Conversion of biomass products to energy sources in the presence of nanocatalysts and membrane-catalyst systems View Full Text


Ontology type: schema:ScholarlyArticle     


Article Info

DATE

2011-03

AUTHORS

M. V. Tsodikov, A. V. Chistyakov, F. A. Yandieva, V. V. Zhmakin, A. E. Gekhman, I. I. Moiseev

ABSTRACT

A particular role in the harmonious exploitation of raw materials is assigned to organic sources of fuels based on renewable biomass. The most promising feedstocks of major energy sources, such as hydrogen and organic components of motor fuels, include ethanol and other bioalcohols, i.e., the primary products of its conversion. In this work, we describe the results for new reactions of conversion of ethanol and a mixture of ethanol and glycerol, which are the major products of biomass, to the C3–C10 alkane-olefin fraction in the presence of nanoscale mono- and bimetal-containing active components supported on γ-Al2O3 (〈d〉 = 5–8 nm) and on the inner surface of microchannels of ceramic membranes (〈d〉 = 15–20 nm). Mono- and bimetallic alkoxide and acetate complexes are used as precursors. It is found that the selectivity for the ethanol conversion to aliphatic hydrocarbons, as well as the content of branched structures, heavily depends on the nuclearity and composition of metal-complex precursors supported on γ-Al2O3. It is found for the first time that glycerol exhibits high reactionary ability in the reaction of cross-condensation of the carbon skeleton of alcohols of different nature. In the presence of a Ta-Re-containing system, a mixture of ethanol and glycerol is converted to 60% of C4–C10+ olefins, which contain up to 50% of branched structures. It is shown that by varying the composition of Pd-Zn-containing active components, it is possible to targetedly convert ethanol to the olefin, alkane, or alkane-olefin fraction. Porous membrane-catalyst systems are designed to produce hydrogen and syngas from biomass products; the systems exhibit high activity in the carbon dioxide and steam reforming of ethanol, a mixture of ethanol and glycerol, and acetic acid. A scheme for the production of a wide range of valuable organic products based on bioalcohols containing no toxic impurities and independent of crude oil is described. According to this scheme, alkanes derived from ethanol and other bioalcohols are the major components of motor fuels; a large number of organic synthesis products can be derived from olefins, hydrogen, and carbon monoxide in the carbonylation/hydrocarbonylation processes. More... »

PAGES

4-10

Identifiers

URI

http://scigraph.springernature.com/pub.10.1134/s2070050411010156

DOI

http://dx.doi.org/10.1134/s2070050411010156

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1012270293


Indexing Status Check whether this publication has been indexed by Scopus and Web Of Science using the SN Indexing Status Tool
Incoming Citations Browse incoming citations for this publication using opencitations.net

JSON-LD is the canonical representation for SciGraph data.

TIP: You can open this SciGraph record using an external JSON-LD service: JSON-LD Playground Google SDTT

