Tunable and Switchable Catalysis Enabled by Cation-Controlled Gating with Crown Ether Ligands
Conspectus Catalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, co...
Saved in:
| Published in | Accounts of chemical research Vol. 56; no. 8; pp. 971 - 981 |
|---|---|
| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
United States
American Chemical Society
18.04.2023
|
| Online Access | Get full text |
| ISSN | 0001-4842 1520-4898 1520-4898 |
| DOI | 10.1021/acs.accounts.3c00056 |
Cover
| Abstract | Conspectus Catalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, continually producing a desired product at a given rate. There is enormous opportunity in developing catalysts that are dynamic, capable of responding to a change in the environment to alter structure and function. Controlled catalysis, in which the activity or selectivity of a catalytic reaction can be adjusted through an external stimulus, offers opportunities for innovation in catalysis. Catalyst discovery could be simplified if a single thoughtfully designed complex could work synergistically with additives to optimize performance rather than trying a multitude of different metal/ligand combinations. Temporal control could be gained to facilitate the execution of multiple reactions in the same flask, for example, by activating one catalyst and deactivating another to avoid incompatibilities. Selectivity switching could enable copolymer synthesis with well-defined chemical and material properties. These applications might sound futuristic for synthetic catalysts, but in nature, such a degree of controlled catalysis is commonplace. For example, allosteric interactions and/or feedback loops modulate enzymatic activity to enable complex small-molecule synthesis and sequence-defined polymerization reactions in complex mixtures containing many catalytic sites. In many cases, regulation is achieved by “gating” substrate access to the active site. Fundamental advances in catalyst design are needed to better understand the factors that enable controlled catalysis in the arena of synthetic chemistry, particularly in achieving substrate gating outside of macromolecular environments. In this Account, the development of design principles for achieving cation-controlled catalysis is described. The guiding hypothesis was that gating substrate access to a catalyst site could be achieved by controlling the dynamics of a hemilabile ligand through secondary Lewis acid/base and/or cation–dipole interactions. To enforce such interactions, catalysts sitting at the interface of organometallic catalysis and supramolecular chemistry were designed. A macrocyclic crown ether was incorporated into a robust organometallic pincer ligand, and these “pincer-crown ether” ligands have been explored in catalysis. Complementary studies of controlled catalysis and detailed mechanistic analysis guided the development of iridium, nickel, and palladium pincer-crown ether catalysts capable of substrate gating. Toggling the gate between open and closed states leads to switchable catalysis, where cation addition/removal changes the turnover frequency or the product selectivity. Varying the degree of gating leads to tunable catalysis, where the activity can be tuned based on the identity and amount of salt added. Research has focused on reactions of alkenes, particularly isomerization reactions, which has in turn led to design principles for cation-controlled catalysts. |
|---|---|
