O problemach przeciwdziałania wzrostowi globalnej temperatury

• Autorzy: Jarominiak Andrzej

Warianty tytułu

EN

Problems of counteracting the increase in global temperature

• Języki publikacji: PL

Abstrakty

PL

Przedstawiono źródła emisji gazów cieplarnianych: przemysł, transport, elektrownie, ciepłownictwo, uprawę ziemi, hodowlę zwierząt i utylizację odpadów. Omówiono główne porozumienia międzynarodowe dotyczące ograniczenia wzrostu globalnej temperatury, decydujące kierunki przeciwdziałania wzrostowi ilości dwutlenku węgla w atmosferze oraz problemy jego wychwytywania, utylizacji, transportu i składowania. Szczególną uwagę poświęcono problemom przeciwdziałania wzrostowi globalnej temperatury przez budownictwo.

EN

The sources of greenhouse gas emissions presented: industry, transport, power plants, heating, farming, animal husbandry and waste disposal. The main international agreements on limiting increase in global temperature as well as decisive countermeasures against the amount of carbon dioxide in the atmosphere and the problems with its capture, transport and storage (CCS), and utilization (CCU) were discussed. Particular attention was paid to the problems of counteracting the increase in global temperature by the construction industry.

Słowa kluczowe

PL

dwutlenek węgla; wzrost temperatury; przeciwdziałanie; emisja gazów cieplarnianych; neutralność klimatyczna; budownictwo; technologia CCS

EN

carbon dioxide; temperature increase; counteraction; greenhouse gas emissions; climate neutrality; construction; CCS technology

• Wydawca: Fundacja Polskiego Związku Inżynierów i Techników Budownictwa
• Czasopismo: Inżynieria i Budownictwo
• Rocznik: 2021
• Tom: R. 77, nr 11-12
• Strony: 515--523
• Opis fizyczny: Bibliogr. 26 poz., il.

Twórcy

autor

Jarominiak Andrzej

Bibliografia

• [1] Bernal S.A., Rodriguez E.D., Kirchheim A.P., Provis J.L.: Management and valorisation of wastes through use in producing alkali-activated cement materials. Review SCI, February 2016.
• [2] Carbon Upcycling Technologies, https://carbonupcycling.com.
• [3] Cevik A., Alzeebarree R., Humur G., Nis A., Gulsan E.: Effect of Nano-silica on the Chemical Durability and Mechanical Performance of Fly Ash Based Geopolimer Concrete. Ceramics International. 2 April 2018. https: //doi.org/10.1016/j.ceramint.2018.04.009.
• [4] Czarnecki L.: Nanotechnologia w budownictwie. "Inżynier Budownictwa", 12/2010.
• [5] Engineers have built machines to scrub CO2 from the air. But will it halt climate change? The Conversation. Tokyo 2020.
• [6] Global CCS Institute: Global Status of CCS, 2019.
• [7] Global CCS Institute: Global Status of CCS, 2020.
• [8] Harvey Ch.: Cement Producers Are Developing a Plane to Reduce CO2 Emissions. E&E NEWS, July 9.2018 (Climate Change).
• [9] Jarominiak A.: Wodór i amoniak środkami osiągnięcia neutralności klimatycznej. "Energetyka", 8/2021.
• [10] Naik T.R.: Suitable of Concrete Construction. Research Gate, May 2008.
• [11] Praca zbiorowa. Redakcja naukowa K. Kurzydłowski i M. Lewandowska: Nanomateriały inżynierskie konstrukcyjne i funkcjonalne. PWN, 2010.
• [12] Ravikumar D., Zhang D., Keoleian G., Miller S., Sick V., Li V.: Carbon dioxide utilization in concrete curing or mixing might not produce a net climate benefit. Nature Communications 08 Febr. 2021.
• [13] Singh B., Ishwarya G., Gupta M., Bhattacharyya S.K.: Geopolymer concrete: review of some recent development. ELSEVIER Construction and Building Materials 85, 2015.
• [14] Suhendro B.: Toward green concrete for better sustainable environment 2nd Intern. Conference on Sustainable Civil Engineering Structures and Construction Materials 2014 (SCESCM 2014).
• [15] Torres-Carrasco M., Puertas F.: Alkaline activation of different aluminosilicates as an alternative to Portland cement: alkali activated cements or geopolymers. Revista Ingenieria de Construcción RIC Vol 32 N°2 2017.
• [16] Xi Fengming i 18 in.: Substantial global carbon uptake by cement carbonation. "Nature Geoscience", 9, 2016.
• [17] Constantinides G., Ulm F.: The nano-granular nature of C-S-H. "Jaurnal of the Mechanics and Physics of Solids", 55, 2007.
• [18] Horiguchi T., Saeki N.: Compressive Strength and Leachate Characteristics of New Green CLSM with EcoCement and Melted Slag from Municipal Solid Waste. Special Publication, Vol. 221, May 2004.
• [19] Horiguchi T., Kikuchi T., Nakagawa Y., Shimura K.: Physical Properties of CLSM Using High Volumes of Incineration Ash from Sewage Sludge. Special Publication, Vol. 242, April 2007.
• [20] Li C., Thostenson, E. T., Chou T W.: Sensors and actuators based on carbon nanotubes and their composites: A review. "Composite Science and Technology", 68, 2008.
• [21] Sasmal S., Bhuvaneshwari B., Lyer N.R.: Can Carbon Nanotubes Make Wonders in Civil/Structural Engineering? Progress in Nanotechnology and Nanomaterials. 2(4), October 2013.
• [22] Pham G.T., Park Y.B., Liang Z.; Zhang C.: Processing and modeling of conductive thermoplastic/carbon nanotube films for strain sensing. Composites part B: Engineering, Elsevier, January 2008.
• [23] Brehm D.: Nanoengineered concrete could cut carbon dioxide emissions. MIT News, January 30, 2007.
• [24] Geopolymers. Structure, processing, properties and industrial applications. Edited by J.L. Provis, J.S.J. van Deventer. CRC Press. Boca Raton, Boston, New York, Washington DC 2009.
• [25] Davidovits J., Davidovits F.: The Pyramids: An Enigma Solved. 2nd Ed., Saint-Quentin, France, Editions J. Davidovits, 2001.
• [26] Barsoum M.W., Ganguly A., Hug G.: Microstructular evidence of reconstituted limestone blocks in the Great Pyramids of Egypt. "Journal of the American Ceramic Society" , 89, 2006.