Qatar’s harsh competition with the United States. It is worth recalling that Qatar is a large producer of natural gas with the South Pars II field, in connection with Iran.

In the near future, the small Emirate plans to sell at least 100 million tons of LNG per year, opposed only by Saudi Arabia’s reaction. According to the usual rating agencies, at banking level Qatar is also expected to suffer the pressure of Saudi Arabia and its allies, including the United States.

Nevertheless, if the cost of the trans-Atlantic transport and the cost of regasification in our terminals are added to the 8 euros about which Tabarelli speaks, we can see that the US gas and the Russian LNG prices tend to become the same.

Russia has also much lower gas production costs than the United States, considering that most of the North American LNG is extracted with shale or fracking technologies, which are much more expensive than the Russian ones.

It should be recalled that in 2017 the Russian Federation was the world’s top natural gas exporter, with a record peak of 190 billion cubic meters, accounting for 40% of all EU consumption.

Moreover, thanks to fracking technologies, the United States has become the world’s largest crude oil producer, but also the largest consumer globally. Hence no additional room for its exports of non-gas hydrocarbons can be easily envisaged.

Certainly buying American gas would mean avoiding the US import tariffs for European cars in the future, which would lead many EU governments to willingly accept President Trump’s offer.

Furthermore, ENI is finding much oil and much natural gas in Egypt, which could lead to the building of a pipeline from the Egyptian coast to which also the Israeli natural gas could join.

This implies a significant weakening of both the Egyptian domestic crisis and the tensions between the “moderate” Arab world and the Jewish State.

In fact, in the concession of Obayed East, Egypt, ENI has found a natural gas reserve of 25 million cubic meters per day which, together with the recent discoveries of the Zohr, Norus and Atol deposits, is expected to make Egypt achieve energy autonomy and independence before early winter 2018-2019.

This, too, could be one of President Trump’s geo-energy goal, along with Israel’s expansion on this market. In all likelihood, however, Russia will remain one of the largest or still the largest LNG seller to the whole EU.

However, let us better analyse the situation: with the South Pars II field it shares with Qatar, also Iran could provide the EU with a large part of its yearly natural gas requirements.

Iran is a Russian ally although, in this case, strategic friendships are always less sound than economic interests.

Furthermore, the war in Syria resulted – and probably this is also one of its underlying causes – in a block of future Iranian pipelines to the Mediterranean.

Moreover, China has bought the shareholdings held by the French Total on the Iranian territory.

For the time being, however, the United States sells much of its LNG to Asia and Latin America, where currently prices are still higher than in Europe.

Hence, like all consumer countries, the EU is interested in diversifying its energy suppliers. Nevertheless, the war in Syria has blocked Iran and the war in Libya has made the Greenstream pipeline, which is essential for Italy, unusable.

It should be recalled that Greenstream is the 520-kilometre pipeline connecting Libya to Italy directly.

Almost all the Libyan gas, however, is currently consumed inside the country.

Moreover, at this stage, President Trump would like Germany to stop even the doubling of Nord Stream 2 from the Russian coast to the German Baltic Sea.

The Ukrainian leadership is also urging the EU to avoid doubling this project, considering the forthcoming expiry of the Ukrainian contracts for the Russian natural gas.

If this happens, as from 2022 Poland will buy a large share of its natural gas from the United States, thus avoiding the Russian LNG.

Nevertheless, the United States will also favour the Southern Gas Corridor in Azerbaijan and Turkey, with a view to transferring the Caspian natural gas to the EU through Apulia.

Hence Italy would be disadvantaged: instead of using its lines and routes with Libya and Algeria, or Russia, it should buy the Caucasian gas, which will be fully managed by US companies – and this holds true also for the US natural gas direct sales, which have recently started in some Italian ports.

A dangerous political calculation, as well as a risky commercial evaluation.

Advisory Board Co-chair Honoris Causa Professor Giancarlo Elia Valori is an eminent Italian economist and businessman. He holds prestigious academic distinctions and national orders. Mr. Valori has lectured on international affairs and economics at the world’s leading universities such as Peking University, the Hebrew University of Jerusalem and the Yeshiva University in New York. He currently chairs “International World Group”, he is also the honorary president of Huawei Italy, economic adviser to the Chinese giant HNA Group. In 1992 he was appointed Officier de la Légion d’Honneur de la République Francaise, with this motivation: “A man who can see across borders to understand the world” and in 2002 he received the title “Honorable” of the Académie des Sciences de l’Institut de France. “

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Oil and the new world order: China, Iran and Eurasia

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The world oil market will undergo a fundamental change in the future. Choosing petrodollars or oil wars is no longer a question that can be answered. With the Strategic Agreement on the Comprehensive Economic and Security Partnership between China and Iran officially signed by the Foreign Ministers of both countries in Tehran on March 27, 2021, the petrodollar theorem is broken and the empire built by the US dollar is cracked.