[
  {
    "@context": "https://springernature.github.io/scigraph/jsonld/sgcontext.json", 
    "about": [
      {
        "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/0306", 
        "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
        "name": "Physical Chemistry (incl. Structural)", 
        "type": "DefinedTerm"
      }, 
      {
        "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/03", 
        "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
        "name": "Chemical Sciences", 
        "type": "DefinedTerm"
      }
    ], 
    "author": [
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Topchiev Institute of Petrochemical Synthesis, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Tsodikov", 
        "givenName": "M. V.", 
        "id": "sg:person.015045563603.02", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.015045563603.02"
        ], 
        "type": "Person"
      }, 
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Topchiev Institute of Petrochemical Synthesis, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Chistyakov", 
        "givenName": "A. V.", 
        "id": "sg:person.013263727151.12", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.013263727151.12"
        ], 
        "type": "Person"
      }, 
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Topchiev Institute of Petrochemical Synthesis, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Yandieva", 
        "givenName": "F. A.", 
        "id": "sg:person.0730161327.03", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.0730161327.03"
        ], 
        "type": "Person"
      }, 
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Topchiev Institute of Petrochemical Synthesis, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Zhmakin", 
        "givenName": "V. V.", 
        "id": "sg:person.015067272473.16", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.015067272473.16"
        ], 
        "type": "Person"
      }, 
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Gekhman", 
        "givenName": "A. E.", 
        "id": "sg:person.07417600445.48", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.07417600445.48"
        ], 
        "type": "Person"
      }, 
      {
        "affiliation": {
          "alternateName": "Russian Academy of Sciences", 
          "id": "https://www.grid.ac/institutes/grid.4886.2", 
          "name": [
            "Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 119991, Moscow, Russia"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Moiseev", 
        "givenName": "I. I.", 
        "id": "sg:person.07505356441.41", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.07505356441.41"
        ], 
        "type": "Person"
      }
    ], 
    "citation": [
      {
        "id": "https://doi.org/10.1016/j.cattod.2006.08.009", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1004638616"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1016/j.ica.2006.01.027", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1004678905"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "sg:pub.10.1007/s10562-007-9347-7", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1017348003", 
          "https://doi.org/10.1007/s10562-007-9347-7"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "sg:pub.10.1007/s10562-007-9347-7", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1017348003", 
          "https://doi.org/10.1007/s10562-007-9347-7"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1016/0304-3991(87)90080-5", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1023624137"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1016/0304-3991(87)90080-5", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1023624137"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "sg:pub.10.1134/s0023158408010151", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1028698971", 
          "https://doi.org/10.1134/s0023158408010151"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1351/pac200476091769", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1033884747"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1016/j.jcat.2005.06.018", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1035485365"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "sg:pub.10.1134/s0023158410040142", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1047876057", 
          "https://doi.org/10.1134/s0023158410040142"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "sg:pub.10.1134/s0023158410040142", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1047876057", 
