Jump to ContentJump to Main Navigation
Show Summary Details
More options …

Pure and Applied Chemistry

The Scientific Journal of IUPAC

Ed. by Burrows, Hugh / Stohner, Jürgen

12 Issues per year


IMPACT FACTOR 2017: 5.294

CiteScore 2017: 3.42

SCImago Journal Rank (SJR) 2017: 1.212
Source Normalized Impact per Paper (SNIP) 2017: 1.546

Online
ISSN
1365-3075
See all formats and pricing
More options …
Volume 79, Issue 11

Issues

Green photochemistry: Production of fine chemicals with sunlight

Michael Oelgemöller
  • Corresponding author
  • School of Chemical Sciences and National Institute for Cellular Biotechnology, Dublin City University, Dublin 9, Ireland
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
/ Christian Jung
  • Corresponding author
  • German Aerospace Center (DLR), Solarforschung, Linder Höhe, D-51147 Cologne, Germany
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
/ Jochen Mattay
  • Corresponding author
  • Organic Chemistry I, Department of Chemistry, University of Bielefeld, P.O. Box 10 01 31, D-33501 Bielefeld, Germany
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
Published Online: 2009-01-01 | DOI: https://doi.org/10.1351/pac200779111939

Three photochemical reactions were investigated under solar irradiation conditions with moderately concentrated sunlight: the photoacylation of naphthoquinone with butyraldehyde and the dye-sensitized photooxygenations of citronellol and 1,5-dihydroxynaphthalene, respectively. All reactions were easily performed on multigram-to-kilogram scales using cheap and commercially available starting materials, and yielded important key intermediates for industrial applications.

Keywords: green chemistry; photoacylation; photochemistry; photooxygenation; solar chemistry

Conference

International IUPAC Conference on Green-Sustainable Chemistry, IUPAC International Conference on Green Chemistry, ICGC, Green Chemistry , 1st, Dresden, Germany, 2006-09-10–2006-09-15

References

  • 1. (a)

    P. Tundo, P. Anastas, D. StC. Black, J. Breen, T. Collins, S. Memoli, J. Miyamoto, M.Polyakoff, W. Tumas. Pure Appl. Chem. 72, 1207 (2000);Google Scholar

  • 1. (b)

    P. T. Anastas, J. C. Wagner. Green Chemistry: Theory and Practice, Oxford University Press, Oxford (1998).Google Scholar

  • 2. (a)

    , A. Albini, M. Fagnoni. Green Chem. 6, 1 (2004);CrossrefGoogle Scholar

  • 2. (b)

    , J. Mattay. Chem. Unserer Zeit 36, 98 (2002);CrossrefGoogle Scholar

  • 2. (c)

    , A. Albini, M. Fagnoni, M. Mella. Pure Appl. Chem. 72, 1321 (2000);CrossrefGoogle Scholar

  • 2. (d)

    , A. G. Griesbeck, W. Kramer, M. Oelgemoller. Green Chem. 1, 205 (1999).CrossrefGoogle Scholar

  • 3. (a)

    B. Pohlmann, H.-D. Scharf, U. Jarolimek, P. Mauermann. Sol. Energy 61, 159 (1997);Google Scholar

  • 3. (b)

    , P.Esser, B. Pohlmann, H.-D. Scharf. Angew. Chem., Int. Ed. 33, 2009 (1994).CrossrefGoogle Scholar

  • 4. (a)

    , H. D. Roth. Pure Appl. Chem. 73, 395 (2001);CrossrefGoogle Scholar

  • 4. (b)

    , H. D. Roth. Angew. Chem., Int. Ed. 28, 1193 (1989).CrossrefGoogle Scholar

  • 5. (a)

    S. Malato, J. Blanco, A. Vidal, C. Richter. Appl. Catal., B 37, 1 (2002);CrossrefGoogle Scholar

  • 5. (b)

    K.-H. Funken, J. Ortner. Z. Phys. Chem. 213, 99 (1999).Google Scholar

  • 6. (a)

