Journal of the American Chemical Society, volume 127, issue 31, pages 10869-10878

Cobalt Catalysts for the Alternating Copolymerization of Propylene Oxide and Carbon Dioxide:  Combining High Activity and Selectivity

Publication typeJournal Article
Publication date2005-07-14
scimago Q1
SJR5.489
CiteScore24.4
Impact factor14.4
ISSN00027863, 15205126
DOI:  10.1021/ja051744l
PubMed ID:  16076192
General Chemistry
Catalysis
Biochemistry
Colloid and Surface Chemistry
Abstract
Synthetic pathways to (salcy)CoX (salcy = N,N'-bis(3,5-di-tert-butylsalicylidene)-1,2-diaminocyclohexane; X = halide or carboxylate) complexes are described. Complexes (R,R)-(salcy)CoCl, (R,R)-(salcy)CoBr, (R,R)-(salcy)CoOAc, and (R,R)-(salcy)CoOBzF(5) (OBzF(5) = pentafluorobenzoate) are highly active catalysts for the living, alternating copolymerization of propylene oxide (PO) and CO(2), yielding poly(propylene carbonate) (PPC) with no detectable byproducts. The PPC generated using these catalyst systems is highly regioregular and has up to 99% carbonate linkages with a narrow molecular weight distribution (MWD). Inclusion of the cocatalysts [PPN]Cl or [PPN][OBzF(5)] ([PPN] = bis(triphenylphosphine)iminium) with complex (R,R)-(salcy)CoCl, (R,R)-(salcy)CoBr, or (R,R)-(salcy)CoOBzF(5) results in remarkable activity enhancement of the copolymerization as well as improved stereoselectivity and regioselectivity with maximized reactivity at low CO(2) pressures. In the case of [PPN]Cl with (R,R)-(salcy)CoOBzF(5), an unprecedented catalytic activity of 620 turnovers per hour is achieved for the copolymerization of rac-PO and CO(2), yielding iso-enriched PPC with 94% head-to-tail connectivity. The stereochemistry of the monomer and catalyst used in the copolymerization has dramatic effects on catalytic activity and the PPC microstructure. Using catalyst (R,R)-(salcy)CoBr with (S)-PO/CO(2) generates highly regioregular PPC, whereas using (R)-PO/CO(2) with the same catalyst gives an almost completely regiorandom copolymer. The rac-PO/CO(2) copolymerization with catalyst rac-(salcy)CoBr yields syndio-enriched PPC, an unreported PPC microstructure. In addition, (R,R)-(salcy)CoOBzF(5)/[PPN]Cl copolymerizes (S)-PO and CO(2) with a turnover frequency of 1100 h(-1), an activity surpassing that observed in any previously reported system.
Found 23
By date By citations
Wiley
A Dodecameric Water Cluster Built around a Cyclic Quasiplanar Hexameric Core in an Organic Supramolecular Complex of a Cryptand
Ghosh S.K., Bharadwaj P.K.
Angewandte Chemie - International Edition scimago Q1 wos Q1
2004-07-05 citations by CoLab: 221 Abstract  
An infinite network is formed by the hydrogen bonding of a cluster of 12 hydrogen-bonded water molecules (see picture) to the secondary amino nitrogen atoms of a laterally nonsymmetric azacryptand. This mode of association had not previously been predicted or found experimentally.
American Chemical Society (ACS)
Regioregular and Regioirregular Oligoether Carbonates:  A 13C{H} NMR Investigation
Byrnes M.J., Chisholm M.H., Hadad C.M., Zhou Z.
Macromolecules scimago Q1 wos Q1
2004-04-27 citations by CoLab: 12 Abstract  
Oligoether carbonates R(PO)nOCO2(PO)nR, where R = Me, Et, or H, PO = propylene oxide ring-opened unit, and n = 1, 2, 3, 4, ∼10, and ∼30, have been prepared and characterized by ESI/MS or MALDI/MS a...
Wiley
Iron-Catalyzed Asymmetric Sulfide Oxidation with Aqueous Hydrogen Peroxide
Legros J., Bolm C.
