Greenhouse Gas Emission Reduction Due to Improvement of Biodegradable Waste Management System

1. BiPRO. (2012). Screening of Waste Management Performance of EU Member States.Search in Google Scholar

Beratungsgesellschaft für integrierte Problemlösungen. Brisele: European Commission.Search in Google Scholar

Retrieved May 19, 2014 from http://ec.europa.eu/environment/waste/studies/pdf/ Screening_report.pdfSearch in Google Scholar

2. Eurostat. (2012). Greenhouse gas emissions by sector. Luxemburg: Eurostat. Retrieved January 21, 2013 from http://epp.eurostat.ec.europa.euSearch in Google Scholar

3. UNFCCC. (2012). National Inventory Submissions. United Nations Framework Contention on Climate Change. Retrieved January 10, 2013 from http://unfccc.int/national_ reports/annex_i_ghg_inventories/national_inventories_submissions/items/6598.phpSearch in Google Scholar

4. BIO Intelligence, S. (2011). Preparatory Study on Food Waste Across EU 27. European Communities. doi:DOI : 10.2779/85947Search in Google Scholar

5. JRC. (2014). End-of-waste criteria for biodegradable waste subjected to biological treatment (compost & digestate): Technical proposals. Joint Research Centre, Luxembourg. doi:ISSN 1831-9424Search in Google Scholar

6. Virsma Ltd (2011). Degradējamā organiskā oglekļa daļas noteikšana apglabātos atkritumos (Report of Latvia’s national greenhouse gas emission inventory) RigaSearch in Google Scholar

7. LEGMC. (2014). Valsts statistisko pārskats “3-Atkritumi” (State Statistical Review “3-Waste”). Latvian Environment, Geology and Meteorology Centre, State Ltd, Riga.Search in Google Scholar

Available at: http://parissrv.lvgmc.lv/#viewType=home_view (Accessed 29.08.2014)Search in Google Scholar

8. Mc Dougall, F., White, P., Franke, M., & Hindle, P. (2003). Integrated Solid Waste Management: a Life Cycle Inventory. In F. W. Mc Dougall, Integrated Solid Waste Management: a Life Cycle Inventory (p. 513). Oxford, UK: Blackwell Science.Search in Google Scholar

9. Tchobanoglous, G., Theisen, H., & S, V. (1993). Integrated Solid Waste Management.Search in Google Scholar

Engineering Principles and Management Issues. (p.978) Singapore: McGraw-Hill Book Co. doi:ISBN 0-07-112865-4Search in Google Scholar

10. Kļavenieks, K. (2014. gada 17. 10). Eiropas Savienības fondu 2014. - 2020. gada finanšu plānošanas perioda potenciāli atbalstāmo vides aizsardzības aktivitāšu ekonomisko ieguvumu novērtējums. (Potentially supported environmental protection activities and its economic assessment for the next European Union Funds financial programming period 2014 - 2020,) Riga: Oral presentation. Geo Consultants, SIASearch in Google Scholar

11. Arina, D., Bendere, R., & Teibe, I. (2012). Pre-treatment Processes of Waste Reducing the Disposed Amount of Organic Waste and Greenhouse Gas Emission. Congress proceedings (p. 517 pdf). Florence: The ISWA World Solid Waste Congress 2012.Search in Google Scholar

12. Kalnacs, J., Arina, D. and Murashov, V. (2013), “Content and Properties of Mechanically Sorted Municipal Wastes and Their Suitability for Production of Alternative Fuel,” Renewable Energy & Power Quality Journal, pp. 1-4. doi:ISSN:2172-038X10.24084/repqj11.525Search in Google Scholar

13. Dubrovskis, V., Niklass, M., Emsis, I., & Kārkliņš A, (2013). Biogāzes ražošana un efektīva izmantošana (Production of biogas and effective consumption), Latvijas Biogāzes asociācija, Rīga. Retrieved November 10, 2014 from http://latvijasbiogaze.lv/ files/Buklet_LQ.pdfSearch in Google Scholar

14. IVL. (2013). Joint Baltic Sea Region Strategy for Municipal Waste Management. IVL Swedish Environmental Research Institute. Retrieved from www.recobaltic21.netSearch in Google Scholar

15. Moora, H. (2009). Life Cycle Assesment as a Decision Support Tool for System Optimisation - the Case of Waste Management in Estonia, Tallinn: Tallinn University of Technology p. 174. doi:ISSN 1406-4766Search in Google Scholar