Gholipour-Ranjbar Habib, Samayoa-Oviedo Hugo Y, Laskin Julia
Department of Chemistry, Purdue University, West Lafayette, Indiana 47906, United States.
ACS Nano. 2023 Sep 12;17(17):17427-17435. doi: 10.1021/acsnano.3c05545. Epub 2023 Aug 28.
The complete ligation of nanoclusters significantly reduces their chemical reactivity, catalytic activity, and charge transfer properties. Therefore, in applications, nanoclusters are activated through partial ligand removal to take advantage of their full potential. However, the precise control of ligand removal in the condensed phase is challenging. In this study, we examine the reactivity of well-defined activated nanoclusters on surfaces prepared through controlled ligand removal in the gas phase. To accomplish this, we utilized a specially designed ion soft-landing instrument equipped with a collision cell to prepare mass-selected fragment ions, which were then deposited onto self-assembled monolayer (SAM) surfaces. Specifically, we generated fragment ions by selectively removing one or two ligands from a series of atomically precise ligated metal sulfide clusters, CoMS(L) (M = Co, Mn, Fe, or Ni, L = PEt). Removal of one ligand from CoMS(L) (M = Co, Mn, Ni) generates CoMS(L) species, which undergo selective dimerization on SAMs. Meanwhile, CoFeS(L) is unreactive and remains intact when it is deposited onto a SAM surface. In contrast, fragments formed by the removal of two ligands, CoMS(L), undergo several nonselective reactions and generate larger fused clusters. We found that the reactivity of the CoMS(L) fragment ions is correlated with the gas phase stability of the corresponding precursor ion toward ligand loss. Specifically, the relatively unstable precursor ion, CoFeS(L), generates the least reactive fragment. Meanwhile, the more stable precursor ions generate more reactive CoMS(L) fragments that dimerize on surfaces. This observation was also confirmed by co-deposition of fragment ions with two different ligands, CoMS(L) and CoMS(L) (L = PEt and L = PEtPh), where fragments generated from more stable precursor ions tend to dimerize and generate dimers with mixed ligands. This study unveils the previously unrecognized potential of fragment ions in generating compounds that are difficult to synthesize using conventional methods. Additionally, it provides a mechanistic understanding of the observed reactivity. Mass-selected deposition of well-defined fragment ions emerges as a powerful approach for designing materials by precisely activating and depositing undercoordinated ligated nanoclusters onto surfaces.
纳米团簇的完全配位显著降低了它们的化学反应性、催化活性和电荷转移性质。因此,在应用中,纳米团簇通过部分配体去除来被激活,以充分发挥其潜力。然而,在凝聚相中精确控制配体去除具有挑战性。在本研究中,我们研究了通过在气相中控制配体去除制备的表面上明确的活化纳米团簇的反应性。为此,我们使用了一种专门设计的配备碰撞池的离子软着陆仪器来制备质量选择的碎片离子,然后将其沉积在自组装单分子层(SAM)表面上。具体而言,我们通过从一系列原子精确配位的金属硫化物团簇CoMS(L)(M = Co、Mn、Fe或Ni,L = PEt)中选择性去除一个或两个配体来产生碎片离子。从CoMS(L)(M = Co、Mn、Ni)中去除一个配体产生CoMS(L)物种,其在SAM上发生选择性二聚化。同时,CoFeS(L)没有反应活性,当它沉积到SAM表面时保持完整。相反,通过去除两个配体形成的碎片CoMS(L)会发生几种非选择性反应并生成更大的融合团簇。我们发现CoMS(L)碎片离子的反应性与相应前体离子对配体损失的气相稳定性相关。具体来说,相对不稳定的前体离子CoFeS(L)产生的反应性最低的碎片。同时,更稳定的前体离子产生更具反应性的CoMS(L)碎片,其在表面上二聚化。通过将碎片离子与两种不同的配体CoMS(L)和CoMS(L)(L = PEt和L = PEtPh)共沉积也证实了这一观察结果,其中由更稳定的前体离子产生的碎片倾向于二聚化并生成具有混合配体的二聚体。本研究揭示了碎片离子在生成使用传统方法难以合成的化合物方面以前未被认识到的潜力。此外,它提供了对观察到的反应性的机理理解。通过精确激活并将配位不足的配位纳米团簇沉积到表面上,质量选择沉积明确的碎片离子成为一种强大的材料设计方法。