    M. Oelgemoller, C. Jung, J. Ortner, M. Mattay, C. Schiel, E. Zimmermann. The Spectrum 18, 28 (2005);Google Scholar

  • 6. (b)

    M. Oelgemoller, C. Jung, J. Ortner, J. Mattay, C. Schiel, E. Zimmermann. In Proc., 2004 International Solar Energy Conference - Portland, USA, ISEC 2004-65021. ASME, Boulder, CO (2004) (CD-ROM);Google Scholar

  • 6. (c)

    B. Pohlmann, H.-D. Scharf, U. Jarolimek, P. Mauermann. Sol. Energy 61, 159 (1997);Google Scholar

  • 6. (d)

    , P. Esser, B. Pohlmann, H.-D. Scharf. Angew. Chem., Int. Ed. 33, 2009 (1994).CrossrefGoogle Scholar

  • 7.

    K.-H. Funken, M. Becker. Renew. Energy 24, 469 (2001).Google Scholar

  • 8.

    , C. Jung, K.-H. Funken, J. Ortner. Photochem. Photobiol. Sci. 3, 409 (2005).CrossrefGoogle Scholar

  • 9.

    Calculated using SEDES for Windows: T. Walsch, K.-J. Riffelmann. SEDES for Windows, Version 2.5, DLR, Koln (1997).Google Scholar

  • 10.

    M. Oelgemoller, J. Mattay. In CRC Handbook of Organic Photochemistry and Photobiology, 2nd ed., W. M. Horspool, F. Lenci (Eds.), Chap. 88, pp. 1-45, CRC Press, Boca Raton, FL (2004) and refs. therein.Google Scholar

  • 11. (a)

    , H. Klinger, O. Standke. Ber. Dtsch. Chem. Ges. 24, 1340 (1891);CrossrefGoogle Scholar

  • 11. (b)

    , H. Klinger, W.Kolvenbach. Ber. Dtsch. Chem. Ges. 31, 1214 (1898).CrossrefGoogle Scholar

  • 12. (a)

    , P. A. Waske, J. Mattay, M. Oelgemoller. Tetrahedron Lett. 47, 1329 (2006);CrossrefGoogle Scholar

  • 12. (b)

    , M.Oelgemoller, C. Schiel, J. Mattay, R. Frohlich. Eur. J. Org. Chem. 2465 (2002);CrossrefGoogle Scholar

  • 12. (c)

    , C. Schiel, M. Oelgemoller, J. Mattay. Synthesis 1275 (2001);CrossrefGoogle Scholar

  • 12. (d)

    C. Schiel, M. Oelgemoller, J. Mattay. J. Inf. Rec. 24, 257 (1998).Google Scholar

  • 13. (a)

    , C. Schiel, M. Oelgemoller, J. Ortner, J. Mattay. Green Chem. 3, 224 (2001);CrossrefGoogle Scholar

  • 13. (b)

    M.Oelgemoller, C. Schiel, J. Ortner, J. Mattay. In AG Solar Nordrhein-Westfalen - Solare Chemie und Solare Materialforschung, Chap. 2.2, AG-Solar NRW, Julich (2002) (CD-ROM).Google Scholar

  • 14. (a)

    W. Rojahn, H.-U. Warnecke. DRAGOCO-Report 27, 159 (1980);Google Scholar

  • 14. (b)

    , G. Ohloff, E. Klein, G.O. Schenck. Angew. Chem. 73, 578 (1961).CrossrefGoogle Scholar

  • 15.

    , N. Monnerie, J. Ortner. J. Sol. Energy Eng. 123, 171 (2001).CrossrefGoogle Scholar

  • 16. (a)

    J. I. Ajona, A. Vidal. Sol. Energy 68, 109 (2000);Google Scholar

  • 16. (b)

    J. Blanco, S. Malato, P. Fernandez, A.Vidal, A. Morales, P. Trincado, J. C. Oliveira, C. Minero, M. Musci, C. Casalle, M. Brunotte, S. Tratzky, N. Dischinger, K.-H. Funken, C. Sattler, M. Vincent, M. Collares-Pereira, J. F. Mendes, C. M. Rangel. Sol. Energy 67, 317 (1999).Google Scholar

