# | Title | Journal | Year | Citations |
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1 | Exploiting single-ion anisotropy in the design of f-element single-molecule magnets | Chemical Science | 2011 | 1,757 |
2 | Reversible photo-induced trap formation in mixed-halide hybrid perovskites for photovoltaics | Chemical Science | 2015 | 1,682 |
3 | Dialkylbiaryl phosphines in Pd-catalyzed amination: a user's guide | Chemical Science | 2011 | 1,349 |
4 | Rethinking the term “pi-stacking” | Chemical Science | 2012 | 1,304 |
5 | Amorphous molybdenum sulfide films as catalysts for electrochemical hydrogen production in water | Chemical Science | 2011 | 1,265 |
6 | MoleculeNet: a benchmark for molecular machine learning | Chemical Science | 2018 | 1,261 |
7 | Vitrimers: permanent organic networks with glass-like fluidity | Chemical Science | 2016 | 1,115 |
8 | ANI-1: an extensible neural network potential with DFT accuracy at force field computational cost | Chemical Science | 2017 | 1,111 |
9 | Evaluating metal–organic frameworks for natural gas storage | Chemical Science | 2014 | 1,038 |
10 | Synergistic catalysis: A powerful synthetic strategy for new reaction development | Chemical Science | 2012 | 1,033 |
11 | Fe, Co, and Ni ions promote the catalytic activity of amorphous molybdenum sulfide films for hydrogen evolution | Chemical Science | 2012 | 861 |
12 | MN15: A Kohn–Sham global-hybrid exchange–correlation density functional with broad accuracy for multi-reference and single-reference systems and noncovalent interactions | Chemical Science | 2016 | 858 |
13 | Improving MOF stability: approaches and applications | Chemical Science | 2019 | 855 |
14 | A hydrazone-based covalent organic framework for photocatalytic hydrogen production | Chemical Science | 2014 | 847 |
15 | Overall water splitting by Pt/g-C3N4photocatalysts without using sacrificial agents | Chemical Science | 2016 | 835 |
16 | Pot economy and one-pot synthesis | Chemical Science | 2016 | 807 |
17 | Characterizing chain processes in visible light photoredox catalysis | Chemical Science | 2015 | 791 |
18 | Solid-state principles applied to organic–inorganic perovskites: new tricks for an old dog | Chemical Science | 2014 | 788 |
19 | A new mechanism for the selectivity to C1 and C2 species in the electrochemical reduction of carbon dioxide on copper electrodes | Chemical Science | 2011 | 764 |
20 | Passivating surface states on water splitting hematite photoanodes with alumina overlayers | Chemical Science | 2011 | 763 |
21 | On the application of the tolerance factor to inorganic and hybrid halide perovskites: a revised system | Chemical Science | 2016 | 757 |
22 | Metal–organic framework-based CoP/reduced graphene oxide: high-performance bifunctional electrocatalyst for overall water splitting | Chemical Science | 2016 | 745 |
23 | Graphene-based electronic sensors | Chemical Science | 2012 | 663 |
24 | Earth-abundant hydrogen evolution electrocatalysts | Chemical Science | 2014 | 636 |
25 | Continuous flow multi-step organic synthesis | Chemical Science | 2010 | 611 |
26 | Mechanochemistry as an emerging tool for molecular synthesis: what can it offer? | Chemical Science | 2018 | 610 |
27 | An extended Tolerance Factor approach for organic–inorganic perovskites | Chemical Science | 2015 | 587 |
28 | Stable singlet carbenes as mimics for transition metal centers | Chemical Science | 2011 | 584 |
29 | Theory of multiple proton–electron transfer reactions and its implications for electrocatalysis | Chemical Science | 2013 | 581 |
30 | Intriguing aspects of lanthanide luminescence | Chemical Science | 2013 | 579 |
31 | Design and preparation of new palladium precatalysts for C–C and C–N cross-coupling reactions | Chemical Science | 2013 | 572 |
32 | Single-atom dispersed Co–N–C catalyst: structure identification and performance for hydrogenative coupling of nitroarenes | Chemical Science | 2016 | 571 |
33 | Ruthenium-catalyzed direct oxidative alkenylation of arenes through twofold C–H bond functionalization | Chemical Science | 2013 | 568 |
34 | Diamine ligands in copper-catalyzed reactions | Chemical Science | 2010 | 567 |
35 | The hydrogen evolution reaction: from material to interfacial descriptors | Chemical Science | 2019 | 560 |
36 | Indole synthesis – something old, something new | Chemical Science | 2013 | 558 |
37 | Recent developments in and perspectives on three-coordinate boron materials: a bright future | Chemical Science | 2017 | 555 |
38 | NKP-1339, the first ruthenium-based anticancer drug on the edge to clinical application | Chemical Science | 2014 | 552 |
39 | Chemical tuning of CO2 sorption in robust nanoporous organic polymers | Chemical Science | 2011 | 532 |
40 | Heteronanowires of MoC–Mo2C as efficient electrocatalysts for hydrogen evolution reaction | Chemical Science | 2016 | 532 |
41 | Slow magnetization dynamics in a series of two-coordinate iron(ii) complexes | Chemical Science | 2013 | 518 |
42 | Nickel-catalyzed cross coupling of non-activated alkyl halides: a mechanistic perspective | Chemical Science | 2011 | 507 |
43 | Highly porous and stable metal–organic frameworks for uranium extraction | Chemical Science | 2013 | 506 |
44 | Chemical sensing in two dimensional porous covalent organic nanosheets | Chemical Science | 2015 | 504 |
45 | The rise of 3-d single-ion magnets in molecular magnetism: towards materials from molecules? | Chemical Science | 2016 | 502 |
46 | Water resistant CsPbX3 nanocrystals coated with polyhedral oligomeric silsesquioxane and their use as solid state luminophores in all-perovskite white light-emitting devices | Chemical Science | 2016 | 499 |
47 | High thermal and chemical stability in pyrazolate-bridged metal–organic frameworks with exposed metal sites | Chemical Science | 2011 | 496 |
48 | The importance of nickel oxyhydroxide deprotonation on its activity towards electrochemical water oxidation | Chemical Science | 2016 | 494 |
49 | Enhanced carbon dioxide capture upon incorporation of N,N′-dimethylethylenediamine in the metal–organic framework CuBTTri | Chemical Science | 2011 | 491 |
50 | Combination of Ru(ii) complexes and light: new frontiers in cancer therapy | Chemical Science | 2015 | 487 |