Adriana Menghi
References :
Milieu, médium, matière
PLANCHE 1 - La structure du monde végétal
Gouvernement de la Nouvelle-Écosse, (année inconnue). Woodlot Management Home Study Program – Module 1: Introduction à la sylviculture. Leçon 3: identification et écologie forestière des feuillus. Consulté le 31 Mars 2021. https://woodlot.novascotia.ca/content/module-1-le%C3%A7-3-identification-et-%C3%A9cologie-foresti%C3%A8re-des-feuillus
Gouvernement de la Nouvelle-Écosse, (année inconnue). Woodlot Management Home Study Program – Module 1: Introduction à la sylviculture. Leçon 2: identification et écologie forestière des résineux. Consulté le 31 Mars 2021 https://woodlot.novascotia.ca/content/module-1-le%C3%A7-2-identification-et-%C3%A9cologie-foresti%C3%A8re-des-r%C3%A9sineux
Ministère de la Forêt, de la Faune et des Parcs du Québec (2000). Les produits et sous-produits du bois. Consulté le 30 Mars 2021. https://mffp.gouv.qc.ca/forets/echo-foret/octobre2000/savoir/produits.htm
Nishino, T., & Peijs, T. (2014). All-cellulose composites. HANDBOOK OF GREEN MATERIALS: 2 Bionanocomposites: processing, characterization and properties (pp. 201-216).
Klemm, D., Heublein, B., Fink, H-P., Bohn, A. (2005). Cellulose: Fascinating Biopolymer and Sustainable Raw Material. Angew. Chem. Int. Ed. 44 (22): 3358–93.
PLANCHE 2 - Moteur économique et culturel
Bégin, A., Schepper, B. (2020) Portrait de l’industrie forestière au Québec: une industrie qui a besoin de l’État. Institut de Recherche et d’Informations Socioéconomiques (IRIS), Montréal.
Berg, P., Lingqvist, O. (2019) Pulp, paper, and packaging in the next decade: transformational change. McKinsey & Company, Paper, Forest Products, and Packaging. Consulté le 18 Mars 2021. https://www.mckinsey.com/industries/paper-forest-products-and-packaging/our-insights/pulp-paper-and-packaging-in-the-next-decade-transformational-change#
Bogdanski Bryan E.C.. The rise and fall of the Canadian pulp and paper sector. The Forestry Chronicle. 90(06): 785-793.
European Environmental Paper Network (EEPN) (2015) Mapping Pulp Mill Expansion – Risks and Recommendations. Consulté le 27 Mars 2021. https://environmentalpaper.org/wp-content/uploads/2017/09/Mapping_Pulp_Mill_-Expansion.pdf
Food and Agriculture Organization of the United Nations (FAO) (2021). Forestry Production and Trade. Pulp and Paper data. Consulté le 3 Avril 2021. http://www.fao.org/faostat/en/#data/FO/visualize
Gilbert, J.-P. (2015). Survol de l’évolution de l’industrie des pâtes et papiers au Québec. Société de l’histoire forestière du Québec (SHFQ). Consulté le 16 Mars 2021. https://shfq.ca/wp-content/uploads/2017/09/P%C3%A2teset-papier-survol.pdf
Gilbert, J.-P., Rouleau, F. (2014) L’industrie des pâtes et papier : son influence sur le développement de localités au Québec. Société de l’histoire forestière du Québec (SHFQ). Consulté le 16 Mars 2021. https://shfq.ca/wp-content/uploads/2015/05/JPG-industrie-pates-papier.pdf
Kuhlberg, M. (2006, modifié 2015) Pulp and Paper Industry. The Canadian Encyclopedia. Consulté le 15 Mars 2021. https://www.thecanadianencyclopedia.ca/en/article/pulp-and-paper-industry
PLANCHE 3 - Présence territoriale et environnementale
Gouvernement du Canada (2016, dernière modification 2019) Quality of effluents from pulp and paper mills. [Dataset]. Téléchargé le 17 Mars 2021.
https://open.canada.ca/data/en/dataset/2ca77dd7-6482-49ef-a9a1-06dbb792bd51Ministère de la Forêt, de la Faune et des Parcs (2020, dernière modification 2021) Usines de transformation primaire du bois. [Dataset]. Téléchargé le 27 Mars 2021.
https://www.donneesquebec.ca/recherche/dataset/usines-de-transformation-primaire-du-boisMinistère des Transports du Québec (2016). Réseau Ferroviaire. [Dataset]. Téléchargé le 20 Janvier 2021. https://www.donneesquebec.ca/recherche/dataset/reseau-ferroviaire
Ministère des Transports du Québec (2016). Réseau Routier. [Dataset]. Téléchargé le 20 Janvier 2021. https://www.donneesquebec.ca/recherche/dataset/reseau-routier-rtss
Pulp and Paper Canada (2019). 2019 Pulp, Paper, and Bioeconomy Map. Consulté le 27 Mars 2021. https://www.pulpandpapercanada.com/wp-content/uploads/2019/08/PPC_MILL_MAP.pdf
PLANCHE 4 - Le papier et les nouveaux matériaux
Biermann, C. J. (1993). Essentials of pulping and papermaking. Academic press.
