Haber first conducted a series of experimts to explore the optimal physicochemical conditions for ammonia synthesis.


    In the experimts, some of the data he obtained were differt from Nestor''s; he did not blindly follow authority but relied on experimts to test, and finally confirmed that Nestor''s calctions were incorrect.


    With the assistance of Lorzo, a British studt, Haber sessfully designed a set of equipmt suitable for high-pressure experimts and a process for synthesizing ammonia, which involves: blowing steam over hot coke to obtain a nearly equal volume mixture of carbon monoxide and hydrog gas.


    The carbon monoxide in the mixture further reacts with steam under the action of a catalyst, producing carbon dioxide and hydrog gas. Th, the mixed gas is dissolved in water under a certain pressure, and carbon dioxide is absorbed to produce rtively pure hydrog gas.


    Simrly, steam is mixed with an appropriate amount of air and passed through red-hot coke; oxyg in the air reacts with carbon to produce carbon monoxide and carbon dioxide and is absorbed and removed, thus obtaining the required nitrog gas.


    The mixture of nitrog gas and hydrog gas is synthesized into ammonia under high temperature and pressure conditions and the action of a catalyst.


    But what are the optimal high temperature and pressure conditions? And which catalyst is the best? This still requires a lot of effort to explore.


    With perseverance and through continuous experimts and calctions, Haber finally achieved inspiring results in 909.


    This means that at 600℃ high temperature, 00 atmospheric pressure, and osmium as a catalyst, a yield of about 8% ammonia can be obtained. An 8% conversion rate is not high, which will certainly affect the economic befits of production.


    Haber knew that the synthesis of ammonia could not reach as high a conversion rate as sulfuric acid production, where the oxidation reaction of sulfur dioxide has almost a 0% conversion rate. What to do?


    Haber believed that if the reaction gas could be processed in a closed loop under high pressure and the ammonia produced could be continuously separated from the loop, the process would be feasible. He sessfully designed the closed-loop process for the feed gas. This is the Haber process for synthesizing ammonia.


    After the birth of the ammonia synthesis technology, Haber''s name became famous throughout the European chemicalmunity.


    After sessfully obtaining the patt for the Haber process of ammonia synthesis, Haber also received the news that he had won the Victoria Chemistry Award that year.


    In order to bring his process out of theboratory and formally start industrial production, Haber made a decisive decision to ept Arthur''s invitation and take up a position at the Royal Austrsian Physical and Chemical Research Association.


    Of course, what really attracted Haber, in addition to the various conditions of the Royal Austrsian Physical and Chemical Research Association, was Arthur''s additional promise that as long as Haber was willing to give his process to Austrsia, Austrsia would do its best to quickly industrialize Haber''s process, build an ammonia synthesis nt within five years, and officially start production.


    At that time, the befits would be shared with Haber, and he was invited to serve as the Executive Vice Presidt of the Royal Austrsian Physical and Chemical Research Association.


    Arthur''s confidce in being able to build a full-scale ammonia synthesis nt stemmed from the fact that, in the original history, Haber''s ammonia synthesis concept was officially realized in 93, and a 30-ton-per-day ammonia synthesis nt was built and put into operation at that time.


    It would take only about three years to build the nt, and historically, Haber had only giv the technology to Germany''srgest chemicalpany.


    Arthur didn''t believe that, with the full support of the nation, he couldg far behind a chemicalpany.


    The day after Haber''s arrival, Arthur announced Haber''s appointmt as deputy chairman of the Royal Austrsian Physical and Chemical Research Association and, in the presce of Haber and Butler Kt, announced that the Royal Financial Group would invest one million Australian dors in the construction of an ammonia synthesis nt using the Haber process.


    Haber contributed his ammonia synthesis technology, holding forty perct of the shares, while Arthur''s royal financial group invested  million Australian dors, holding sixty perct of the shares.


    The ammonia synthesis nt would be located in the Leonora Industrial Base, and the construction of the nt itself would not be difficult; however, the specific equipmt and methods for industrial production of ammonia synthesis still needed further research by Haber and other members of the Royal Austrsian Physical and Chemical Research Association.