Angewandte Chemie - International Edition scimago Q1 wos Q1
2003-11-17 citations by CoLab: 252 Abstract  
An iron in the fire: Iron-based catalysts promote the asymmetric oxidation of alkyl aryl sulfides to the corresponding sulfoxides with up to 90 % ee (see scheme). Simple hydrogen peroxide (30 % in water) serves as the terminal oxidant.
American Chemical Society (ACS)
Comparative Kinetic Studies of the Copolymerization of Cyclohexene Oxide and Propylene Oxide with Carbon Dioxide in the Presence of Chromium Salen Derivatives. In Situ FTIR Measurements of Copolymer vs Cyclic Carbonate Production
Darensbourg D.J., Yarbrough J.C., Ortiz C., Fang C.C.
Journal of the American Chemical Society scimago Q1 wos Q1
2003-06-01 citations by CoLab: 300 Abstract  
The catalysis of the reaction of carbon dioxide with epoxides (cyclohexene oxide or propylene oxide) using the (salen)Cr(III)Cl complex as catalyst, where H(2)salen = N,N'-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexenediimine (1), to provide copolymer and cyclic carbonate has been investigated by in situ infrared spectroscopy. As previously demonstrated for the cyclohexene oxide/CO(2) reaction in the presence of complex 1, coupling of propylene oxide and carbon dioxide was found to occur by way of a pathway first-order in catalyst concentration. Unlike the cyclohexene oxide/carbon dioxide reaction catalyzed by complex 1, which affords completely alternating copolymer and only small quantities of trans-cyclic cyclohexyl carbonate, under similar conditions propylene oxide/carbon dioxide produces mostly cyclic propylene carbonate. Comparative kinetic measurements were performed as a function of reaction temperature to assess the activation barrier for production of cyclic carbonates and polycarbonates for the two different classes of epoxides, i.e., alicyclic (cyclohexene oxide) and aliphatic (propylene oxide). As anticipated in both instances the unimolecular pathway for cyclic carbonate formation has a larger energy of activation than the bimolecular enchainment pathway. That is, the energies of activation determined for cyclic propylene carbonate and poly(propylene carbonate) formation were 100.5 and 67.6 kJ.mol(-1), respectively, compared to the corresponding values for cyclic cyclohexyl carbonate and poly(cyclohexylene carbonate) production of 133 and 46.9 kJ.mol(-1). The small energy difference in the two concurrent reactions for the propylene oxide/CO(2) process (33 kJ.mol(-1)) accounts for the large quantity of cyclic carbonate produced at elevated temperatures in this instance.
Wiley
DMAP/Cr(III) Catalyst Ratio: The Decisive Factor for Poly(propylene carbonate) Formation in the Coupling of CO2 and Propylene Oxide
Eberhardt R., Allmendinger M., Rieger B.
Macromolecular Rapid Communications scimago Q1 wos Q2
2003-02-01 citations by CoLab: 182 Abstract  
Highly efficient formation of poly(propylene carbonate) can be achieved in the coupling of CO 2 and propylene oxide assisted by 4-(N,N-dimethylamino)pyridine (DMAP) and catalyzed with salen chromium(III) chloride by using DMAP/Cr ratios of less than 2. Under these conditions a possible backbiting mechanism is suppressed, leading to only minor amounts of cyclic carbonate as a side product.
American Chemical Society (ACS)
High-Activity, Single-Site Catalysts for the Alternating Copolymerization of CO2 and Propylene Oxide
Allen S.D., Moore D.R., Lobkovsky E.B., Coates G.W.
Journal of the American Chemical Society scimago Q1 wos Q1
2002-11-08 citations by CoLab: 292 Abstract  
Despite recent advances regarding catalysts for CO2/epoxide copolymerization, the development of high-activity catalysts for alternating polymerization of CO2 and commodity epoxides, such as propylene oxide, remains a challenge. A new class of unsymmetrically substituted beta-diiminate zinc complexes is reported that exhibits unprecedented activity for CO2/propylene oxide copolymerization. The polymers formed are of high molecular weight (Mn approximately 35 kg/mol) and have narrow polydispersities (PDI approximately 1.1), consistent with a living polymerization.