  • 17. (a)

    , C. Heinemann, X. Xing, K.-D. Warzecha, P. Ritterskamp, H. Gorner, M. Demuth. Pure Appl. Chem. 70, 2167 (1998);CrossrefGoogle Scholar

  • 17. (b)

    M. Demuth, A. Ritter. WO patent 99/54032 (1999).Google Scholar

  • 18. (a)

    , M. Oelgemoller, N. Healy, L. de Oliveria, C. Jung, M. Mattay. Green Chem. 8, 831 (2006);CrossrefGoogle Scholar

  • 18. (b)

    , M. Oelgemoller, C. Jung, J. Ortner, M. Mattay, E. Zimmermann. Green Chem. 7, 35 (2005).CrossrefGoogle Scholar

  • 19. (a)

    , D. J. Crouse, M. M. Wheeler, M.Goemann, P. S. Tobin, S. K. Basu, D. M. S. Wheeler. J. Org. Chem. 46, 1814 (1981);CrossrefGoogle Scholar

  • 19. (b)

    , C.Grundmann. Synthesis 644 (1977).CrossrefGoogle Scholar

  • 20. (a)

    , O. Suchard, R. Kane, B. J. Roe, E. Zimmermann, C. Jung, P. A. Waske, J. Mattay, M.Oelgemoller. Tetrahedron 62, 1467 (2006);CrossrefGoogle Scholar

  • 20. (b)

    D. Murtinho, M. Pineiro, M. M. Pereira, A. M. d'A. Rocha Gonsalves, L. G. Arnaut, M. da Graca Miguel, H. D. Burrows. J. Chem. Soc., Perkin Trans. 2 2441 (2000);CrossrefGoogle Scholar

  • 20. (c)

    S. Croux, M.-T. Maurette, M. Hocquaux, A. Ananides, A. M. Braun, E.Oliveros. New J. Chem. 14, 161 (1990);Google Scholar

  • 20. (d)

    , G. Wurm, U. Geres. Arch. Pharm. (Weinheim) 318, 931 (1985);CrossrefGoogle Scholar

  • 20. (e)

    , H.-J. Durchstein, G. Wurm. Arch. Pharm. (Weinheim) 317, 809 (1984);CrossrefGoogle Scholar

  • 20. (f)

    J.Griffiths, K.-Y. Chu, C. Hawkins. J. Chem. Soc., Chem. Comm. 676 (1976).CrossrefGoogle Scholar

  • 21.

    J. Ortner, D. Faust, K.-H. Funken, T. Lindner, J. Schulat, C. G. Stojanoff, P. J. Froning. Phys. IV (France) 9, Pr3-379 (1999).Google Scholar

  • 22. (a)

    , B. Paczkowska, J. Paczkowski, D. C. Neckers. Macromolecules 19, 863 (1986);CrossrefGoogle Scholar

  • 22. (b)

    , A. P. Schapp, A. L. Thayer, E. C. Blossey, D. C. Neckers. J. Am. Chem. Soc. 97, 3741 (1975);CrossrefGoogle Scholar

  • 22. (c)

    , E.C. Blossey, D. C. Neckers, A. L. Thayer, A. P. Schapp. J. Am. Chem. Soc. 95, 5820 (1973).CrossrefGoogle Scholar

  • 23.

    , J. R. Williams, G. Orton, L. R. Unger. Tetrahedron Lett. 14, 4603 (1973).CrossrefGoogle Scholar

  • 24. (a)

    , A. Itoh, S. Hashimoto, K. Kuwabara, T. Kodama, Y. Masaki. Green Chem. 7, 830 (2005);CrossrefGoogle Scholar

  • 24. (b)

    , R. A. Doohan, N. W. A. Geragthy. Green Chem. 7, 91 (2005);CrossrefGoogle Scholar

  • 24. (c)

    , J.-T. Li, J.-H. Yang, J.-F. Han, T.-S. Li. Green Chem. 5, 433 (2003);CrossrefGoogle Scholar

  • 24. (d)

    , T. Ruther, A. M. Bond, W. R. Jackson. Green Chem. 5, 364 (2003).CrossrefGoogle Scholar

  • 25. (a)

    , K.-H. Funken, F.-J. Muller, J. Ortner, K.-J. Riffelmann, C. Sattler. Energy 24, 681 (1999);CrossrefGoogle Scholar

  • 25. (b)

    C. Sattler, F.-J. Muller, K.-J. Riffelmann, J. Ortner, K.-H. Funken. J. Phys. IV (France) 9, Pr3-723 (1999).Google Scholar

  • 26.

