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Organic chemists aim to separate alkenes such as ethylene and propene from alkynes before converting them into polymers. The technique has several drawbacks including hydrogenation of alkynes to produce unwanted alkanes, which has spurred an interest in other methods of separation. , also known as , are crystalline solids made of silicon, aluminium and oxygen to retain cations, water and/or small molecules. However, most molecules cannot be efficiently separated with zeolites due to their size and volatilities. Researchers aim to efficiently remove alkyne impurities to produce polymer-grade lower olefins (unsaturated hydrocarbons), which remains challenging for many industries.

In a new report, Yuchao Chai and an international research team in advanced materials, chemical physics, neutron sciences and the Diamond Light Source in the U.K., U.S., and China developed a new strategy to control the interior pore of (FAU) zeolites. They achieved this by confining isolated open nickel(II) sites in their six-membered rings. Under ambient conditions, the Nickel (Ni) FAU sites (known as Ni@FAU) showed remarkable adsorption of alkynes and the efficient separation of acetylene/ethylene, propyne/propylene, and butyne/1-3, butadiene mixtures with unprecedented separation selectivity. Using in situ neutron diffraction and inelastic neutron scattering techniques, the team showed how confirmed nickel(II) sites allowed chemo-selective and reversible binding to acetylene by forming metastable [Ni(II)(C₂H₂)₃] complexes. The ability to control the chemistry of pore interiors of easily sealable zeolites unlocked their potential to achieve challenging industrial separation. The work is now published in Science.

Chemical industries produce more than 350 million metric tons of such as ethylene, propylene, and 1,3-butadiene by steam cracking hydrocarbons. The process of separating large quantities of chemical mixtures into purer forms contributes to enormous consumption. In order to obtain polymer-grade olefins, scientists must also reduce the by-products of alkynes in the stream, as they irreversibly poison the . State-of-the-art techniques that aim to purify olefins are based on partial hydrogenation of alkynes, but such methods are . Emerging methods use porous sorbents such as (MOFs) for preferential adsorption of alkynes compared to olefins, but remain to be commercialized due to their inherently costs. Zeolites are structurally robust and offer low-cost production with wide industrial separation applications due to their properties. However, they are ineffective for alkyne/olefin separation due to similarities in molecular size and volatility. The facile production and high stability of Ni(II) sites isolated into faujasite (FAU) zeolites to produce 'Ni@FAU' therefore reinforced their potential in industrial purification of lower olefins.

The team synthesized M@FAU zeolites; where M stood for Nickel—Ni(II), Copper—Cu (II) and Zn (II), using hydrothermal reactions of mixed gels and subsequent processing. They used a ligand abbreviated as to coordinate Ni(II) ions for their inclusion in the zeolite pore structures at difficult locations. Using synchrotron X-ray powder diffraction data, the team confirmed M@FAU zeolite crystals to be in a specific cubic space group. They confirmed the homogenous distribution of transition-metal cations throughout the M@FAU crystals using electron microscopy and confirmed the divalent oxidation state of confined metal ions using .

To confirm the primary location of the confined Ni(II) (nickel) sites in FAU zeolites, the scientists used (DFT) calculations and in situ (NPD) studies. During competitive adsorption of equimolar mixtures of (C₂H₂) and (C₂H₄) in the setup, Chai et al. observed the selective uptake of acetylene. They identified the adsorption species in C₂H₂^- and C₂H₄^- molecules loaded in Ni@FAU using and identified fragments corresponding to Ni(C₂H₂)₃ as a key species in C₂H₂-adsoprbed Ni@FAU. However, they did not observe Ni(C₂H₄)_n (where n =1 to 4) species to form C₂H₄-adsorbed Ni@FAU. The results showed the highly selective adsorption capacity of acetylene (C₂H₂) in Ni@FAU alongside its ability to remove trace acetylene from the ethylene stream.

Chai et al. conducted further experiments to separate C₂H₂/C₂H₄ mixtures using M@FAU (where M = Ni, Cu and Zn as before), under dynamic conditions. All experiments sufficiently adsorbed acetylene and produced ultrapure ethylene streams at the outlet. The dynamic uptake compared favorably with . The scientists noted further separation capabilities with Ni@FAU after increasing the column temperature or adding carbon dioxide or water into the gas stream. The results signalled the industrial potential of Ni@FAU for the adsorptive removal of alkynes from olefin streams. After 10 cycles of acetylene/ethylene separations with Ni@FAU, the team noted full sorbent regeneration between each cycle without declined retention for practical recyclability. In contrast, they noted poor reversibility with Cu@FAU. To evaluate the role of nickel in Ni@FAU, the research team introduced the metal ions into FAU zeolites via different methods such as ion-exchange and wet impregnation and showed minimal acetylene/ethylene separation. The scientists therefore credited the excellent performance of Ni@FAU to their binding methods and environments that efficiently confined nickel sites within the pores.

The team also identified the locations of confined nickel sites and adsorbed gas molecules (represented as C2D2, C2D4, C3D4 and C3D6) within Ni@FAU using in situ neutron powder diffraction studies. Based on of desolvated Ni@FAU, they confirmed the structural integrity and the absence of residual nuclear density within the supercage structure. After gas loading in the setup, they successfully interpreted the binding domains of gases via Fourier difference map analysis and (a technique to characterize crystalline materials).

All results were consistent with the characteristics of selective, yet reversible sorption noted in the study. The distinct nature of the sorbent-gas interactions validated the high selectivity of Ni@FAU toward alkyne adsorption. Chai et al. also visualized the binding dynamics of adsorbed C₂H₂ and C₂H₄ molecules on Ni@FAU with (INS) studies. Adsorption on to nickel sites resulted in the isolation and restriction of the gas molecules in an anisotropic environment, which resulted in distinct inelastic neutron scattering features. Allowing the team to verify the interactions between Ni@FAU and C₂H₂ (acetylene) to be stronger than that of Ni@FAU and C₂H₄ (ethylene).

In this way, Yuchao Chai and colleagues demonstrated the increasing promise of solid-sorbent based techniques such as Ni@FAU (Nickel faujasite zeolites) to improve the operational efficiency of existing separation processes. At present, the techniques used for petrochemical industries and for the separation of alkyne impurities from olefins can only be realized by exploring differences in their , , and . Scientists had previously considered zeolites with well-defined channels as viable candidates for gas separation for decades, primarily due to their molecular sieving property. Based on such studies, the team confined atomically dispersed nickel sites in the FAU zeolite channels in this work to form Ni@FAU and discriminate between alkyne and olefin binding. The work facilitated the production of polymer-grade olefins under practical conditions. The Ni@FAU sorbent offers an innovative and practical solution to the challenging process of separating alkyne/olefin compounds.

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