          "https://doi.org/10.1134/s0023158410040142"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1021/cm011726c", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1055409036"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1021/cm011726c", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1055409036"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1126/science.1176745", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1062460370"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1126/science.1176745", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1062460370"
        ], 
        "type": "CreativeWork"
      }, 
      {
        "id": "https://doi.org/10.1126/science.324_587", 
        "sameAs": [
          "https://app.dimensions.ai/details/publication/pub.1062601626"
        ], 
        "type": "CreativeWork"
      }
    ], 
    "datePublished": "2011-03", 
    "datePublishedReg": "2011-03-01", 
    "description": "A particular role in the harmonious exploitation of raw materials is assigned to organic sources of fuels based on renewable biomass. The most promising feedstocks of major energy sources, such as hydrogen and organic components of motor fuels, include ethanol and other bioalcohols, i.e., the primary products of its conversion. In this work, we describe the results for new reactions of conversion of ethanol and a mixture of ethanol and glycerol, which are the major products of biomass, to the C3\u2013C10 alkane-olefin fraction in the presence of nanoscale mono- and bimetal-containing active components supported on \u03b3-Al2O3 (\u3008d\u3009 = 5\u20138 nm) and on the inner surface of microchannels of ceramic membranes (\u3008d\u3009 = 15\u201320 nm). Mono- and bimetallic alkoxide and acetate complexes are used as precursors. It is found that the selectivity for the ethanol conversion to aliphatic hydrocarbons, as well as the content of branched structures, heavily depends on the nuclearity and composition of metal-complex precursors supported on \u03b3-Al2O3. It is found for the first time that glycerol exhibits high reactionary ability in the reaction of cross-condensation of the carbon skeleton of alcohols of different nature. In the presence of a Ta-Re-containing system, a mixture of ethanol and glycerol is converted to 60% of C4\u2013C10+ olefins, which contain up to 50% of branched structures. It is shown that by varying the composition of Pd-Zn-containing active components, it is possible to targetedly convert ethanol to the olefin, alkane, or alkane-olefin fraction. Porous membrane-catalyst systems are designed to produce hydrogen and syngas from biomass products; the systems exhibit high activity in the carbon dioxide and steam reforming of ethanol, a mixture of ethanol and glycerol, and acetic acid. A scheme for the production of a wide range of valuable organic products based on bioalcohols containing no toxic impurities and independent of crude oil is described. According to this scheme, alkanes derived from ethanol and other bioalcohols are the major components of motor fuels; a large number of organic synthesis products can be derived from olefins, hydrogen, and carbon monoxide in the carbonylation/hydrocarbonylation processes.", 
    "genre": "research_article", 
    "id": "sg:pub.10.1134/s2070050411010156", 
    "inLanguage": [
      "en"
    ], 
    "isAccessibleForFree": false, 
    "isPartOf": [
      {
        "id": "sg:journal.1048926", 
        "issn": [
          "2070-0504", 
          "2070-0555"
        ], 
        "name": "Catalysis in Industry", 
        "type": "Periodical"
      }, 
      {
        "issueNumber": "1", 
        "type": "PublicationIssue"
      }, 
      {
        "type": "PublicationVolume", 
        "volumeNumber": "3"
      }
    ], 
    "name": "Conversion of biomass products to energy sources in the presence of nanocatalysts and membrane-catalyst systems", 
    "pagination": "4-10", 
    "productId": [
      {
        "name": "readcube_id", 
        "type": "PropertyValue", 
        "value": [
          "3a75a131859e48af8423d96160bb603dd34998432831b436eb07b574f5f5a39b"
        ]
      }, 
      {
        "name": "doi", 
        "type": "PropertyValue", 
        "value": [
          "10.1134/s2070050411010156"
        ]
      }, 
      {
        "name": "dimensions_id", 
        "type": "PropertyValue", 
        "value": [
          "pub.1012270293"
        ]
      }
    ], 
    "sameAs": [
      "https://doi.org/10.1134/s2070050411010156", 
      "https://app.dimensions.ai/details/publication/pub.1012270293"
    ], 
    "sdDataset": "articles", 
    "sdDatePublished": "2019-04-10T19:55", 
    "sdLicense": "https://scigraph.springernature.com/explorer/license/", 
    "sdPublisher": {
      "name": "Springer Nature - SN SciGraph project", 
      "type": "Organization"
    }, 
    "sdSource": "s3://com-uberresearch-data-dimensions-target-20181106-alternative/cleanup/v134/2549eaecd7973599484d7c17b260dba0a4ecb94b/merge/v9/a6c9fde33151104705d4d7ff012ea9563521a3ce/jats-lookup/v90/0000000001_0000000264/records_8681_00000504.jsonl", 
    "type": "ScholarlyArticle", 
    "url": "http://link.springer.com/10.1134%2FS2070050411010156"
  }
]
 