    , G. Ciamician. Science 36, 385 (1912).CrossrefGoogle Scholar

About the article

Published Online: 2009-01-01

Published in Print: 2007-01-01


Citation Information: Pure and Applied Chemistry, Volume 79, Issue 11, Pages 1939–1947, ISSN (Online) 1365-3075, ISSN (Print) 0033-4545, DOI: https://doi.org/10.1351/pac200779111939.

Export Citation

© 2013 Walter de Gruyter GmbH, Berlin/Boston.Get Permission

Citing Articles

Here you can find all Crossref-listed publications in which this article is cited. If you would like to receive automatic email messages as soon as this article is cited in other publications, simply activate the “Citation Alert” on the top of this page.

[1]
Wei Huang, Jeehye Byun, Irina Rörich, Charusheela Ramanan, Paul W. M. Blom, Hao Lu, Di Wang, Lucas Caire da Silva, Run Li, Lei Wang, Katharina Landfester, and Kai A. I. Zhang
Angewandte Chemie International Edition, 2018
[2]
Wei Huang, Jeehye Byun, Irina Rörich, Charusheela Ramanan, Paul W. M. Blom, Hao Lu, Di Wang, Lucas Caire da Silva, Run Li, Lei Wang, Katharina Landfester, and Kai A. I. Zhang
Angewandte Chemie, 2018
[3]
Robbie Radjagobalou, Jean-François Blanco, Odile Dechy-Cabaret, Michael Oelgemöller, and Karine Loubière
Chemical Engineering and Processing - Process Intensification, 2018
[4]
Geetmani Singh Nongthombam, George Kupar Kharmawlong, John Elisa Kumar, and Rishanlang Nongkhlaw
New Journal of Chemistry, 2018
[5]
Andrew M. R. Hall, Rachael Broomfield-Tagg, Matthew Camilleri, David R. Carbery, Anna Codina, David T. E. Whittaker, Steven Coombes, John P. Lowe, and Ulrich Hintermair
Chemical Communications, 2017
[6]
Rajaa Farran, Clémence Ducloiset, Julien Buendia, Nhat Tam Vo, Régis Guillot, Zakaria Halime, Philippe Dauban, Winfried Leibl, Marie Sircoglou, and Ally Aukauloo
ChemPhotoChem, 2017
[8]
Kateryna Bazaka, Jakaria Ahmad, Michael Oelgemöller, Ashraf Uddin, and Mohan V. Jacob
Scientific Reports, 2017, Volume 7, Page 45599
[9]
Erica N. DeLaney, Darren S. Lee, Luke D. Elliott, Jing Jin, Kevin I. Booker-Milburn, Martyn Poliakoff, and Michael W. George
Green Chem., 2017, Volume 19, Number 6, Page 1431
[10]
Heta A. Patel, Arun L. Patel, and Ashutosh V. Bedekar
New J. Chem., 2016, Volume 40, Number 10, Page 8935
[11]
Anthony Clay, Elango Kumarasamy, Anoklase J.-L. Ayitou, and Jayaraman Sivaguru
Chemistry Letters, 2014, Volume 43, Number 12, Page 1816
[12]
Katelyn Randazzo, Zhihan Wang, Zijun D. Wang, Jonathan Butz, and Qianli R. Chu
ACS Sustainable Chemistry & Engineering, 2016, Volume 4, Number 9, Page 5053
[13]
Michael Oelgemöller and Norbert Hoffmann
Org. Biomol. Chem., 2016, Volume 14, Number 31, Page 7392
[14]
Günther Knör
Coordination Chemistry Reviews, 2016, Volume 325, Page 102
[16]
Maxime Fréneau, Pascal de Sainte-Claire, Manabu Abe, and Norbert Hoffmann
Journal of Physical Organic Chemistry, 2016, Volume 29, Number 12, Page 718