This is because the petrodollar has not brought substantial economic development to the oil-producing countries in the Middle East during over half a century of linkage to the US dollar.

The Middle East countries generally have not their own industrial systems. The national economies are heavily dependent on oil exports and imports of cereals and industrial products. The national finances are driven by the US dollar and the financial system that follows it.

If the Middle East countries wanted to escape the control of the dollar, they should face the threat of war from the United States and its allies – things we have seen over and over again. Just think of Saddam Hussein being supported when he was fighting Iran and later being Public Enemy No. 1 when he started trading oil in euros.

The West has always wanted the Middle East to be an oil ‘sacred cow’ and has not enabled it to develop its own modern industrial system: the lack of progress in the Middle East was intended as long-term blackmail.

In the Western system of civilisation based on exchange of views and competition, the West is concerned that Iran and the entire Middle East may once again restore the former glory and hegemony of the Persian, Arab and Ottoman empires.

China is facing the exploitation of the global oil market and the threat of its supply disruption. Relying on industrial, financial, and military strength, Europe and the United States control the oil production capital, trade markets, dollar settlements, and global waterways that make up the entire petrodollar world order, differentiating China and the Middle East and dividing the world on the basis of the well-known considerations. You either choose the dollar or you choose war – and the dollar has long been suffering.

Just as in ancient times nomadic tribes blocked the Silk Road and monopolised trade between East and West, Europe and the United States are holding back and halting cooperation and development of the whole of Asia and the rest of the planet. Centuries ago, it was a prairie cavalry, bows, arrows and scimitars: today it is a navy ship and a financial system denominated in dollars.

Therefore, China and Iran, as well as the entire Middle East, are currently looking for ways to avoid middlemen and intermediaries and make the difference. If there is another strong power that can provide military security and at the same time offer sufficient funds and industrial products, the whole Middle East oil can be freed from the dominance of the dollar and can trade directly to meet demand, and even introduce new modern industrial systems.

Keeping oil away from the US dollar and wars and using oil for cooperation, mutual assistance and common development is the inner voice of the entire Middle East and developing countries: a power that together cannot be ignored in the world.

The former Soviet Union had hoped to use that power and strength to improve its system. However, it overemphasised its own geostrategic and paracolonial interests – turning itself into a social-imperialist superpower competing with the White House. Moreover, the USSR lacked a cooperative and shared mechanism to strengthen its alliances, and eventually its own cronies began to rebel as early as the 1960s.

More importantly – although the Soviet Union at the time could provide military security guarantees for allied countries – it was difficult for it to provide economic guarantees and markets, although the Soviet Union itself was a major oil exporter. The natural competitive relationship between the Soviet Union and the Middle East, as well as the Soviet Union’s weak industrial capacity, eventually led to the disintegration of the whole system, starting with the defection of Sadat’s Egypt in 1972. Hence the world reverted to the unipolarised dollar governance once the Soviet katekon collapsed nineteen years later.

With the development and rise of its economy, however, now China has also begun to enter the world scene and needs to establish its own new world order, after being treated as a trading post by Britain in the 19th century, later divided into zones of influence by the West and Japan, and then quarantined by the United States after the Second World War.

Unlike the US and Soviet world order, China’s proposal is not a paracolonial project based on its own national interests, nor is it an old-fashioned “African globalisation” plan based on multinationals, and it is certainly not an ideological export.

For years, there has been talk of Socialism with Chinese characteristics and certainly not of attempts to impose China’s Marxism on the rest of the world, as was the case with Russia. China, instead, wishes to have a new international economic order characterised by cooperation, mutual assistance and common development.

Unlike the Western civilisation based on rivalry and competition, the Eastern civilisation, which pays more attention to harmony without differences and to coordinated development, is trying to establish a new world economic order with a completely different model from those that wrote history in blood.