| AbstractList | ConspectusCatalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, continually producing a desired product at a given rate. There is enormous opportunity in developing catalysts that are dynamic, capable of responding to a change in the environment to alter structure and function. Controlled catalysis, in which the activity or selectivity of a catalytic reaction can be adjusted through an external stimulus, offers opportunities for innovation in catalysis. Catalyst discovery could be simplified if a single thoughtfully designed complex could work synergistically with additives to optimize performance rather than trying a multitude of different metal/ligand combinations. Temporal control could be gained to facilitate the execution of multiple reactions in the same flask, for example, by activating one catalyst and deactivating another to avoid incompatibilities. Selectivity switching could enable copolymer synthesis with well-defined chemical and material properties. These applications might sound futuristic for synthetic catalysts, but in nature, such a degree of controlled catalysis is commonplace. For example, allosteric interactions and/or feedback loops modulate enzymatic activity to enable complex small-molecule synthesis and sequence-defined polymerization reactions in complex mixtures containing many catalytic sites. In many cases, regulation is achieved by "gating" substrate access to the active site. Fundamental advances in catalyst design are needed to better understand the factors that enable controlled catalysis in the arena of synthetic chemistry, particularly in achieving substrate gating outside of macromolecular environments. In this Account, the development of design principles for achieving cation-controlled catalysis is described. The guiding hypothesis was that gating substrate access to a catalyst site could be achieved by controlling the dynamics of a hemilabile ligand through secondary Lewis acid/base and/or cation-dipole interactions. To enforce such interactions, catalysts sitting at the interface of organometallic catalysis and supramolecular chemistry were designed. A macrocyclic crown ether was incorporated into a robust organometallic pincer ligand, and these "pincer-crown ether" ligands have been explored in catalysis. Complementary studies of controlled catalysis and detailed mechanistic analysis guided the development of iridium, nickel, and palladium pincer-crown ether catalysts capable of substrate gating. Toggling the gate between open and closed states leads to switchable catalysis, where cation addition/removal changes the turnover frequency or the product selectivity. Varying the degree of gating leads to tunable catalysis, where the activity can be tuned based on the identity and amount of salt added. Research has focused on reactions of alkenes, particularly isomerization reactions, which has in turn led to design principles for cation-controlled catalysts.ConspectusCatalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, continually producing a desired product at a given rate. There is enormous opportunity in developing catalysts that are dynamic, capable of responding to a change in the environment to alter structure and function. Controlled catalysis, in which the activity or selectivity of a catalytic reaction can be adjusted through an external stimulus, offers opportunities for innovation in catalysis. Catalyst discovery could be simplified if a single thoughtfully designed complex could work synergistically with