[17]
Yasuharu Yoshimi, Akinori Nishio, Masae Hayashi, and Toshio Morita
Journal of Photochemistry and Photobiology A: Chemistry, 2016, Volume 331, Page 17
[18]
Dieter Wöhrle
Chemie in unserer Zeit, 2016, Volume 50, Number 4, Page 244
[19]
Seyed Saeed Mehrabi-Kalajahi, Mahdi Hajimohammadi, and Nasser Safari
Journal of the Iranian Chemical Society, 2016, Volume 13, Number 6, Page 1069
[20]
Saman Ghasimi, Katharina Landfester, and Kai A. I. Zhang
ChemCatChem, 2016, Volume 8, Number 4, Page 694
[21]
Sam Josland, Saira Mumtaz, and Michael Oelgemöller
Chemical Engineering & Technology, 2016, Volume 39, Number 1, Page 81
[22]
Zi Jun Wang, Saman Ghasimi, Katharina Landfester, and Kai A. I. Zhang
Advanced Materials, 2015, Volume 27, Number 40, Page 6265
[23]
Stefano Protti, Gianluca A. Artioli, Francesco Capitani, Carlo Marini, Paolo Dore, Paolo Postorino, Lorenzo Malavasi, and Maurizio Fagnoni
RSC Adv., 2015, Volume 5, Number 35, Page 27470
[24]
Richard Brimioulle, Dominik Lenhart, Mark M. Maturi, and Thorsten Bach
Angewandte Chemie International Edition, 2015, Volume 54, Number 13, Page 3872
[25]
Richard Brimioulle, Dominik Lenhart, Mark M. Maturi, and Thorsten Bach
Angewandte Chemie, 2015, Volume 127, Number 13, Page 3944
[26]
Norbert Hoffmann
Journal of Physical Organic Chemistry, 2015, Volume 28, Number 2, Page 121
[27]
Sumit Choudhury, Jin-Ook Baeg, No-Joong Park, and Rajesh K. Yadav
Green Chemistry, 2014, Volume 16, Number 9, Page 4389
[28]
Kerry Gilmore and Peter H. Seeberger
The Chemical Record, 2014, Volume 14, Number 3, Page 410
[29]
Michael Oelgemöller
Journal of the Chinese Chemical Society, 2014, Volume 61, Number 7, Page 743
[30]
Rafael Alonso and Thorsten Bach
Angewandte Chemie International Edition, 2014, Volume 53, Number 17, Page 4368
[31]
[32]
Jens Eberhard, Katrin Peuntinger, Susann Rath, Beate Neumann, Hans-Georg Stammler, Dirk M. Guldi, and Jochen Mattay
Photochemical & Photobiological Sciences, 2014, Volume 13, Number 2, Page 380
[33]
Emmanuel Arzoumanian, Filippo Ronzani, Aurélien Trivella, Esther Oliveros, Mohamed Sarakha, Claire Richard, Sylvie Blanc, Thierry Pigot, and Sylvie Lacombe
ACS Applied Materials & Interfaces, 2014, Volume 6, Number 1, Page 275
[34]
Milan Dinda, Supratim Chakraborty, Supravat Samanta, Chitrangi Bhatt, Subarna Maiti, Sandip Roy, Yogesh Kadam, and Pushpito K. Ghosh
Environmental Science & Technology, 2013, Page 130827153630005
[35]
Abdoulaye Gassama, Cédric Ernenwein, Ali Youssef, Mickaël Agach, Emmanuel Riguet, Siniša Marinković, Boris Estrine, and Norbert Hoffmann
Green Chemistry, 2013, Volume 15, Number 6, Page 1558
[36]
Michal Majek and Axel Jacobi von Wangelin
Chemical Communications, 2013, Volume 49, Number 48, Page 5507
[37]
Filippo Ronzani, Nathalie Costarramone, Sylvie Blanc, Abdelhamid Khalil Benabbou, Mickaël Le Bechec, Thierry Pigot, Michael Oelgemöller, and Sylvie Lacombe
