Is Carbon Heteroatom Doping the Key to Active and Stable Carbon Supported Cobalt Fischer–Tropsch Catalysts?

IF 11.3 1区化学 Q1 CHEMISTRY, PHYSICAL

ACS Catalysis Pub Date : 2025-04-09 DOI:10.1021/acscatal.4c0809210.1021/acscatal.4c08092

Felix Herold*, Dominic de Oliveira, Göran Baade, Jens Friedland, Robert Güttel, Michael Claeys and Magnus Rønning*,

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引用次数: 0

Abstract

Carbon supports are an interesting alternative to established oxidic catalyst supports for Co-based Fischer–Tropsch synthesis (FTS) catalysts as they allow high Co reducibility and do not suffer from the formation of Co/support compounds. To optimize Co-based carbon-supported FTS catalysts, significant research has focused on doping carbon supports with heteroatoms, aiming to enhance both catalytic activity and stability. While improvements in FTS performance have been reported for N-doped carbon supports, the exact effects of heteroatom doping are still poorly understood, largely due to difficulties in directly comparing Co FTS catalysts supported on doped versus nondoped carbon materials. In this study, we synthesized a series of highly comparable N-, S-, and P-doped carbon nanofiber (CNF) model supports, which were combined with size-controlled, colloidal Co nanoparticles to create well-defined model FTS catalysts. Comprehensive characterization of these catalysts using in situ X-ray absorption spectroscopy (XAS), in situ X-ray diffraction (XRD), and in situ magnetometry revealed that the presence of dopants significantly altered the structure and properties of the catalytically active Co⁰ phase, affecting Co coordination numbers, crystal phase composition, and magnetic behavior. Challenging optimistic literature reports, our findings demonstrate that all the studied heteroatoms negatively impact either FTS activity or catalyst stability. Co on N-doped CNFs experienced rapid deactivation due to increased sintering as well as Co phase transformations, which were not observed for Co on nondoped CNFs. Co on S-doped CNF suffered from instability of carbon-bound S species in a hydrogen atmosphere, contributing to low FTS performance by S-poisoning. Finally, Co on P-doped CNFs displayed strong metal–support interactions that improved sintering stability, but FTS activity was hampered by low Co reducibility and the loss of active Co⁰ due to a complex sequence of cobalt phosphide formation and its subsequent decomposition into phosphorus oxides and cobalt oxide species under FTS conditions.

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对于以 Co 为基质的费托合成 (FTS) 催化剂而言，碳载体是现有氧化催化剂载体的一种有趣替代品，因为碳载体具有较高的 Co 还原性，并且不会形成 Co/载体化合物。为了优化 Co 基碳支撑的 FTS 催化剂，大量研究集中于在碳支撑中掺杂杂原子，以提高催化活性和稳定性。虽然掺杂 N 的碳载体的 FTS 性能有所改善，但人们对掺杂杂原子的确切影响仍然知之甚少，这主要是由于很难直接比较掺杂与未掺杂碳材料上支持的 Co FTS 催化剂。在本研究中，我们合成了一系列具有高度可比性的掺杂 N、S 和 P 的碳纳米纤维 (CNF) 模型载体，并将其与尺寸可控的胶体 Co 纳米颗粒相结合，以创建定义明确的模型 FTS 催化剂。利用原位 X 射线吸收光谱 (XAS)、原位 X 射线衍射 (XRD) 和原位磁力测定法对这些催化剂进行综合表征后发现，掺杂剂的存在极大地改变了催化活性 Co0 相的结构和性质，影响了 Co 的配位数、晶相组成和磁性行为。我们的研究结果证明，所有研究的杂原子都会对 FTS 活性或催化剂稳定性产生负面影响，这对乐观的文献报道提出了质疑。掺杂 N 的 CNF 上的 Co 会因烧结加剧和 Co 相变而迅速失活，而未掺杂的 CNF 上的 Co 则不会出现这种情况。掺 S 的 CNF 上的 Co 在氢气环境中因碳结合的 S 物种不稳定而导致 S 中毒，从而降低了 FTS 性能。最后，掺杂 P 的 CNF 上的 Co 显示出较强的金属支撑相互作用，提高了烧结稳定性，但在 FTS 条件下，由于磷化钴的形成及其随后分解为磷氧化物和氧化钴物种的复杂过程导致 Co 还原性低和活性 Co0 损失，从而影响了 FTS 活性。

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来源期刊

ACS Catalysis CHEMISTRY, PHYSICAL-

CiteScore

20.80

自引率

6.20%

发文量

1253

审稿时长

1.5 months

期刊介绍： ACS Catalysis is an esteemed journal that publishes original research in the fields of heterogeneous catalysis, molecular catalysis, and biocatalysis. It offers broad coverage across diverse areas such as life sciences, organometallics and synthesis, photochemistry and electrochemistry, drug discovery and synthesis, materials science, environmental protection, polymer discovery and synthesis, and energy and fuels. The scope of the journal is to showcase innovative work in various aspects of catalysis. This includes new reactions and novel synthetic approaches utilizing known catalysts, the discovery or modification of new catalysts, elucidation of catalytic mechanisms through cutting-edge investigations, practical enhancements of existing processes, as well as conceptual advances in the field. Contributions to ACS Catalysis can encompass both experimental and theoretical research focused on catalytic molecules, macromolecules, and materials that exhibit catalytic turnover.