additives to optimize performance rather than trying a multitude of different metal/ligand combinations. Temporal control could be gained to facilitate the execution of multiple reactions in the same flask, for example, by activating one catalyst and deactivating another to avoid incompatibilities. Selectivity switching could enable copolymer synthesis with well-defined chemical and material properties. These applications might sound futuristic for synthetic catalysts, but in nature, such a degree of controlled catalysis is commonplace. For example, allosteric interactions and/or feedback loops modulate enzymatic activity to enable complex small-molecule synthesis and sequence-defined polymerization reactions in complex mixtures containing many catalytic sites. In many cases, regulation is achieved by "gating" substrate access to the active site. Fundamental advances in catalyst design are needed to better understand the factors that enable controlled catalysis in the arena of synthetic chemistry, particularly in achieving substrate gating outside of macromolecular environments. In this Account, the development of design principles for achieving cation-controlled catalysis is described. The guiding hypothesis was that gating substrate access to a catalyst site could be achieved by controlling the dynamics of a hemilabile ligand through secondary Lewis acid/base and/or cation-dipole interactions. To enforce such interactions, catalysts sitting at the interface of organometallic catalysis and supramolecular chemistry were designed. A macrocyclic crown ether was incorporated into a robust organometallic pincer ligand, and these "pincer-crown ether" ligands have been explored in catalysis. Complementary studies of controlled catalysis and detailed mechanistic analysis guided the development of iridium, nickel, and palladium pincer-crown ether catalysts capable of substrate gating. Toggling the gate between open and closed states leads to switchable catalysis, where cation addition/removal changes the turnover frequency or the product selectivity. Varying the degree of gating leads to tunable catalysis, where the activity can be tuned based on the identity and amount of salt added. Research has focused on reactions of alkenes, particularly isomerization reactions, which has in turn led to design principles for cation-controlled catalysts. ConspectusCatalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, continually producing a desired product at a given rate. There is enormous opportunity in developing catalysts that are dynamic, capable of responding to a change in the environment to alter structure and function. Controlled catalysis, in which the activity or selectivity of a catalytic reaction can be adjusted through an external stimulus, offers opportunities for innovation in catalysis. Catalyst discovery could be simplified if a single thoughtfully designed complex could work synergistically with additives to optimize performance rather than trying a multitude of different metal/ligand combinations. Temporal control could be gained to facilitate the execution of multiple reactions in the same flask, for example, by activating one catalyst and deactivating another to avoid incompatibilities. Selectivity switching could enable copolymer synthesis with well-defined chemical and material properties. These applications might sound futuristic for synthetic catalysts, but in nature, such a degree of controlled catalysis is commonplace. For example, allosteric