Hiziroglu, S. (2016) Basics of Paper Manufacturing. Oklahoma State University. Consulté le 10 Mars 2021. https://extension.okstate.edu/fact-sheets/basics-of-paper-manufacturing.html
Hubbe, M. A., Venditti, R. A., & Rojas, O. J. (2007). What happens to cellulosic fibers during papermaking and recycling? A review. BioResources, 2(4), 739-788.
Gouvernement du Québec. (2012). Les fabriques de pâtes et papiers au Québec : Procédées, rejets, et réglementation. Ministère du Développement durable, de l’Environnement, de la Faune et des Parcs – Direction des politiques de l’eau/Service des eaux industrielles. Consulté le 10 Mars 2021. https://www.environnement.gouv.qc.ca/milieu_ind/bilans/pates-procedes-rejets-reglementation.pdf
Rahimi, Maryam & Brown, Richard & Tsuzuki, Takuya & Rainey, Thomas. (2016). A comparison of cellulose nanocrystals and cellulose nanofibres extracted from bagasse using acid and ball milling methods. Advances in Natural Sciences: Nanoscience and Nanotechnology. 7.
Ribeiro, Ruan & Pohlmann, Bruno & Calado, Veronica & Ramirez, Ninoska & Pereira Jr, Nei. (2019). Production of nanocellulose by enzymatic hydrolysis: Trends and challenges. Engineering in Life Sciences. 19.
Dias, Otavio & Konar, Samir & Leao, Alcides & Yang, Weimin & Tjong, Jimi & Sain, Mohini. (2020). Current State of Applications of Nanocellulose in Flexible Energy and Electronic Devices. Frontiers in Chemistry. 8
PLANCHE 5 - Les possibilités des boues papetières
Roy, G. (2018) Du bioplastique made in Québec. Unpointcinq, média de l’action climatique au Québec. Consulté le 23 Mars 2021. https://unpointcinq.ca/economie/bioplastique-compostable-quebec/
Bosk Bioproducts (date inconnue) Bioplastique écoresponsable. Consulté le 23 Mars 2021. https://www.bosk-bioproducts.com/technology.html
Honext (2019) It’s time to rethink waste and acknowledge its potential. Consulté le 21 Mars 2021. https://honextmaterial.com/process/
Meyer, T., Honghi, T. (2019) Utilization of Kraft Pulp Mill Waste. Pulp & Paper Centre at the University of Toronto. Consulté le 19 Mars 2021. https://www.tappi.org/content/Events/19PEERS/19PEE33.pdf
Watteau, Françoise & Huot, Hermine & Morel, Jean-Louis & Rees, Frédéric & Schwartz, Christophe & Séré, Geoffroy. (2018). Micropedology to reveal pedogenetic processes in Technosols. Spanish Journal of Soil Science. 8.
Naik, Tarun & Moriconi, Giacomo. (2005). Environmental-friendly durable concrete made with recycled materials for sustainable concrete construction. International Symposium on Sustainable Development of Cement, Concrete and Concrete Structures, 5-7 Octobre 2005, Toronto, 485-505.
PLANCHE 6 - Remédiation et filtration biologique des eaux usées
Champignons:
1. Trametes Versicolor
2. Phlebia Radiata
3. Lentinus Edodes
4. Aspergillus Niger
5. Phanerochaete Chrysosporium
6. Pleurotus Ostreatus
Kumar, V., Thakur, I. S., Shah, M. P. (2020) Bioremediation Approaches for Treatment of Pulp and Paper Industry Wastewater: Recent Advances and Challenges. Microbial Bioremediation & Biodegradation. p. 1-48. Springer.
Plantes:
7. Solidago canadensis
Phytoremediation. By McCutcheon & Schnoor. 2003, New Jersey, John Wiley & Sons.
8. Ranunculus sceleratus
Sharma, P., Tripathi, S., Chandra, R. (2020) Phytoremediation potential of heavy metal accumulator plants for waste management in the pulp and paper industry. Heliyon, 6(7).