Journal of Catalysis, 2013, Volume 303, Page 164
[38]
Fernando De Leon, Sudhakar Kalagara, Ashley A. Navarro, and Shizue Mito
Tetrahedron Letters, 2013, Volume 54, Number 24, Page 3147
[39]
[40]
Sónia Ribeiro, Arménio C. Serra, and António M. d' A. Rocha Gonsalves
ChemCatChem, 2013, Volume 5, Number 1, Page 134
[41]
Magnus Rueping, Carlos Vila, Anna Szadkowska, Rene M. Koenigs, and Jeanne Fronert
ACS Catalysis, 2012, Volume 2, Number 12, Page 2810
[42]
Norbert Hoffmann
Photochemical & Photobiological Sciences, 2012, Volume 11, Number 11, Page 1613
[43]
Sumit Choudhury, Jin-Ook Baeg, No-Joong Park, and Rajesh K. Yadav
Angewandte Chemie, 2012, Volume 124, Number 46, Page 11792
[44]
Sumit Choudhury, Jin-Ook Baeg, No-Joong Park, and Rajesh K. Yadav
Angewandte Chemie International Edition, 2012, Volume 51, Number 46, Page 11624
[45]
Zhan Lu and Tehshik P. Yoon
Angewandte Chemie, 2012, Volume 124, Number 41, Page 10475
[46]
Zhan Lu and Tehshik P. Yoon
Angewandte Chemie International Edition, 2012, Volume 51, Number 41, Page 10329
[47]
Alexander Yavorskyy, Oksana Shvydkiv, Norbert Hoffmann, Kieran Nolan, and Michael Oelgemöller
Organic Letters, 2012, Volume 14, Number 17, Page 4342
[48]
Shin Aida, Kimitada Terao, Yasuhiro Nishiyama, Kiyomi Kakiuchi, and Michael Oelgemöller
Tetrahedron Letters, 2012, Volume 53, Number 42, Page 5578
[49]
M. Consuelo Cuquerella, Inmaculada Andreu, Sonia Soldevila, and Francisco Bosca
The Journal of Physical Chemistry A, 2012, Volume 116, Number 21, Page 5030
[50]
Yusuke Yasu, Takashi Koike, and Munetaka Akita
Chemical Communications, 2012, Volume 48, Number 43, Page 5355
[51]
M. Oelgemoeller
Chemical Engineering & Technology, 2012, Volume 35, Number 7, Page 1144
[52]
Farhan R. Bou-Hamdan and Peter H. Seeberger
Chemical Science, 2012, Volume 3, Number 5, Page 1612
[53]
Alexander Yavorskyy, Oksana Shvydkiv, Carolin Limburg, Kieran Nolan, Yan M. C. Delauré, and Michael Oelgemöller
Green Chemistry, 2012, Volume 14, Number 4, Page 888
[55]
Alexander Yavorskyy, Oksana Shvydkiv, Kieran Nolan, Norbert Hoffmann, and Michael Oelgemöller
Tetrahedron Letters, 2011, Volume 52, Number 2, Page 278
[56]
Rabih Jahjah, Abdoulaye Gassama, Frédéric Dumur, Siniša Marinković, Sabine Richert, Stephan Landgraf, Aurélien Lebrun, Cyril Cadiou, Patrice Sellès, and Norbert Hoffmann
The Journal of Organic Chemistry, 2011, Volume 76, Number 17, Page 7104
[57]
Oksana Shvydkiv, Alexander Yavorskyy, Su Bee Tan, Kieran Nolan, Norbert Hoffmann, Ali Youssef, and Michael Oelgemöller
Photochemical & Photobiological Sciences, 2011, Volume 10, Number 9, Page 1399
[58]
M. Isabel Burguete, Raquel Gavara, Francisco Galindo, and Santiago V. Luis
Catalysis Communications, 2010, Volume 11, Number 13, Page 1081
[59]