interactions and/or feedback loops modulate enzymatic activity to enable complex small-molecule synthesis and sequence-defined polymerization reactions in complex mixtures containing many catalytic sites. In many cases, regulation is achieved by "gating" substrate access to the active site. Fundamental advances in catalyst design are needed to better understand the factors that enable controlled catalysis in the arena of synthetic chemistry, particularly in achieving substrate gating outside of macromolecular environments. In this Account, the development of design principles for achieving cation-controlled catalysis is described. The guiding hypothesis was that gating substrate access to a catalyst site could be achieved by controlling the dynamics of a hemilabile ligand through secondary Lewis acid/base and/or cation-dipole interactions. To enforce such interactions, catalysts sitting at the interface of organometallic catalysis and supramolecular chemistry were designed. A macrocyclic crown ether was incorporated into a robust organometallic pincer ligand, and these "pincer-crown ether" ligands have been explored in catalysis. Complementary studies of controlled catalysis and detailed mechanistic analysis guided the development of iridium, nickel, and palladium pincer-crown ether catalysts capable of substrate gating. Toggling the gate between open and closed states leads to switchable catalysis, where cation addition/removal changes the turnover frequency or the product selectivity. Varying the degree of gating leads to tunable catalysis, where the activity can be tuned based on the identity and amount of salt added. Research has focused on reactions of alkenes, particularly isomerization reactions, which has in turn led to design principles for cation-controlled catalysts. Conspectus Catalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals and plastics, the production of fuels, and much more. In most cases, a particular catalyst is optimized to mediate a particular reaction, continually producing a desired product at a given rate. There is enormous opportunity in developing catalysts that are dynamic, capable of responding to a change in the environment to alter structure and function. Controlled catalysis, in which the activity or selectivity of a catalytic reaction can be adjusted through an external stimulus, offers opportunities for innovation in catalysis. Catalyst discovery could be simplified if a single thoughtfully designed complex could work synergistically with additives to optimize performance rather than trying a multitude of different metal/ligand combinations. Temporal control could be gained to facilitate the execution of multiple reactions in the same flask, for example, by activating one catalyst and deactivating another to avoid incompatibilities. Selectivity switching could enable copolymer synthesis with well-defined chemical and material properties. These applications might sound futuristic for synthetic catalysts, but in nature, such a degree of controlled catalysis is commonplace. For example, allosteric interactions and/or feedback loops modulate enzymatic activity to enable complex small-molecule synthesis and sequence-defined polymerization reactions in complex mixtures containing many catalytic sites. In many cases, regulation is achieved by “gating” substrate access to the active site. Fundamental advances in catalyst design are needed to better understand the factors that enable controlled catalysis