Download the RDF metadata as:  json-ld nt turtle xml License info

HOW TO GET THIS DATA PROGRAMMATICALLY:

JSON-LD is a popular format for linked data which is fully compatible with JSON.

curl -H 'Accept: application/ld+json' 'https://scigraph.springernature.com/pub.10.1134/s2070050411010156'

N-Triples is a line-based linked data format ideal for batch operations.

curl -H 'Accept: application/n-triples' 'https://scigraph.springernature.com/pub.10.1134/s2070050411010156'

Turtle is a human-readable linked data format.

curl -H 'Accept: text/turtle' 'https://scigraph.springernature.com/pub.10.1134/s2070050411010156'

RDF/XML is a standard XML format for linked data.

curl -H 'Accept: application/rdf+xml' 'https://scigraph.springernature.com/pub.10.1134/s2070050411010156'


 

This table displays all metadata directly associated to this object as RDF triples.

133 TRIPLES      21 PREDICATES      38 URIs      19 LITERALS      7 BLANK NODES

Subject Predicate Object
1 sg:pub.10.1134/s2070050411010156 schema:about anzsrc-for:03
2 anzsrc-for:0306
3 schema:author N97befc6011124bffa14a313e84f3a10a
4 schema:citation sg:pub.10.1007/s10562-007-9347-7
5 sg:pub.10.1134/s0023158408010151
6 sg:pub.10.1134/s0023158410040142
7 https://doi.org/10.1016/0304-3991(87)90080-5
8 https://doi.org/10.1016/j.cattod.2006.08.009
9 https://doi.org/10.1016/j.ica.2006.01.027
10 https://doi.org/10.1016/j.jcat.2005.06.018
11 https://doi.org/10.1021/cm011726c
12 https://doi.org/10.1126/science.1176745
13 https://doi.org/10.1126/science.324_587
14 https://doi.org/10.1351/pac200476091769
15 schema:datePublished 2011-03
16 schema:datePublishedReg 2011-03-01
17 schema:description A particular role in the harmonious exploitation of raw materials is assigned to organic sources of fuels based on renewable biomass. The most promising feedstocks of major energy sources, such as hydrogen and organic components of motor fuels, include ethanol and other bioalcohols, i.e., the primary products of its conversion. In this work, we describe the results for new reactions of conversion of ethanol and a mixture of ethanol and glycerol, which are the major products of biomass, to the C3–C10 alkane-olefin fraction in the presence of nanoscale mono- and bimetal-containing active components supported on γ-Al2O3 (〈d〉 = 5–8 nm) and on the inner surface of microchannels of ceramic membranes (〈d〉 = 15–20 nm). Mono- and bimetallic alkoxide and acetate complexes are used as precursors. It is found that the selectivity for the ethanol conversion to aliphatic hydrocarbons, as well as the content of branched structures, heavily depends on the nuclearity and composition of metal-complex precursors supported on γ-Al2O3. It is found for the first time that glycerol exhibits high reactionary ability in the reaction of cross-condensation of the carbon skeleton of alcohols of different nature. In the presence of a Ta-Re-containing system, a mixture of ethanol and glycerol is converted to 60% of C4–C10+ olefins, which contain up to 50% of branched structures. It is shown that by varying the composition of Pd-Zn-containing active components, it is possible to targetedly convert ethanol to the olefin, alkane, or alkane-olefin fraction. Porous membrane-catalyst systems are designed to produce hydrogen and syngas from biomass products; the systems exhibit high activity in the carbon dioxide and steam reforming of ethanol, a mixture of ethanol and glycerol, and acetic acid. A scheme for the production of a wide range of valuable organic products based on bioalcohols containing no toxic impurities and independent of crude oil is described. According to this scheme, alkanes derived from ethanol and other bioalcohols are the major components of motor fuels; a large number of organic synthesis products can be derived from olefins, hydrogen, and carbon monoxide in the carbonylation/hydrocarbonylation processes.
18 schema:genre research_article
19 schema:inLanguage en
20 schema:isAccessibleForFree false
21 schema:isPartOf N03c3708dbafe4a458cfb89212c02438b
22 N9b0b087ca9c341a9aa53df7b76245220
23 sg:journal.1048926
24 schema:name Conversion of biomass products to energy sources in the presence of nanocatalysts and membrane-catalyst systems
25 schema:pagination 4-10
26 schema:productId N4a1419a0cdff46a081b2c4cbf45812f2
27 Nae1b06b98cce4fbe95feaf598ba74618
28 Nfb2f8cb27252460693527972306b365c
29 schema:sameAs https://app.dimensions.ai/details/publication/pub.1012270293
30 https://doi.org/10.1134/s2070050411010156
31 schema:sdDatePublished 2019-04-10T19:55
32 schema:sdLicense https://scigraph.springernature.com/explorer/license/
33 schema:sdPublisher N33c4830024ad41978bf645e8b7fb98b5
34 schema:url http://link.springer.com/10.1134%2FS2070050411010156
35 sgo:license sg:explorer/license/
36 sgo:sdDataset articles
37 rdf:type schema:ScholarlyArticle
38 N03c3708dbafe4a458cfb89212c02438b schema:issueNumber 1
39 rdf:type schema:PublicationIssue
40 N071c972d11f541258043f82d55b57a43 rdf:first sg:person.07505356441.41
41 rdf:rest rdf:nil
42 N0a6ca688965d446fb747fb8d81e2fd53 rdf:first sg:person.0730161327.03
43 rdf:rest N85f6a7264a1246b688d5de750f20830e