Reverting to the previous treaty, between the US dollar and the war, China has offered Iran and even the world a third choice. China seems increasingly willing to exist as a service provider. This seems to be more useful for China, first of all to solve its own problems and not to get involved in endless international disputes.

It can thus be more accepted by all countries around the world and unite more States to break the joint encirclement of the “democratic” and liberal imperialism of Europe and the United States.

Consequently, China and Iran – whose origins date back almost to the same period – met at a critical moment in history. According to the Strategic Agreement on Comprehensive Economic and Security Partnership between China and Iran, China will invest up to 400 billion dollars in dozens of oil fields in Iran over the next 25 years, as well as in banking, telecommunications, ports, railways, healthcare, 5G networks, GPS, etc.

China will help Iran build the entire modern industrial system. At the same time, it will receive a heavily discounted and long-term stable supply of Iranian oil. The Sino-Iranian partnership will lay the foundations for a proposed new world order, with great respect for Eastern values, not based on some failed, decadent and increasingly radicalising principles.

Faced with the value restraint and the pressure of sanctions from the United States and Europe, China is seeking to unite the European third Rome, Indo-European Iran, the second Rome and the five Central Asian countries to create a powerful geoeconomic counterpart in the hinterland of Eurasia.

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The stages and choices of energy production from hydrogen

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There are three main ways to use hydrogen energy:

1) internal combustion;

2) conversion to electricity using a fuel cell;

3) nuclear fusion.

The basic principle of a hydrogen internal combustion engine is the same as that of a gasoline or diesel internal combustion engine. The hydrogen internal combustion engine is a slightly modified version of the traditional gasoline internal combustion engine. Hydrogen internal combustion burns hydrogen directly without using other fuels or producing exhaust water vapour.

Hydrogen internal combustion engines do not require any expensive special environment or catalysts to fully do the job – hence there are no problems of excessive costs. Many successfully developed hydrogen internal combustion engines are hybrid, meaning they can use liquid hydrogen or gasoline as fuel.

The hydrogen internal combustion engine thus becomes a good transition product. For example, if you cannot reach your destination after refuelling, but you find a hydrogen refuelling station, you can use hydrogen as fuel. Or you can use liquid hydrogen first and then a regular refuelling station. Therefore, people will not be afraid of using hydrogen-powered vehicles when hydrogen refuelling stations are not yet widespread.

The hydrogen internal combustion engine has a small ignition energy; it is easy to achieve combustion – hence better fuel saving can be achieved under wider working conditions.

The application of hydrogen energy is mainly achieved through fuel cells. The safest and most efficient way to use it is to convert hydrogen energy into electricity through such cells.

The basic principle of hydrogen fuel cell power generation is the reverse reaction of electrolysis of water, hydrogen and oxygen supplied to the cathode and anode, respectively. The hydrogen spreading – after the electrolyte reaction – makes the emitted electrons reach the anode through the cathode by means of an external load.

The main difference between the hydrogen fuel cell and the ordinary battery is that the latter is an energy storage device that stores electrical energy and releases it when needed, while the hydrogen fuel cell is strictly a power generation device, like a power plant.

The same as an electrochemical power generation device that directly converts chemical energy into electrical energy. The use of hydrogen fuel cell to generate electricity, directly converts the combustion chemical energy into electrical energy without combustion.

The energy conversion rate can reach 60% to 80% and has a low pollution rate. The device can be large or small, and it is very flexible. Basically, hydrogen combustion batteries work differently from internal combustion engines: hydrogen combustion batteries generate electricity through chemical reactions to propel cars, while internal combustion engines use heat to drive cars.

Because the fuel cell vehicle does not entail combustion in the process, there is no mechanical loss or corrosion. The electricity generated by the hydrogen combustion battery can be used directly to drive the four wheels of the vehicle, thus leaving out the mechanical transmission device.

The countries that are developing research are aware that the hydrogen combustion engine battery will put an end to pollution. Technology research and development have already successfully produced hydrogen cell vehicles: the cutting-edge car-prucing industries include GM, Ford, Toyota, Mercedes-Benz, BMW and other major international companies.

In the case of nuclear fusion, the combination of hydrogen nuclei (deuterium and tritium) into heavier nuclei (helium) releases huge amounts of energy.