in the arena of synthetic chemistry, particularly in achieving substrate gating outside of macromolecular environments. In this Account, the development of design principles for achieving cation-controlled catalysis is described. The guiding hypothesis was that gating substrate access to a catalyst site could be achieved by controlling the dynamics of a hemilabile ligand through secondary Lewis acid/base and/or cation–dipole interactions. To enforce such interactions, catalysts sitting at the interface of organometallic catalysis and supramolecular chemistry were designed. A macrocyclic crown ether was incorporated into a robust organometallic pincer ligand, and these “pincer-crown ether” ligands have been explored in catalysis. Complementary studies of controlled catalysis and detailed mechanistic analysis guided the development of iridium, nickel, and palladium pincer-crown ether catalysts capable of substrate gating. Toggling the gate between open and closed states leads to switchable catalysis, where cation addition/removal changes the turnover frequency or the product selectivity. Varying the degree of gating leads to tunable catalysis, where the activity can be tuned based on the identity and amount of salt added. Research has focused on reactions of alkenes, particularly isomerization reactions, which has in turn led to design principles for cation-controlled catalysts. |
| Author | Miller, Alexander J. M. Acosta-Calle, Sebastian |
| AuthorAffiliation | Department of Chemistry |
| AuthorAffiliation_xml | – name: Department of Chemistry |
| Author_xml | – sequence: 1 givenname: Sebastian surname: Acosta-Calle fullname: Acosta-Calle, Sebastian – sequence: 2 givenname: Alexander J. M. orcidid: 0000-0001-9390-3951 surname: Miller fullname: Miller, Alexander J. M. email: ajmm@email.unc.edu |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/36977400$$D View this record in MEDLINE/PubMed |
| BookMark | eNqFkDtPwzAUhS0Eog_4BwhlZEmxHTsPNhSVglSJgTIiy3acNlVqF9tR1X-P08fCAJN9zz3nSPcbgUtttALgDsEJghg9cukmXErTae8miYQQ0vQCDBHFMCZ5kV-CYdBQ-BM8ACPn1mHEJM2uwSBJiywjEA7B16LTXLQq4rqKPnaNl6vDWHLP271rXDQ97KtI7HuxMToujfbWtL04C4peRiG3ikprdjqa-pWy0bxZhkJ3A65q3jp1e3rH4PNluihf4_n77K18nsccp4mP61rCCqm0lkQQKjJBclFwqpTAnOIcUl6HqwokYaKooIpyTBKCC6JEVlOEkzF4OPZurfnulPNs0zip2pZrZTrHcFZgihJCkmC9P1k7sVEV29pmw-2enZEEw9PRIK1xzqqaycYfDveWNy1DkPX8WeDPzvzZiX8Ik1_hc_8_MXiM9du16awOtP6O_ADwhJ6m |
| CitedBy_id | crossref_primary_10_1093_chemle_upae042 crossref_primary_10_1002_ange_202313899 crossref_primary_10_1002_anie_202313899 crossref_primary_10_1016_j_molliq_2023_122878 crossref_primary_10_1021_jacs_3c10877 crossref_primary_10_1016_j_jorganchem_2024_123210 crossref_primary_10_1002_ange_202314376 crossref_primary_10_1002_anie_202314376 crossref_primary_10_1002_anie_202404684 crossref_primary_10_1039_D4QI01563K crossref_primary_10_1021_acs_nanolett_4c01897 crossref_primary_10_1039_D4QI01219D crossref_primary_10_1002_ange_202404684 crossref_primary_10_1002_ange_202315381 crossref_primary_10_1002_anie_202315381 crossref_primary_10_1002_ejic_202500073 crossref_primary_10_1021_jacs_3c06267 crossref_primary_10_3390_molecules29235544 crossref_primary_10_1039_D3SC06177A crossref_primary_10_1177_15330338241259780 |
