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Green Ammonia

July 22, 2024

As I wrote in an earlier article (Ammonia Synthesis, March 6, 2017), ammonia is an important industrial chemical. It's estimated that the worldwide production of ammonia in 2023 exceeded 150 million metric tons. About 70% of ammonia is used to make nitrate fertilizers,[1] and the rest is used for such things as neutralization of acids and stack emissions, and the manufacture of nitric acid for chemical synthesis. Unfortunately, the production of ammonia is energy and emissions intensive.

Ammonia production has a direct emissions rate of about 2.4 metric tons per metric ton of production, four times that of cement, which leads to direct emissions of 450 metric tons of carbon dioxide annually.[1] There are also indirect carbon dioxide emission of about 170 metric tons of carbon dioxide from electricity generation and the chemical reaction when fertiliser is applied to soil.[1] The production of ammonia accounts for about 2% of energy consumption and 1.3% of carbon dioxide emissions from energy systems.[1]

Compounds of ammonia were known to the ancients, and ammonia is named after the Greek god, Ammon, the Greek version of the Egyptian Sun god, Amun-Ra. Deposits of the ammonia salt, ammonium chloride (sal ammoniac), were found near the temple of Ammon in Libya. Pliny the Elder mentions ammonium chloride crystals of that region in his Naturalis Historia (Natural History) (see figure). It wasn't until 1774 that gaseous ammonia was first isolated by Joseph Priestley (1733-1804). Claude Berthollet determined the composition of ammonia, NH3, in 1785. Ammonia was produced by simple reaction of nitrates until the 20th century.

Pliny's Natural History, Book XXXI, Chapter 39, line 79, mentioning ammonium chloride

Ammonium chloride (sal ammoniac), as mentioned in Pliny's Natural History, Book XXXI, Chapter 39, line 79.[2] My translation of this reads, "For example, the region of Cyrenaica is notable, also, for hammoniacum, which is found beneath the sands. It is similar in color to the alum which is called schiston, it consists of long masses, not transparent, has a foul taste, but is useful as medicine." (Simulated manuscript created using GIMP.)


During World War I, Germany's supply from Chile of potassium nitrate (saltpeter), an ammonia precursor and an essential compound for synthesis of explosives, was disrupted. That was the impetus for the industrial scale development of the 1909 Bosch-Haber process for ammonia synthesis from nitrogen gas. Carl Bosch (1874-1940) of BASF industrialized the synthesis of ammonia from its elements, N2 + 3H2 -> 2NH3, as discovered by German chemist, Fritz Haber (1868-1934).

While the reaction of N2 and 3H2 to form 2NH3 is exothermic (-45.9 kJ/mol, -10.97 kcal/mole), and it has a favorable change in the Gibbs free energy (-16.4 kJ/mol, -3.92 kcal/mol), it does not occur spontaneously. The co-existence of free hydrogen and free nitrogen in the atmosphere affirms this. Haber discovered in 1905 that a catalyst will produced small quantities of ammonia from the elements at 1000 °C. The catalyst for the Bosch-Haber process was potassium-promoted iron, but many other catalysts will work, including osmium and uranium. The synthesis is typically conducted at about 450 °C under 15-25 MPa (2,200-3,600 psi) pressure. A ruthenium catalyst allows for reaction at a lower pressure. Presently, about 180 million metric tons of ammonia are synthesized annually by the Bosch-Haber process, and similar processes.[6] It's estimated that a third of annual global food production uses ammonia from the Bosch-Haber process.

Ammonia synthesis energy diagram

Why we need a catalyst for ammonia synthesis. Breaking nitrogen and hydrogen molecules into their constituent atoms takes a lot of energy, but all this energy is recovered in the end. (Wikimedia Commons image by Marsupilami. Click for larger image.)


Fritz Haber, who perfected the catalytic synthesis of ammonia from nitrogen gas and hydrogen gas, was a German chemist who received the Nobel Prize in Chemistry in 1918. American chemist, Linus Pauling (1901-1994) was awarded the 1954 Nobel Prize in Chemistry, but he also won the reserved 1962 Nobel Peace Prize for his activism against nuclear weapons testing. Haber's activities, however, were the antithesis of peace, since he helped in the development of chemical warfare during World War I in contravention of the Hague Convention of 1907. There's the eponymous Haber's rule for the dosage effect of poisonous gas. Before the nuclear age, poison gas was viewed as an existential threat to human civilization. This can be surmised from the H. G. Wells' film, Things to Come.[3] Haber was widely criticised by fellow scientists for such activities.