Thermonuclear reactions, or radical changes in atomic nuclei, are currently very promising new energy sources. The hydrogen nuclei involved in the nuclear reaction, such as hydrogen, deuterium, fluorine, lithium, iridium (obtained particularly from meteorites fallen on our planet), etc., obtain the necessary kinetic energy from thermal motion and cause the fusion reaction.

The thermonuclear reaction itself behind the hydrogen bomb explosion, which can produce a large amount of heat in an instant, cannot yet be used for peaceful purposes. Under specific conditions, however, the thermonuclear reaction can achieve a controlled thermonuclear reaction. This is an important aspect for experimental research. The controlled thermonuclear reaction is based on the fusion reactor. Once a fusion reactor is successful, it can provide mankind with the cleanest and most inexhaustible source of energy.

The feasibility of a larger controlled nuclear fusion reactor is tokamak. Tokamak is a toroidal-shaped device that uses a powerful magnetic field to confine plasma. Tokamak is one of several types of magnetic confinement devices developed to produce controlled thermonuclear fusion energy. As of 2021, it is the leading candidate for a fusion reactor.

The name tokamak comes from Russian (toroidal’naja kamera s magnitnymi katuškami: toroidal chamber with magnetic coils). Its magnetic configuration is the result of research conducted in 1950 by Soviet scientists Andrei Dmitrievič Sakharov (1921-1989) and Igor’ Evgen’evič Tamm (1895-1971), although the name dates back more precisely to 1957.

At the centre of tokamak there is a ring-shaped vacuum chamber with coils wound outside. When energized, a huge spiral magnetic field is generated inside the tokamak, which heats the plasma inside to a very high temperature, which achieves the purpose of nuclear fusion.

Energy, resources and environmental problems urgently need hydrogen energy to solve the environmental crisis, but the preparation of hydrogen energy is not yet mature, and most of the research on hydrogen storage materials is still in the exploratory laboratory stage. Hydrogen energy production should also focus on the “biological” production of hydrogen.

Other methods of hydrogen production are unsustainable and do not meet scientific development requirements. Within biological production, microbial production requires an organic combination of genetic engineering and chemical engineering so that existing technology can be fully used to develop hydrogen-producing organisms that meet requirements as soon as possible. Hydrogen production from biomass requires continuous improvement and a vigorous promotion of technology. It is a difficult process.

Hydrogen storage focused on the discovery of new aspects of materials or their preparation is not yet at large-scale industrial level. Considering different hydrogen storage mechanisms, and the material to be used, also needs further study.

Furthermore, each hydrogen storage material has its own advantages and disadvantages, and most storage material properties have the characteristics that relate to adductivity and properties of a single, more commonly known material.

It is therefore believed that efforts should be focused on the development of a composite hydrogen storage material, which integrates the storage advantages of multiple individual materials, along the lines of greater future efforts.

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The advantages of hydrogen and Israel’s warnings

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Hydrogen is the most common element in nature. It is estimated to make up 75% of the mass of the universe. Except for that contained in air, it is primarily stored in water in the form of a compound, and water is the most widely distributed substance on earth.

Hydrogen has the best thermal conductivity of all gases – i.e. ten times higher than most of them – and it is therefore an excellent heat transfer carrier in the energy industry.

Hydrogen has good combustion performance, rapid ignition, and has a wide fuel range when mixed with air. It has a high ignition point and rapid combustion rate.

Except for nuclear fuels, the calorific value of hydrogen is the highest among all fossil and chemical fuels, as well as biofuels, reaching 142.35 kJ/kg. The calorie per kilogram of hydrogen burned is about three times that of gasoline and 3.9 times that of alcohol, as well as 4.5 times that of coke.

Hydrogen has the lightest weight of all elements. It can appear as gas, liquid, or solid metal hydride, which can adapt to different storage and transport needs and to various application environments.

Burning hydrogen is cleaner than other fuels –  besides generating small amounts of water – and does not produce hydrogen azide as carbon monoxide, carbon dioxide (harmful to the environment), hydrocarbons, lead compounds and dust particles, etc. A small amount of hydrogen nitride will not pollute the environment after proper treatment, and the water produced by combustion can continue to produce hydrogen and be reused repeatedly.

Extensive use practices show that hydrogen has a record of safe use. There were 145 hydrogen-related accidents in the United States between 1967 and 1977, all of which occurred in petroleum refining, the chlor-alkali industry, or nuclear power plants, and did not really involve energy applications.