    Arthur made a promise in this regard: as long as the Royal Austrsian Physical and Chemical Research Association could solve the ammonia production problem, the royal family would give the Association one million Australian dors for research funding and an additional twty thousand Australian dors for each member.


    One million Australian dors in research funding, divided among the 0-plus experts of the Royal Austrsian Physical and Chemical Research Association, would amount to ts of thousands of Australian dors per person.


    And as long as the group could solve the ammonia production technology issue, each member would receive an additional twty thousand Australian dors in rewards, which is equivalt to four years of their sry, and no one would refuse.


    It is important to know that the sries of members of the Royal Austrsian Physical and Chemistry Research Association are definitely not low and are gerally at a medium-to-high level in Europe.


    Moreover, Arthur is gerous. As long as there are significant research results, there will be rewards. Therefore, the actual ie of these members is ev higher than that of most experts in Europe. Also, they have free ess toboratories and an annual fixed amount of research funding. This is why experts are willing to change their nationality toe to Austrsia.


    After trusting the challge of industrializing synthetic ammonia to the Royal Austrsian Physical and Chemistry Research Association and letting Haber pay atttion to the construction of the synthetic ammonia factories, Arthur finally set his mind at ease.


    In fact, besides synthetic ammonia, Austrsia currtly also attaches great importance to the chemical industry.


    Several chemical factories that have newly settled in the Leonora Industrial Base have mainly joyed the strong support of Austrsia for the chemical industry.


    In addition to the extra tax concessions, the royal financial group and governmt provided double loans to these chemical industries to sure that they have sufficit funds for developmt.


    At prest, the tax paid by geral industries is about elev perct, while that of the chemical industry is only eight perct.


    And these chemical factories can asionally get free help from members of the Royal Austrsian Physical and Chemistry Research Association. Of course, if they have sufficit funds, they can directly hire these members as consultants.


    Besides these, the Austrsian governmt has also provided greater support for the chemical gineering majors in various universities.


    Not only has the number of studts admitted to the chemical gineering majors increased, but there has also be more reduction in tuition and misceneous fees for studts rolling in chemical gineering majors. There are also more schrships and befits to cultivate more talt for the chemical industry.


    Currtly, the strongest in the chemical industry should be Austrsia National University and Oand University.


    The chemical gineering major of Austrsia National University currtly rolls up to 400 studts per year, while that of Oand University rolls 00 studts per year.


    In addition to the chemical gineering majors in other universities, regardless of their size, the chemical industry of Austrsia can train at least 700 university studts per year, which can make up for the shortage of talt in the chemical industry.


    Of course, as for top chemical talts, Austrsia currtly has no way to cultivate them by itself and can only rely on hiring them from Europe and the United States.


    Most of the time, however, they hire from Europe. After all, education in Europe is already very popr, and various talts are also very abundant, making it somewhat easier to win them over.n/?/vel/b//in dot c//om


    In countries like the United States, although the economy is very developed, education is not as widespread as in Europe.


    Ev the reason for the rise of the United States inter gerations is due to the attraction of arge number of European talts during World War I and World War II.


    To draw talts from the United States now, first, these talts are highly valued by the American governmt, and second, their talt may not necessarily beparable to Europeans.


    With the currt good rtionship betwe Austrsia and Germany, it is rtively easy for Austrsia to invite some chemical experts from Germany.


    So far, Austrsia has hired more than forty well-known experts from Europe, most of whom are outstanding talts who have basically joined the Royal Austrsian Physical and Chemistry Research Association.


    The remaining talts with a little fame have also tered the chemical gineering majors of various universities under Arthur''s arrangemt, cultivating more middle-level talts in the chemical industry in Austrsia.


    Although the chemical industry has both advantages and disadvantages for human society, the befits far outweigh the disadvantages and are very important for a country''s developmt.


    Under various measures tak by Austrsia to develop the chemical industry, various chemical factories have sprung up like bamboo shoots after rain, and talts in the chemical industry have gradually be umted.