| Cites_doi | 10.1021/cs500273d 10.1007/b113929 10.1002/anie.201906124 10.1021/ja3036477 10.1021/acs.organomet.9b00462 10.1039/C3CS60027K 10.1002/ejoc.201901914 10.1039/C9DT00235A 10.1002/anie.201408314 10.1038/nchem.2445 10.1021/jacs.8b01815 10.1021/acscatal.0c03784 10.1021/jacs.1c05185 10.1002/asia.200900111 10.1021/ja507324s 10.1039/C8CY00328A 10.1039/C9CC00803A 10.1002/anie.201000380 10.1039/C4CC02399D 10.1021/jacs.0c11601 10.1021/acs.chemrev.1c00324 10.1351/pac200375010071 10.1021/acs.organomet.5b00405 10.1016/j.eurpolymj.2020.110100 10.1002/anie.201701006 10.1021/acs.chemrev.5b00426 10.1021/acs.accounts.8b00523 10.1039/C7DT02156A 10.1055/s-2008-1078425 10.1039/C5CS00096C 10.1021/jacs.0c08631 10.1021/om100804k 10.1002/1521-3773(20010216)40:4<680::AID-ANIE6800>3.0.CO;2-0 10.1021/acs.organomet.7b00431 10.1016/0010-8545(91)80013-4 10.1021/acs.chemrev.5b00052 10.1021/acs.organomet.5b00786 10.1021/jacs.5b01054 10.1021/acs.inorgchem.7b01485 10.1021/ja9723601 10.1021/cr500632f 10.1021/acs.organomet.6b00607 10.1039/D0SC03736B 10.1021/acs.organomet.6b00856 10.1021/acs.organomet.2c00315 10.1002/chem.201602453 10.1002/cctc.201402341 10.1021/cr00019a004 |
| ContentType | Journal Article |
| Copyright | 2023 American Chemical Society |
| Copyright_xml | – notice: 2023 American Chemical Society |
| DBID | AAYXX CITATION NPM 7X8 |
| DOI | 10.1021/acs.accounts.3c00056 |
| DatabaseName | CrossRef PubMed MEDLINE - Academic |
| DatabaseTitle | CrossRef PubMed MEDLINE - Academic |
| DatabaseTitleList | MEDLINE - Academic PubMed |
| Database_xml | – sequence: 1 dbid: NPM name: PubMed url: https://proxy.k.utb.cz/login?url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed sourceTypes: Index Database |
| DeliveryMethod | fulltext_linktorsrc |
| Discipline | Chemistry |
| EISSN | 1520-4898 |
| EndPage | 981 |
| ExternalDocumentID | 36977400 10_1021_acs_accounts_3c00056 a998458893 |
| Genre | Journal Article |
| GroupedDBID | --- -DZ -~X 23M 4.4 55A 5GY 5VS 5ZA 6J9 6P2 7~N 85S AABXI ABFRP ABMVS ABPTK ABQRX ABUCX ACGFO ACGFS ACJ ACNCT ACS ADHLV AEESW AENEX AFEFF AFXLT AGXLV AHGAQ ALMA_UNASSIGNED_HOLDINGS AQSVZ BAANH CS3 D0L EBS ED~ F5P GGK GNL IH2 IH9 JG~ LG6 P2P RNS ROL TWZ UI2 UPT VF5 VG9 W1F WH7 XSW YZZ ZCA ~02 53G AAYXX ABBLG ABJNI ABLBI CITATION CUPRZ NPM YIN 7X8 |
| ID | FETCH-LOGICAL-a263t-ffc0d1e6fc4b45b7b48b9a5eeb2a52805af52091c03e5b5e5a2434294eb7f5123 |
| IEDL.DBID | ACS |
| ISSN | 0001-4842 1520-4898 |
| IngestDate | Fri Jul 11 06:43:16 EDT 2025 Wed Feb 19 02:25:04 EST 2025 Tue Jul 01 03:16:09 EDT 2025 Thu Apr 24 23:01:55 EDT 2025 Thu Jul 06 08:30:35 EDT 2023 |
| IsPeerReviewed | true |
| IsScholarly | true |
| Issue | 8 |
| Language | English |
| License | https://doi.org/10.15223/policy-029 https://doi.org/10.15223/policy-037 https://doi.org/10.15223/policy-045 |
| LinkModel | DirectLink |
| MergedId | FETCHMERGED-LOGICAL-a263t-ffc0d1e6fc4b45b7b48b9a5eeb2a52805af52091c03e5b5e5a2434294eb7f5123 |
| Notes | ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 |
| ORCID | 0000-0001-9390-3951 |
| PMID | 36977400 |
| PQID | 2792513443 |
| PQPubID | 23479 |
| PageCount | 11 |
| ParticipantIDs | proquest_miscellaneous_2792513443 pubmed_primary_36977400 crossref_citationtrail_10_1021_acs_accounts_3c00056 crossref_primary_10_1021_acs_accounts_3c00056 acs_journals_10_1021_acs_accounts_3c00056 |
| ProviderPackageCode | CITATION AAYXX |
| PublicationCentury | 2000 |
| PublicationDate | 20230418 2023-04-18 2023-Apr-18 |
| PublicationDateYYYYMMDD | 2023-04-18 |
| PublicationDate_xml | – month: 04 year: 2023 text: 20230418 day: 18 |
| PublicationDecade | 2020 |
| PublicationPlace | United States |
| PublicationPlace_xml | – name: United States |
| PublicationTitle | Accounts of chemical research |
| PublicationTitleAlternate | Acc. Chem. Res |