Laura A. Anderson, Alison Redden, and Kevin D. Moeller
Green Chemistry, 2011, Volume 13, Number 7, Page 1652
[60]
Davide Ravelli, Stefano Protti, Paolo Neri, Maurizio Fagnoni, and Angelo Albini
Green Chemistry, 2011, Volume 13, Number 7, Page 1876
[61]
Panče Naumov, Yildiray Topcu, Mirjana Eckert-Maksić, Zoran Glasovac, Fabijan Pavošević, Manoj Kochunnoonny, and Hideyuki Hara
The Journal of Physical Chemistry A, 2011, Volume 115, Number 26, Page 7834
[62]
Yijin Su, Liangren Zhang, and Ning Jiao
Organic Letters, 2011, Volume 13, Number 9, Page 2168
[63]
Mahdi Hajimohammadi, Nasser Safari, Hamid Mofakham, and Farzad Deyhimi
Green Chemistry, 2011, Volume 13, Number 4, Page 991
[64]
Oksana Shvydkiv, Alexander Yavorskyy, Kieran Nolan, Ali Youssef, Emmanuel Riguet, Norbert Hoffmann, and Michael Oelgemöller
Photochemical & Photobiological Sciences, 2010, Volume 9, Number 12, Page 1601
[65]
Emma E. Coyle, Kieran Joyce, Kieran Nolan, and Michael Oelgemöller
Green Chemistry, 2010, Volume 12, Number 9, Page 1544
[66]
Tehshik P. Yoon, Michael A. Ischay, and Juana Du
Nature Chemistry, 2010, Volume 2, Number 7, Page 527
[67]
Hongjun Liu, Wei Feng, Choon Wee Kee, Yujun Zhao, Dasheng Leow, Yuanhang Pan, and Choon-Hong Tan
Green Chemistry, 2010, Volume 12, Number 6, Page 953
[68]
Abdoulaye Gassama, Cédric Ernenwein, and Norbert Hoffmann
ChemSusChem, 2009, Volume 2, Number 12, Page 1130
[69]
Stefano Protti, Davide Ravelli, Maurizio Fagnoni, and Angelo Albini
Chemical Communications, 2009, Number 47, Page 7351
[70]
Brian Murphy, Peter Goodrich, Christopher Hardacre, and Michael Oelgemöller
Green Chemistry, 2009, Volume 11, Number 11, Page 1867
[71]
Stefano Protti and Maurizio Fagnoni
Photochemical & Photobiological Sciences, 2009, Volume 8, Number 11, Page 1499
[72]
Daniele Dondi, Stefano Protti, Angelo Albini, Sonia Mañas Carpio, and Maurizio Fagnoni
Green Chemistry, 2009, Volume 11, Number 10, Page 1653
[73]
Evan S. Beach, Zheng Cui, and Paul T. Anastas
Energy & Environmental Science, 2009, Volume 2, Number 10, Page 1038
[74]
Philippe Saint-Cricq, Thierry Pigot, Lionel Nicole, Clément Sanchez, and Sylvie Lacombe
Chemical Communications, 2009, Number 35, Page 5281
[75]
Philipp Selig, Eberhardt Herdtweck, and Thorsten Bach
Chemistry - A European Journal, 2009, Volume 15, Number 14, Page 3509
[76]
Elodie Haggiage, Emma E. Coyle, Kieran Joyce, and Michael Oelgemöller
Green Chemistry, 2009, Volume 11, Number 3, Page 318
[77]
Stefano Protti, Daniele Dondi, Maurizio Fagnoni, and Angelo Albini
Green Chem., 2009, Volume 11, Number 2, Page 239
[78]
Emma E. Coyle and Michael Oelgemöller
Photochemical & Photobiological Sciences, 2008, Volume 7, Number 11, Page 1313
[79]
Yao-Peng Zhao, Roger O. Campbell, and Robert S. H. Liu
Green Chemistry, 2008, Volume 10, Number 10, Page 1038

Comments (0)

Please log in or register to comment.
Log in