Experience in the use of hydrogen shows that common hydrogen accidents can be summarized as follows: undetected leaks; safety valve failure; emptying system failure; broken pipes, tubes or containers; property damage; poor replacement; air or oxygen and other impurities left in the system; too high hydrogen discharge rate; possible damage of pipe and tube joints or bellows; accidents or tipping possibly occurring during the hydrogen transmission process.

These accidents require two additional conditions to cause a fire: one is the source of the fire and the other is the fact that the mixture of hydrogen and air or oxygen must be within the limits of the possibility of fires or violent earthquakes in the local area.

Under these two conditions, an accident cannot be caused if proper safety measures are established. In fact, with rigorous management and careful implementation of operating procedures, most accidents do not theoretically occur.

The development of hydrogen energy is triggering a profound energy revolution and could become the main source of energy in the 21st century.

The United States, Europe, Japan, and other developed countries have formulated long-term hydrogen energy development strategies from the perspective of national sustainable development and security strategies.

Israel, however, makes warning and calls for caution.

While the use of hydrogen allows for the widespread penetration of renewable energy, particularly solar and wind energy – which, due to storage difficulties, are less available than demand – Israeli experts say that, despite its many advantages, there are also disadvantages and barriers to integrating green hydrogen into industry, including high production costs and high upfront investment in infrastructure.

According to the Samuel Neaman Institute’s Energy Forum report (April 11, 2021; authors Professors Gershon Grossman and Naama Shapira), Israel is 7-10 years behind the world in producing energy from clean hydrogen.

Prof. Gideon Friedman, actingchief scientist and Director of Research and Development at the Ministry of Energy, explains why: “Israel has a small industry that is responsible for only 10% of greenhouse gas emissions – unlike the world where they are usually 20% – and therefore the problems of emissions in industry are a little less acute in the country.”

At a forum held prior to the report’s presentation, senior officials and energy experts highlighted the problematic nature of integrating clean hydrogen into industry in Israel.

Dr. Yossi Shavit, Head of the cyber unit in industry at the Ministry of Environmental Protection, outlined the risks inherent in hydrogen production, maintenance and transportation, including the fact that it is a colourless and odourless gas that makes it difficult to detect a leak. According to Dr. Shavit, hydrogen is a hazardous substance that has even been defined as such in a new regulation on cyber issues published in 2020.

Dr. Shlomo Wald, former chief scientist at the Ministry of Infrastructure, argued that in the future hydrogen would be used mainly for transportation, along with electricity.

Prof. Lior Elbaz of Bar-Ilan University said that one of the most important things is the lack of laws: “There is no specific regulation for hydrogen in Israel, but it is considered a dangerous substance. In order for hydrogen to be used for storage and transportation, there needs to be a serious set of laws that constitute a bottleneck in our learning curve.” “Israel has something to offer in innovation in the field, but government support will still be needed in this regard – as done in all countries – and approximately a trillion dollars in the field of hydrogen is expected to be invested in the next decade.”

Although the discussion was mainly about Israel’s delay in integrating clean hydrogen into the industry, it has emerged that Sonol (Israel’s fuel supplier ranking third in the country’s gas station chain) is leading a project, together with the Ministry of Transport, to establish Israel’s first hydrogen refuelling station. “We believe there will be hydrogen transportation in Israel for trucks and buses,” said Dr. Amichai Baram, Vice President of operations at Sonol. “Hydrogen-powered vehicles for the country – albeit not really cheap in the initial phase – and regulations promoted in the field, both for gas stations and vehicles.”

Renewables account for only 6% of Israel’s energy sources and, according to the latest plans published by the Ministry of Energy and adopted by the government, the target for 2030 is 30%.

This is an ambitious goal compared to reality, and also far from the goal of the rest of the countries in the world that aim at energy reset by 2050.

The authors of the aforementioned report emphasize that fully using the clean hydrogen potential is key to achieving a higher growth target for Israel.

According to recommendations, the State should critically examine the issue in accordance with Israel’s unique conditions and formulate a strategy for the optimal integration of hydrogen into the energy economy.

Furthermore, it must support implementation, both through appropriate regulations and through the promotion of cooperation with other countries and global companies, as well as through investment in infrastructure, and in research and development, industry and in collaboration with the academic world.

There are countries in Europe or the Middle East that have already started green energy production projects, and finally it was recommended to work to develop Israeli innovations in the field, in collaboration with the Innovation Authority and the Ministry of Energy.

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