9. Salix Babylonica
Mleczek, Mirosław & Rissmann, Iwona & Rutkowski, Paweł & Kaczmarek, Zygmunt & Golinski, Piotr. (2009). Accumulation of selected heavy metals by different genotypes of Salix. Environmental and Experimental Botany. 66. 289-296.
10. Brassica juncea
Phytoremediation. By McCutcheon & Schnoor. 2003, New Jersey, John Wiley & Sons
Fu, W., Huang, K., Cai, HH. et al. (2017) Exploring the Potential of Naturalized Plants for Phytoremediation of Heavy Metal Contamination. Int J Environ Res 11, 515–521.
11. Elodea Canadensis
Wani, Rifat & Ganai, Bashir & Shah, Manzoor & Baba, Uqab. (2017). Heavy Metal Uptake Potential of Aquatic Plants through Phytoremediation Technique - A Review. Journal of Bioremediation & Biodegradation.
12. Ceratophyllum demersumMajeed, U., Ahmad, I., Hassan, M., & Mohammad, A. (2014). Phytoremedial potential of aquatic plants for heavy metals contaminated industrial effluent. European Academic Research, 2(6).
13. Lemna Minor
Wani, Rifat & Ganai, Bashir & Shah, Manzoor & Baba, Uqab. (2017). Heavy Metal Uptake Potential of Aquatic Plants through Phytoremediation Technique - A Review. Journal of Bioremediation & Biodegradation.
14. Athyrium filix-femina
Wani, Rifat & Ganai, Bashir & Shah, Manzoor & Baba, Uqab. (2017). Heavy Metal Uptake Potential of Aquatic Plants through Phytoremediation Technique - A Review. Journal of Bioremediation & Biodegradation.
Algues et bactéries:
15. Chlorella
16. Chlamydomonas
17. Anabaena
18. Microcystis
19. Bacillus Subtilis
20. Cryptococcus sp.
21. Raoultella Planticola
22. Serratia marcescens
Cabrera, M. N. (2017). Pulp mill wastewater: Characteristics and treatment. Biological Wastewater Treatment and Resource Recovery, 2, 119-139.
Kumar, V., Thakur, I. S., Shah, M. P. (2020) Bioremediation Approaches for Treatment of Pulp and Paper Industry Wastewater: Recent Advances and Challenges. Microbial Bioremediation & Biodegradation. p. 1-48. Springer.
Autres sources:
Bretzel, F., Pezzarossa, B., Scatena, M., Vannucchi, F. and Cinelli, F. (2018). Use of paper mill sludge for the acclimation of nursery trees planted in urban soil. Acta Hortic. 1215, 129-132
Canadian Wildlife Federation (2021) Native Plant Encyclopedia – Region Québec. Consulté le 4 Avril 2021. https://cwf-fcf.org/en/resources/encyclopedias/native-plant-encyclopedia/
Chandra, R., Yadav, S., Yadav, S. (2017) Phytoextraction potential of heavy metals by native wetland plants growing on chlorolignin containing sludge of pulp and paper industry. Ecological Engineering, V. 98. 134-145.
Ducks Unlimited Canada (2014) Boreal Wetlands Fact Sheet. Consulté le 31 Mars 2021. https://www.ducks.ca/assets/2014/12/Boreal-Wetlands-Fact-Sheets.pdf
Fazel Todd, L., Landman, K., Kelly, S. (2016) Phytoremediation: An interim landscape architecture strategy to improve accessibility of contaminated vacant lands in Canadian municipalities, Urban Forestry & Urban Greening, V. 18, P. 242-256.
Gardea-Torresdey, Jorge & peralta-videa, Jose & de la Rosa, Guadalupe & Parsons, Jason. (2005). Phytoremediation of heavy metals and study of the metal coordination by X-ray absorption spectroscopy. Coordination Chemistry Reviews. 249.
Maehlum, T. (1999) Wetlands for Treatment of Landfill Leachates in Cold Climates, Constructed Wetlands for the Treatment of Landfill Leachates, Chapitre 3, pp 33–46, eds. G.
Rideau Valley Conservation Authority (2016) Algae and Aquatic Plant Education Manual. Consulté le 2 Avril 2021. https://www.rvca.ca/media/k2/attachments/Algae_Manual_Concise.pdf
Sharma, P., Tripathi, S., Chandra, R. (2020) Phytoremediation potential of heavy metal accumulator plants for waste management in the pulp and paper industry. Heliyon, 6(7).