| PublicationYear | 2023 |
| Publisher | American Chemical Society |
| Publisher_xml | – name: American Chemical Society |
| References | ref9/cit9 ref45/cit45 ref3/cit3 ref27/cit27 ref16/cit16 ref23/cit23 ref8/cit8 ref2/cit2 ref34/cit34 ref37/cit37 ref48/cit48 ref17/cit17 ref10/cit10 ref35/cit35 ref19/cit19 ref21/cit21 Kubas G. J. (ref20/cit20) 2001 ref42/cit42 ref46/cit46 ref49/cit49 ref13/cit13 ref24/cit24 ref38/cit38 Larsen C. R. (ref31/cit31) 2018 ref6/cit6 ref36/cit36 ref18/cit18 ref11/cit11 ref25/cit25 ref29/cit29 ref32/cit32 ref39/cit39 ref14/cit14 ref5/cit5 ref43/cit43 ref28/cit28 ref40/cit40 ref26/cit26 ref12/cit12 ref15/cit15 ref41/cit41 ref22/cit22 ref33/cit33 ref4/cit4 ref30/cit30 ref47/cit47 ref1/cit1 ref44/cit44 ref7/cit7 |
| References_xml | – ident: ref35/cit35 doi: 10.1021/cs500273d – volume-title: Metal Dihydrogen and Sigma-Bond Complexes: Structure, Theory, and Reactivity year: 2001 ident: ref20/cit20 doi: 10.1007/b113929 – ident: ref29/cit29 doi: 10.1002/anie.201906124 – ident: ref45/cit45 doi: 10.1021/ja3036477 – ident: ref24/cit24 doi: 10.1021/acs.organomet.9b00462 – ident: ref6/cit6 doi: 10.1039/C3CS60027K – ident: ref18/cit18 doi: 10.1002/ejoc.201901914 – ident: ref36/cit36 doi: 10.1039/C9DT00235A – ident: ref34/cit34 doi: 10.1002/anie.201408314 – ident: ref28/cit28 doi: 10.1038/nchem.2445 – ident: ref47/cit47 doi: 10.1021/jacs.8b01815 – ident: ref39/cit39 doi: 10.1021/acscatal.0c03784 – ident: ref43/cit43 doi: 10.1021/jacs.1c05185 – ident: ref44/cit44 doi: 10.1002/asia.200900111 – ident: ref1/cit1 doi: 10.1021/ja507324s – ident: ref41/cit41 doi: 10.1039/C8CY00328A – ident: ref13/cit13 doi: 10.1039/C9CC00803A – ident: ref5/cit5 doi: 10.1002/anie.201000380 – ident: ref26/cit26 doi: 10.1039/C4CC02399D – ident: ref3/cit3 doi: 10.1021/jacs.0c11601 – ident: ref30/cit30 doi: 10.1021/acs.chemrev.1c00324 – ident: ref38/cit38 doi: 10.1351/pac200375010071 – ident: ref22/cit22 doi: 10.1021/acs.organomet.5b00405 – ident: ref49/cit49 doi: 10.1016/j.eurpolymj.2020.110100 – ident: ref2/cit2 doi: 10.1002/anie.201701006 – ident: ref10/cit10 doi: 10.1021/acs.chemrev.5b00426 – ident: ref12/cit12 doi: 10.1021/acs.accounts.8b00523 – ident: ref19/cit19 doi: 10.1039/C7DT02156A – ident: ref16/cit16 doi: 10.1055/s-2008-1078425 – ident: ref7/cit7 doi: 10.1039/C5CS00096C – ident: ref48/cit48 doi: 10.1021/jacs.0c08631 – ident: ref17/cit17 doi: 10.1021/om100804k – start-page: 1365 volume-title: Applied Homogeneous Catalysis with Organometallic Compounds year: 2018 ident: ref31/cit31 – ident: ref15/cit15 doi: 10.1002/1521-3773(20010216)40:4<680::AID-ANIE6800>3.0.CO;2-0 – ident: ref23/cit23 doi: 10.1021/acs.organomet.7b00431 – ident: ref14/cit14 doi: 10.1016/0010-8545(91)80013-4 – ident: ref27/cit27 doi: 10.1021/acs.chemrev.5b00052 – ident: ref37/cit37 doi: 10.1021/acs.organomet.5b00786 – ident: ref9/cit9 doi: 10.1021/jacs.5b01054 – ident: ref25/cit25 doi: 10.1021/acs.inorgchem.7b01485 – ident: ref33/cit33 doi: 10.1021/ja9723601 – ident: ref8/cit8 doi: 10.1021/cr500632f – ident: ref40/cit40 doi: 10.1021/acs.organomet.6b00607 – ident: ref42/cit42 doi: 10.1039/D0SC03736B – ident: ref46/cit46 doi: 10.1021/acs.organomet.6b00856 – ident: ref4/cit4 doi: 10.1021/acs.organomet.2c00315 – ident: ref11/cit11 doi: 10.1002/chem.201602453 – ident: ref32/cit32 doi: 10.1002/cctc.201402341 – ident: ref21/cit21 doi: 10.1021/cr00019a004 |
| SSID | ssj0002467 |
| Score | 2.484602 |