44 N33c4830024ad41978bf645e8b7fb98b5 schema:name Springer Nature - SN SciGraph project
45 rdf:type schema:Organization
46 N4a1419a0cdff46a081b2c4cbf45812f2 schema:name dimensions_id
47 schema:value pub.1012270293
48 rdf:type schema:PropertyValue
49 N85f6a7264a1246b688d5de750f20830e rdf:first sg:person.015067272473.16
50 rdf:rest Nd1099321152e4d84943762ccbddd6154
51 N97befc6011124bffa14a313e84f3a10a rdf:first sg:person.015045563603.02
52 rdf:rest Ne24c3ecf47e1462782c037f34c998fd3
53 N9b0b087ca9c341a9aa53df7b76245220 schema:volumeNumber 3
54 rdf:type schema:PublicationVolume
55 Nae1b06b98cce4fbe95feaf598ba74618 schema:name readcube_id
56 schema:value 3a75a131859e48af8423d96160bb603dd34998432831b436eb07b574f5f5a39b
57 rdf:type schema:PropertyValue
58 Nd1099321152e4d84943762ccbddd6154 rdf:first sg:person.07417600445.48
59 rdf:rest N071c972d11f541258043f82d55b57a43
60 Ne24c3ecf47e1462782c037f34c998fd3 rdf:first sg:person.013263727151.12
61 rdf:rest N0a6ca688965d446fb747fb8d81e2fd53
62 Nfb2f8cb27252460693527972306b365c schema:name doi
63 schema:value 10.1134/s2070050411010156
64 rdf:type schema:PropertyValue
65 anzsrc-for:03 schema:inDefinedTermSet anzsrc-for:
66 schema:name Chemical Sciences
67 rdf:type schema:DefinedTerm
68 anzsrc-for:0306 schema:inDefinedTermSet anzsrc-for:
69 schema:name Physical Chemistry (incl. Structural)
70 rdf:type schema:DefinedTerm
71 sg:journal.1048926 schema:issn 2070-0504
72 2070-0555
73 schema:name Catalysis in Industry
74 rdf:type schema:Periodical
75 sg:person.013263727151.12 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
76 schema:familyName Chistyakov
77 schema:givenName A. V.
78 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.013263727151.12
79 rdf:type schema:Person
80 sg:person.015045563603.02 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
81 schema:familyName Tsodikov
82 schema:givenName M. V.
83 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.015045563603.02
84 rdf:type schema:Person
85 sg:person.015067272473.16 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
86 schema:familyName Zhmakin
87 schema:givenName V. V.
88 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.015067272473.16
89 rdf:type schema:Person
90 sg:person.0730161327.03 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
91 schema:familyName Yandieva
92 schema:givenName F. A.
93 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.0730161327.03
94 rdf:type schema:Person
95 sg:person.07417600445.48 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
96 schema:familyName Gekhman
97 schema:givenName A. E.
98 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.07417600445.48
99 rdf:type schema:Person
100 sg:person.07505356441.41 schema:affiliation https://www.grid.ac/institutes/grid.4886.2
101 schema:familyName Moiseev
102 schema:givenName I. I.
103 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.07505356441.41
104 rdf:type schema:Person
105 sg:pub.10.1007/s10562-007-9347-7 schema:sameAs https://app.dimensions.ai/details/publication/pub.1017348003
106 https://doi.org/10.1007/s10562-007-9347-7
107 rdf:type schema:CreativeWork
108 sg:pub.10.1134/s0023158408010151 schema:sameAs https://app.dimensions.ai/details/publication/pub.1028698971
109 https://doi.org/10.1134/s0023158408010151
110 rdf:type schema:CreativeWork
111 sg:pub.10.1134/s0023158410040142 schema:sameAs https://app.dimensions.ai/details/publication/pub.1047876057
112 https://doi.org/10.1134/s0023158410040142
113 rdf:type schema:CreativeWork
114 https://doi.org/10.1016/0304-3991(87)90080-5 schema:sameAs https://app.dimensions.ai/details/publication/pub.1023624137
115 rdf:type schema:CreativeWork
116 https://doi.org/10.1016/j.cattod.2006.08.009 schema:sameAs https://app.dimensions.ai/details/publication/pub.1004638616
117 rdf:type schema:CreativeWork
118 https://doi.org/10.1016/j.ica.2006.01.027 schema:sameAs https://app.dimensions.ai/details/publication/pub.1004678905
119 rdf:type schema:CreativeWork
120 https://doi.org/10.1016/j.jcat.2005.06.018 schema:sameAs https://app.dimensions.ai/details/publication/pub.1035485365
121 rdf:type schema:CreativeWork
122 https://doi.org/10.1021/cm011726c schema:sameAs https://app.dimensions.ai/details/publication/pub.1055409036
123 rdf:type schema:CreativeWork
124 https://doi.org/10.1126/science.1176745 schema:sameAs https://app.dimensions.ai/details/publication/pub.1062460370
125 rdf:type schema:CreativeWork
126 https://doi.org/10.1126/science.324_587 schema:sameAs https://app.dimensions.ai/details/publication/pub.1062601626
127 rdf:type schema:CreativeWork
128 https://doi.org/10.1351/pac200476091769 schema:sameAs https://app.dimensions.ai/details/publication/pub.1033884747
129 rdf:type schema:CreativeWork
130 https://www.grid.ac/institutes/grid.4886.2 schema:alternateName Russian Academy of Sciences
131 schema:name Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 119991, Moscow, Russia
132 Topchiev Institute of Petrochemical Synthesis, Russian Academy of Sciences, 119991, Moscow, Russia
133 rdf:type schema:Organization
 




Preview window. Press ESC to close (or click here)


...