Wiley
A Novel Polymer-Supported Arene-Ruthenium Complex for Ring-Closing Olefin Metathesis
Akiyama R., Kobayashi S.
Angewandte Chemie - International Edition scimago Q1 wos Q1
2002-07-15 citations by CoLab: 108 Abstract  
Styrene as ligand and support: An excellent polymer-supported ruthenium catalyst 1 has been developed in which the benzene rings of polystyrene are utilized as ligands to immobilize the ruthenium onto the polymer. In the presence of 1, ring-closing olefin metathesis proceeded smoothly to afford adducts in high yields. Furthermore, the catalyst was recovered quantitatively by filtration, and could be reused without loss of activity.
American Chemical Society (ACS)
Stereochemistry of Lactide Polymerization with Chiral Catalysts:  New Opportunities for Stereocontrol Using Polymer Exchange Mechanisms
Ovitt T.M., Coates G.W.
Journal of the American Chemical Society scimago Q1 wos Q1
2002-01-26 citations by CoLab: 656 Abstract  
The synthesis of chiral aluminum and yttrium alkoxides and their application for lactide polymerization are reported. The complexes (SalBinap)MOR [4, M = Al, R = (i)Pr; 5, M = Y, R = (CH(2))(2)NMe(2)] are synthesized by reacting the ligand (SalBinap)H(2) [2,2'-[(1,1'-binaphthalene)-2,2'-diylbis(nitrilomethylidyne)]bisphenol] with the appropriate metal trisalkoxide. While enantiomerically pure yttrium complex 5 did not effect stereocontrol in the polymerization of either meso- or rac-lactide, homochiral 4 was found to exhibit excellent stereocontrol in a range of lactide polymerizations. Enantiomerically pure 4 polymerizes meso-lactide to syndiotactic poly(lactic acid) (PLA), while rac-4 polymerizes meso- and rac-lactide to heterotactic and isotactic stereoblock PLA, respectively. On the basis of the absolute stereochemistry of ring-opening of meso-lactide using (R)-4, a polymer exchange mechanism is proposed to account for the PLA microstructures resulting from rac-4.
American Chemical Society (ACS)
Selectivity in Propene Polymerization with Metallocene Catalysts
Resconi L., Cavallo L., Fait A., Piemontesi F.
Chemical Reviews scimago Q1 wos Q1
2000-03-25 citations by CoLab: 1273
Wiley
The Search for New Environmentally Friendly Chemical Processes
Bolm C., Beckmann O., Dabard O.A.
Angewandte Chemie - International Edition scimago Q1 wos Q1
1999-03-26 citations by CoLab: 46 Abstract  
Minimization of the hazards in chemical industry processes and the avoidance of the production of toxic substances-these are the goals of environmentally friendly processes. These technologies can also be economically advantageous. This approach is exemplified by a new, almost ideal atom-efficient oxidative route to adipic acid (1, see scheme), which offers several environmentally improved features compared to the traditional manufacture. [W]=tungsten catalyst.
American Association for the Advancement of Science (AAAS)
Asymmetric Catalysis with Water: Efficient Kinetic Resolution of Terminal Epoxides by Means of Catalytic Hydrolysis
Tokunaga M., Larrow J.F., Kakiuchi F., Jacobsen E.N.
Science scimago Q1 wos Q1 Open Access
1997-08-15 citations by CoLab: 1209 PDF Abstract  
Epoxides are versatile building blocks for organic synthesis. However, terminal epoxides are arguably the most important subclass of these compounds, and no general and practical method exists for their production in enantiomerically pure form. Terminal epoxides are available very inexpensively as racemic mixtures, and kinetic resolution is an attractive strategy for the production of optically active epoxides, given an economical and operationally simple method. Readily accessible synthetic catalysts (chiral cobalt-based salen complexes) have been used for the efficient asymmetric hydrolysis of terminal epoxides. This process uses water as the only reagent, no added solvent, and low loadings of a recyclable catalyst (<0.5 mole percent), and it affords highly valuable terminal epoxides and 1,2-diols in high yield with high enantiomeric enrichment.
Elsevier
The coordination chemistry of carbon dioxide and its relevance for catalysis: a critical survey
Leitner W.