Fritz Haber in a BASF-Laboratory, circa 1914

Fritz Haber in a BASF laboratory, circa 1914.

His 1914 bench apparatus is about the same as what I used in my freshman chemistry laboratory about fifty years later. Fortunately, there have been major improvements to laboratory instrumentation for chemistry since that time.

(Portion of a Wikimedia Commons image. Click for a larger image.)


Since the Bosch-Haber process is a process in widespread use that contributes to global warming, it's a prime candidate for improvement. However, no major improvements in ammonia synthesis have appeared in the century after its discovery, despite awards of the Nobel Prize in 1931 and 2007 subsequent to Haber's 1918 prize. There was the 1931 chemistry prize to Carl Bosch (1874–1940) and Friedrich Bergius (1884–1949) for their "contributions to the Invention and development of chemical high pressure methods;" and, the 2007 chemistry prize to Gerhard Ertl (b. 1936) "for his studies of chemical processes on solid surfaces."

Chemists have had their chance, and it now appears that physicists have decided to enter this high-stakes game. A recent study in Science by physicists at the Technical University of Denmark, led by theoretical physicist, Jens Nørskov and experimental physicist, Ib Chorkendorff, has looked at how lanthanum atoms on a cobalt catalyst quench the cobalt spin and reduce the activation energy required to split molecular nitrogen N2.[4-7] This mechanism could make cobalt a particularly good catalyst for ammonia synthesis.[6]

The Bosch-Haber process is energy intensive, often using temperatures up to 650 ° C and 200 atmospheres pressure to split the triply bonded nitrogen atoms before reaction with hydrogen.[6] The iron catalyst for this process is inexpensive, but there's been decades of research looking for a catalyst for ammonia synthesis in milder conditions.[6] Nickel and cobalt are alternative catalyst materials, but these are generally not reactive with nitrogen without particular promoters.[6]

The physicists at the Technical University of Denmark have found that suppressing magnetism in cobalt activates the metal as an ammonia catalyst.[4] Following up an clues from computational catalysis, the researchers demonstrated that lanthanum atoms quench the magnetic moment of adjacent cobalt atoms to lower the activation energy and enhance nitrogen cleavage well below the temperature of the Bosch-Haber process.[4-6]

Lanthanum promotor on a cobalt surface for catalytic splitting of nitrogen.

Lanthanum promoter on a cobalt surface for catalytic splitting of nitrogen. TS* is the transition state of molecular nitrogen, and the dissociated excited state nitrogen atoms (N*) diffuse along the surface to bond with three individual hydrogen atoms (not shown). (Created using Inkscape. Click for larger image.)


They did experiments on cobalt single crystals, and also mass-selected cobalt nanoparticles at ambient pressures and 350°C and found that the lanthanum-promoted cobalt catalyst is twice as effective in ammonia synthesis as the Bosch-Haber process.[4,6] Further experiments using cobalt thin films and the stepped surfaces of cobalt crystals showed that cobalt steps are the sites where lanthanum atoms are more effective at ammonia synthesis.[6] About half of the nitrogen molecules adsorbed on the lanthanum-cobalt catalyst were converted to ammonia each second at 350°C and 1 atmosphere.[4] However, the cost of both cobalt and lanthanum will prevent an immediate replacement for the Bosch-Haber process, but this concept may provide a path to to creation of other catalysts.[6]

References:

  1. Ammonia Technology Roadmap, International Energy Agency (IEA), October 2021.
  2. Pliny the Elder, "Naturalis Historia," Book 31, Chapter 39, on the University of Chicago Penelope web site by Bill Thayer.
  3. Things to Come (1936, William Cameron Menzies, Director), on the Internet Movie Database.
  4. Ke Zhang, Ang Cao, Lau Halkier Wandall, Jerome Vernieres, Jakob Kibsgaard, Jens K. Nørskov, and Ib Chorkendorff, "Spin-mediated promotion of Co catalysts for ammonia synthesis," Science, vol. 383, no. 6689 (March 21, 2024), pp. 1357-1363, DOI: 10.1126/science.adn0558.
  5. Günther Rupprechter, "A milder reaction to feed the world," Science, vol. 383, no. 6689 (March 21, 2024), p. 1295, DOI: 10.1126/science.ado4095.
  6. R. Mark Wilson, "Creating a good ammonia catalyst from an unreactive metal, Physics Today, May 10, 2024, DOI:https://doi.org/10.1063/pt.ubla.wnhk.

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