| Snippet | Conspectus Catalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals... ConspectusCatalysis has become an essential tool in science and technology, impacting the discovery of pharmaceuticals, the manufacture of commodity chemicals... |
| SourceID | proquest pubmed crossref acs |
| SourceType | Aggregation Database Index Database Enrichment Source Publisher |
| StartPage | 971 |
| Title | Tunable and Switchable Catalysis Enabled by Cation-Controlled Gating with Crown Ether Ligands |
| URI | http://dx.doi.org/10.1021/acs.accounts.3c00056 https://www.ncbi.nlm.nih.gov/pubmed/36977400 https://www.proquest.com/docview/2792513443 |
| Volume | 56 |
| hasFullText | 1 |
| inHoldings | 1 |
| isFullTextHit | |
| isPrint | |
| link | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwlV1JS8UwEA76POjFfV-I4MVDnm0226OU9xRxOajgRUqSpiJKFfseor_emS5PVEQ9Nm2GJjPtfJPZCNmxACG0t47FOlYMfniegRoRLLOB11GUZ1GVHn16po-u5PG1uv4wFL968Hm4Z1wJpKvOCWVXOAQZepxMcA2qBqFQcjH683Kp6xqZYCLLSPI2Ve4HKqiQXPlZIf2AMitt058h523OTh1kct8dDmzXvX0v4fjHhcyS6QZ40oNaUubImC_myWTS9ntbIDeXwyqPipoioxcvd8DO6jLBAx6sW0J71f2M2lccBIaypA50x8FDgwHUFM91aYK2Pe0htqQnd7eYTbxIrvq9y-SINc0XmOFaDFieuyALvc6dtFLZfSsjGxvlwRI3ikeBMjlG0IQuEF5Z5ZXhUgCvpbf7OaAIsUQ6xWPhVwi1XGU8ziPDjQZz0sZZDLQyLowFc1KJVbILe5M2H0-ZVn5xHqY42G5Y2mzYKhEtt1LXVDHHZhoPv8xio1lPdRWPX57fbgUhBS6gD8UU_nFYplhvUYVCSnjr5VpCRhSFRjAdBGv_WM86mcIG9uifCqMN0hk8D_0mwJyB3apk-x3EFvmc |
| linkProvider | American Chemical Society |
| linkToHtml | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwlR3LTtwwcLTQA1xoC7SFvlyplx68TfwiOaJo6bYsXFgqLiiyEwehVgGRXSH69Z1xkkUgIbTHTOKR7Zl4ZjwvgK8OVQjjXcFTk2qOB57nKEYkL13kTZJUZRLSo4-OzfhU_TrTZwPQfS4MTqJBTE1w4t9XF4i_E8y2DRSaoSxI1zAr8EIbZahjw352sjiAhTJtqUy0lFWiRJ8x9wQWkktF81AuPaFsBqFz8BJ-L6YbYk3-DOczNyz-ParkuPR6XsFGp4ay_ZZvXsPA15uwlvXd37bgfDoPWVXM1iU7ub1E4obHjK57qIoJG4X3JXN3BETy8qwNeyfgD0vh1IxueVlGlj4bkabJJpcXlFu8DacHo2k25l0rBm6FkTNeVUVUxt5UhXJKuz2nEpda7dEut1okkbYVxdPERSS9dtprK5REyivv9irUKeQbWK2vav8OmBO6FGmVWGENGpcuLVPEVQppHRqXWu7AN9ybvPuVmjx4yUWcE7DfsLzbsB2QPdHyoqtpTq01_j4zii9GXbc1PZ75_kvPDzlSgTwqtvZX8yan6os6lkrhrN-2jLLAKA2p1lG0u8R6PsPaeHo0ySc_jw_fwzq1tifPVZx8gNXZzdx_RAVo5j4Fdv8P61QCDQ |
| linkToPdf | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3dS-QwEA93Cp4vft156nlnBF_uIWubL9tHqbvnN4IKIkhJmvQQpYrdRfSvv5m0XfRA5O6x02ZIMpPOb5LMDCEbFiCE9rZgqU4Vgx-eZ2BGBHM28jpJSpeE8OijY717Lvcv1MWLUl_QiRo41eEQH1f1vSvbDAPxJtJNU0Sh7okC8Yb-SCYBk8RYtWE7Ox3_hLnUTbpM8JZlInkXNfcGF7RNRf3aNr0BOIPhGcySy3GXw32Tm95oaHvF81_ZHP9rTHNkpoWjdLvRn3nywVcL5FPWVYH7TK7ORiG6iprK0dPHaxByeMxw2wezmdB-eO-ofUIiiJllzfV3JP4yeK2a4m4vzdDjp31EnPTw-jfGGH8h54P-WbbL2pIMzHAthqwsi8jFXpeFtFLZLSsTmxrlwT83iieRMiXeq4mLSHhllVeGSwEaIL3dKgFbiEUyUd1VfolQy5XjaZkYbjQ4mTZ1KfByXBgLTqYSy-QnzE3eLqk6D6flPM6R2E1Y3k7YMhGd4PKizW2OJTZu32nFxq3um9we73y_3ulEDlLAkxVT-btRnWMWRhULKaHXXxtlGXMUGiF2FK38w3jWyNTJziA_3Ds--EamscI9HmDFySqZGD6M_HfAQUP7I2j8Hxx0BIc |
| openUrl | ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Tunable+and+Switchable+Catalysis+Enabled+by+Cation-Controlled+Gating+with+Crown+Ether+Ligands&rft.jtitle=Accounts+of+chemical+research&rft.au=Acosta-Calle%2C+Sebastian&rft.au=Miller%2C+Alexander+J+M&rft.date=2023-04-18&rft.eissn=1520-4898&rft.volume=56&rft.issue=8&rft.spage=971&rft_id=info:doi/10.1021%2Facs.accounts.3c00056&rft_id=info%3Apmid%2F36977400&rft.externalDocID=36977400 |
| thumbnail_l | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=0001-4842&client=summon |
| thumbnail_m | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=0001-4842&client=summon |
| thumbnail_s | http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=0001-4842&client=summon |