Coordination Chemistry Reviews scimago Q1 wos Q1
1996-08-01 citations by CoLab: 488 Abstract  
The ability of carbon dioxide to act as a ligand in transition metal complexes is now well documented and several coordination modes of CO 2 have been described. Spectroscopic methodologies allowing the characterization of CO 2 complexes even if crystallographic data are not available have now been developed. The binding of CO 2 to a metal centre generally leads to “activation” of the CO 2 molecule, and various reactions of coordinated CO 2 are known. However, activation by coordination is not a necessary prerequisite for catalytic conversion of carbon dioxide to useful chemicals. Recent theoretical and experimental work suggests that only weak interactions between CO 2 and the active metal centre are sufficient to bring about catalytic reactions involving the formal insertion of CO 2 in an MX bond as a key step.
American Chemical Society (ACS)
Metalloporphyrins as Initiators for Living and Immortal Polymerizations
Aida T., Inoue S.
Accounts of Chemical Research scimago Q1 wos Q1
1996-01-10 citations by CoLab: 340
American Chemical Society (ACS)
The Organometallic Chemistry of Carbon Dioxide
Gibson D.H.
Chemical Reviews scimago Q1 wos Q1
1996-01-01 citations by CoLab: 573 Abstract  
The possibility of recycling CO{sub 2} from industrial emissions and of removing some of this greenhouse gas, an environmental pollutant, is receiving increased attention. Also, the possibility of using CO{sub 2} as the starting material for the synthesis of fine chemicals provides an attractive alternative to compounds presently derived from petroleum. Efforts to convert CO{sub 2} to useful chemicals will inevitably center on transition metal catalysts. Furthermore, efforts to enhance the yield of hydrogen in water gas shift reactions are also centered on carbon dioxide interactions with transition metal catalysts. For all these reasons, a broader understanding of the organometallic chemistry of CO{sub 2} is being sought. In this article, only those compounds that can be clearly identified as having carbon dioxide bound to metal centers through carbon will be considered. Thus the discussions will not include metal formate complexes whose chemistry has been reviewed recently. Also, the discussions will not include metallocarboxylic acids or metallocarboxylate esters except where these compounds have been used as reagents for the synthesis of CO{sub 2} complexes or result from reactions of these compounds. 111 refs.
Wiley
Carbon Dioxide as a Raw Material: The Synthesis of Formic Acid and Its Derivatives from CO2
Leitner W.
Angewandte Chemie International Edition in English
1995-11-03 citations by CoLab: 707 Abstract  
AbstractThe use of carbon dioxide as a raw material for chemical syntheses is an ecologically and economically valuable extension to the carbon sources used at the present time. In order to convert the thermodynamically stable and comparatively unreactive CO2 molecule into the desired product in an efficient manner, suitable reaction conditions and activation mechanisms must be found. The catalytic reduction of CO2 to formic acid and its derivatives has been intensively studied in recent years. A number of new approaches to the synthesis of formic acid from CO2 have reached such a state of knowledge that continuing development may well lead to industrial‐scale operation in the near future. This can to a large extent be attributed to the fruitful interaction between investigative work into reaction mechanisms and the development of new catalytic systems.
Found 479
By date By citations
Wiley
Organocatalyzed Copolymerization of CO 2 with Epoxide Toward Polycarbonate Synthesis
Feng X., Gnanou Y.
2025-03-07 citations by CoLab: 0
American Chemical Society (ACS)
Dual Kinetic Control of Polycarbonate Sequences via Breaking Catalysis Symmetry Using Dual Biomimetic Organoboron Catalysts
Chen Z., Yang G., Wu T., Qian Z., Wu G.
Macromolecules scimago Q1 wos Q1
2025-01-17 citations by CoLab: 0
Wiley
One‐Pot Synthesis of Polycarbonate‐b‐Polyester Block Copolymers From CO2/Epoxide/ε‐Caprolactone Catalyzed by Salen‐Cobalt(III) Complex
Fan C., Ge Q., Lu S., Feng X., Tu Y., Jia L., Lin S., Pan Q., Ng F.T.
Journal of Polymer Science scimago Q1 wos Q2
2025-01-08 citations by CoLab: 0 Abstract  
ABSTRACTA Salen‐Co(III)‐Cl catalyzed copolymerization strategy is developed for the controlled synthesis of polycarbonate‐b‐polyester block copolymers through a one‐pot process involving CO2, 4‐vinyl‐1‐cyclohexene‐1,2‐epoxy (VCHO), and ε‐caprolactone (ε‐CL). This procedure is extended to the copolymerization of CO2, VCHO, and lactide. The catalytic system is designed and optimized with temperature and CO2 acting as triggers to switch between CO2/epoxide copolymerization and ε‐CL homopolymerization. In addition, introducing water as the chain transfer agent reduced the polydispersity index (PDI) of the block copolymers. The copolymer composition can be controlled by adjusting the concentration ratio of epoxides and ε‐CL, yielding copolymers with carbonate molar ratios ranging from 14% to 67%. The block copolymers exhibit enhanced thermal stability, and the glass transition temperature (Tg) can be controlled by adjusting the block composition.
American Chemical Society (ACS)
Terpolymerization of Propylene Oxide, CO2, and p-Toluenesulfonyl Isocyanate for the Synthesis of Poly(urethane-carbonate): p-Toluenesulfonyl Isocyanate Acts as a Backbiting Suppressor
Muranaka S., Yamamoto I., Ema T.
ACS Applied Polymer Materials scimago Q1 wos Q1
2024-12-12 citations by CoLab: 1
Polymerization–cyclodepolymerization of polypropylene carbonate mediated by cobalt catalyst
Rzhevskiy S.A., Shurupova O.V., Asachenko A.F., Belov N.M., Plutalova A.V., Trofimchuk E.S., Toms R.V., Chernikova E.V., Beletskaya I.P.
Mendeleev Communications scimago Q3 wos Q3
2024-11-29 citations by CoLab: 1
American Chemical Society (ACS)
Trapping of Key “Ate” Intermediates of NHC-Group IV Relevant to Catalyzing Copolymerization of Cyclohexene Oxide with CO2
Suresh L., Lalrempuia R., Fjermestad T., Törnroos K.W., Bour J., Frache G., Nova A., Le Roux E.
Organometallics scimago Q1 wos Q2
2024-11-27 citations by CoLab: 0
MDPI
Novel Simple Approach for Production of Elastic Poly(propylene carbonate)
Trofimchuk E.S., Chernov I.V., Toms R.V., Rzhevskiy S.A., Asachenko A.F., Plutalova A.V., Shandryuk G.A., Chernikova E.V., Beletskaya I.P.
Polymers scimago Q1 wos Q1 Open Access
2024-11-22 citations by CoLab: 0 PDF Abstract  
The simple approach of increasing the elastic properties of atactic poly(propylene carbonate) (PPC) with Mn = 71.4 kDa, ĐM = Mw/Mn = 1.86, and predominantly carbonate units (>99%) is suggested by selecting the appropriate hot pressing temperature for PPC between 110 and 140 °C. Atactic PPC is synthesized through ring-opening copolymerization of (rac)-propylene oxide and CO2 mediated by racemic salen complex of Co(III). Hot pressing PPC results in the release of a small amount of propylene carbonate (PC), sufficient to lower the glass transition temperature from 39.4 to 26.1 °C. Consequently, increasing the pressing temperature from 110 to 140 °C generates materials with a reduced modulus of elasticity (from 1.94 to 0.09 GPa), yield strength (from 38 to 2 MPa) and increased tensile elongation (from 140 to 940%). Thermomechanical analysis has shown a significant expansion in sample volume by hundreds of percent within the 80–130 °C range. PPC also displays large, reversible deformations, which can be utilized by creating shape memory materials.
American Chemical Society (ACS)
Understanding the Effect of M(III) Choice in Heterodinuclear Polymerization Catalysts
Eisenhardt K.H., Fiorentini F., Williams C.K.
Inorganic Chemistry scimago Q1 wos Q1
2024-11-19 citations by CoLab: 0
American Chemical Society (ACS)
Evolution of Copolymers of Epoxides and CO2: Catalysts, Monomers, Architectures, and Applications
Yang G., Xie R., Zhang Y., Xu C., Wu G.
Chemical Reviews scimago Q1 wos Q1
2024-10-25 citations by CoLab: 9
MDPI
The Role of Ligand Exchange in Salen Cobalt Complexes in the Alternating Copolymerization of Propylene Oxide and Carbon Dioxide
Rzhevskiy S.A., Shurupova O.V., Asachenko A.F., Plutalova A.V., Chernikova E.V., Beletskaya I.P.
International Journal of Molecular Sciences scimago Q1 wos Q2 Open Access
2024-10-11 citations by CoLab: 3 PDF Abstract  
A comparative study of the copolymerization of racemic propylene oxide (PO) with CO2 catalyzed by racemic (salcy)CoX (salcy = N,N′-bis(3,5-di-tert-butylsalicylidene)-1,2-diaminocyclohexane; X = perfluorobenzoate (OBzF5) or 2,4-dinitrophenoxy (DNP)) in the presence of a [PPN]Cl ([PPN] = bis(triphenylphosphine)iminium) cocatalyst is performed in bulk at 21 °C and a 2.5 MPa pressure of CO2. The increase in the nucleophilicity of an attacking anion results in the increase in the copolymerization rate. Racemic (salcy)CoX provides a high selectivity of the copolymerization, which can be higher than 99%, and the living polymerization mechanism. Poly(propylene carbonate) (PPC) with bimodal molecular weight distribution (MWD) is formed throughout copolymerization. Both modes are living and are characterized by low dispersity, while their contribution to MWD depends on the nature of the attacking anion. The racemic (salcy)CoDNP/[PPN]DNP system is found to be preferable for the production of PPC with a high yield and selectivity.
Elsevier
Mononuclear phenoxy-imine Mg(II) compounds as catalysts for the ring-opening copolymerization of epoxides with CO2
Singha Roy S., Sarkar S., Srinivasan N., Antharjanam P.K., Kunnikuruvan S., Chakraborty D.
Materials Today Chemistry scimago Q1 wos Q1
2024-10-01 citations by CoLab: 0
American Chemical Society (ACS)
Rational Optimization of Ammonium and Phosphonium Cations of Bifunctional Organoborane Catalysts for Copolymerization of Propylene Oxide with CO2 to Afford Poly(propylene carbonate)
Xu C., Lu C., Zhao S., Yang G., Li W., Wang J., Wu G.
Macromolecules scimago Q1 wos Q1
2024-09-20 citations by CoLab: 3
Royal Society of Chemistry (RSC)
CO2-based polycarbonates from biobased cyclic terpenes with end-of-life usage potential
Holzmüller P., Preis J., Frey H.
Polymer Chemistry scimago Q1 wos Q2
2024-08-27 citations by CoLab: 1 Abstract  
Biobased menthyl, thymyl, and carvacryl glycidyl ethers were copolymerized with CO2, leading to molar masses up to 60 kg mol−1 with Tg values ranging from 0 to 58 °C. The polymers degrade under basic conditions, affording diols and CO2 for recycling.
American Chemical Society (ACS)
Synergic Catalysis: the Importance of Intermetallic Separation in Co(III)K(I) Catalysts for Ring Opening Copolymerizations
Fiorentini F., Eisenhardt K.H., Deacy A.C., Williams C.K.
Journal of the American Chemical Society scimago Q1 wos Q1
2024-08-09 citations by CoLab: 7
American Chemical Society (ACS)
Quantifying CO2 Insertion Equilibria for Low-Pressure Propene Oxide and Carbon Dioxide Ring Opening Copolymerization Catalysts
Eisenhardt K.H., Fiorentini F., Lindeboom W., Williams C.K.
Journal of the American Chemical Society scimago Q1 wos Q1
2024-04-08 citations by CoLab: 14

Top-30

Journals

10
20
30
40
50
60
Macromolecules
Macromolecules, 55, 11.48%
Journal of the American Chemical Society
Journal of the American Chemical Society, 35, 7.31%
Inorganic Chemistry
Inorganic Chemistry, 29, 6.05%
Journal of Polymer Science, Part A: Polymer Chemistry
Journal of Polymer Science, Part A: Polymer Chemistry, 21, 4.38%
Polymer Chemistry
Polymer Chemistry, 19, 3.97%
Dalton Transactions
Dalton Transactions, 18, 3.76%
Angewandte Chemie
Angewandte Chemie, 14, 2.92%
Angewandte Chemie - International Edition
Angewandte Chemie - International Edition, 14, 2.92%
Macromolecular Rapid Communications
Macromolecular Rapid Communications, 8, 1.67%
Organometallics
Organometallics, 8, 1.67%
ChemCatChem
ChemCatChem, 7, 1.46%
Chemical Communications
Chemical Communications, 7, 1.46%
Chemical Reviews
Chemical Reviews, 6, 1.25%
Chemistry - A European Journal
Chemistry - A European Journal, 6, 1.25%
Journal of Applied Polymer Science
Journal of Applied Polymer Science, 6, 1.25%
Green Chemistry
Green Chemistry, 6, 1.25%
Catalysis Science and Technology
Catalysis Science and Technology, 6, 1.25%
Inorganica Chimica Acta
Inorganica Chimica Acta, 5, 1.04%
Polymer
Polymer, 5, 1.04%
ChemSusChem
ChemSusChem, 5, 1.04%
Journal of the Chinese Chemical Society
Journal of the Chinese Chemical Society, 5, 1.04%
ACS Catalysis
ACS Catalysis, 5, 1.04%
Chinese Journal of Polymer Science (English Edition)
Chinese Journal of Polymer Science (English Edition), 4, 0.84%
Acta Polymerica Sinica, 4, 0.84%
Coordination Chemistry Reviews
Coordination Chemistry Reviews, 4, 0.84%
Polyhedron
Polyhedron, 4, 0.84%
European Journal of Inorganic Chemistry
European Journal of Inorganic Chemistry, 4, 0.84%
Macromolecular Chemistry and Physics
Macromolecular Chemistry and Physics, 4, 0.84%
Applied Organometallic Chemistry
Applied Organometallic Chemistry, 4, 0.84%
10
20
30
40
50
60

Publishers

20
40
60
80
100
120
140
160
American Chemical Society (ACS)
American Chemical Society (ACS), 153, 31.94%
Wiley
Wiley, 123, 25.68%
Royal Society of Chemistry (RSC)
Royal Society of Chemistry (RSC), 74, 15.45%
Elsevier
Elsevier, 54, 11.27%
Springer Nature
Springer Nature, 31, 6.47%
MDPI
MDPI, 6, 1.25%
Oxford University Press
Oxford University Press, 4, 0.84%
China Science Publishing & Media, 4, 0.84%
Taylor & Francis
Taylor & Francis, 4, 0.84%
Pleiades Publishing
Pleiades Publishing, 3, 0.63%
Beilstein-Institut
Beilstein-Institut, 1, 0.21%
AIP Publishing
AIP Publishing, 1, 0.21%
ASME International
ASME International, 1, 0.21%
The Royal Society
The Royal Society, 1, 0.21%
SAGE
SAGE, 1, 0.21%
Wuhan University of Technology
Wuhan University of Technology, 1, 0.21%
Chinese Society of Rare Earths
Chinese Society of Rare Earths, 1, 0.21%
IOP Publishing
IOP Publishing, 1, 0.21%
Frontiers Media S.A.
Frontiers Media S.A., 1, 0.21%
Trans Tech Publications
Trans Tech Publications, 1, 0.21%
Society of Polymer Science, Japan, 1, 0.21%
Proceedings of the National Academy of Sciences (PNAS)
Proceedings of the National Academy of Sciences (PNAS), 1, 0.21%
Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii
Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii, 1, 0.21%
OOO Zhurnal "Mendeleevskie Soobshcheniya", 1, 0.21%
20
40
60
80
100
120
140
160
  • We do not take into account publications without a DOI.
  • Statistics recalculated only for publications connected to researchers, organizations and labs registered on the platform.
  • Statistics recalculated weekly.

Are you a researcher?

Create a profile to get free access to personal recommendations for colleagues and new articles.
Share
Cite this
GOST | RIS | BibTex | MLA
Found error?