Updated sustainability status of crystalline silicon‐based photovoltaic systems: Life‐cycle energy and environmental impact reduction trends

2021 ◽  
Author(s):  
Vasilis Fthenakis ◽  
Enrica Leccisi
Keyword(s):  
Life Cycle ◽  
Environmental Impact ◽  
Crystalline Silicon ◽  
Photovoltaic Systems ◽  
Impact Reduction ◽  
Silicon Based

scholarly journals Life Cycle Assessment of Variable Rate Fertilizer Application in a Pear Orchard

2020 ◽  
Vol 12 (17) ◽  
pp. 6893
Author(s):  
Anna Vatsanidou ◽  
Spyros Fountas ◽  
Vasileios Liakos ◽  
George Nanos ◽  
Nikolaos Katsoulas ◽  
...  
Keyword(s):  
Climate Change ◽  
Life Cycle Assessment ◽  
Life Cycle ◽  
Environmental Impact ◽  
Precision Agriculture ◽  
Management System ◽  
Primary Data ◽  
Variable Rate ◽  
Impact Reduction ◽  
Pear Orchard

Precision Agriculture (PA) is a crop site-specific management system that aims for sustainability, adopting agricultural practices more friendly to the environment, like the variable rate application (VRA) technique. Many studies have dealt with the effectiveness of VRA to reduce nitrogen (N) fertilizer, while achieving increased profit and productivity. However, only limited attention was given to VRA’s environmental impact. In this study an International Organization for Standardization (ISO) based Life Cycle Assessment (LCA) performed to identify the environmental effects of N VRA on a small pear orchard, compared to the conventional uniform application. A Cradle to Gate system with a functional unit (FU) of 1 kg of pears was analyzed including high quality primary data of two productive years, including also the non-productive years, as well as all the emissions during pear growing and the supply chains of all inputs, projecting them to the lifespan of the orchard. A methodology was adopted, modelling individual years and averaging over the orchard’s lifetime. Results showed that Climate change, Water scarcity, Fossil fuels and Particulate formation were the most contributing impact categories to the overall environmental impact of the pear orchard lifespan, where climate change and particulates were largely determined by CO2, N2O, and NH3 emissions to the air from fertilizer production and application, and as CO2 from tractor use. Concerning fertilization practice, when VRA was combined with a high yield year, this resulted in significantly reduced environmental impact. LCA evaluating an alternative fertilizer management system in a Greek pear orchard revealed the environmental impact reduction potential of that system.

scholarly journals Present and Future Sustainability Development of 3D Metal Printing

2020 ◽  
Author(s):  
Austin Anderson ◽  
Selso Gallegos ◽  
Behnaz Rezaie ◽  
Fardad Azarmi
Keyword(s):  
Life Cycle ◽  
Environmental Impact ◽  
Environmental Sustainability ◽  
Stratospheric Ozone ◽  
Electricity Consumption ◽  
Casting Process ◽  
Future Research ◽  
Pump Impeller ◽  
Impact Reduction ◽  
Toxicity Potential

Additive manufacturing (AM), also known as 3D printing is a relatively new concept and promising technology for industrial production. It is important to investigate the environmental impact of the AM process in light of the critical situation of the Earth. The elimination of some costly prefabrication processes such as molding or post-fabrication stages such as machining and welding required in traditional manufacturing methods favor the AM process and provide great economic advantages. Furthermore, the reduction of manufacturing steps contributes to environmental protection through fewer operations, less material, and energy consumption, and reduced transportation. This study is a preliminary work for analyses of environmental impact and life cycle of some well-known AM technologies for manufacturing metallic parts and components. As a case study, fabrication of a pump impeller is simulated through a well-known metal production AM technology and a conventional technology such as a casting process for direct comparison. Life Cycle Analysis (LCA) is applied to measure the environmental impact in five different stages of pump impeller lifetime with the two different fabrication processes. AM compared to casting has an environmental impact reduction of 15%, 20%, 65%, 20%, and 10% respectively in Global Warming Potential (GWP), Acidifications Potential (AP), Water Aquatic Eco-toxicity Potential (FAETP), Human Toxicity Potential (HTP), and Stratospheric Ozone Depletion (ODP). In the pre-manufacturing stage, the AM process has a higher impact on the environment in comparison with the casting process due to intense electricity consumption. Using hydroelectricity and renewable energy electricity mitigates the environmental impact of the AM process in pre-manufacturing and manufacturing stages as temporary until the advancement of AM technology for consuming less energy. Finally, a plan for future research to enhance the environmental sustainability of the AM process is proposed.

Environmental impact reduction as a new dimension for quality measurement of healthcare services

2018 ◽  
Vol 31 (8) ◽  
pp. 910-922 ◽  
Author(s):  
Amin Esmaeili ◽  
Charles McGuire ◽  
Michael Overcash ◽  
Kamran Ali ◽  
Seyed Soltani ◽  
...  
Keyword(s):  
Life Cycle ◽  
Environmental Impact ◽  
Carbon Footprint ◽  
Healthcare Services ◽  
Life Cycle Approach ◽  
Imaging Device ◽  
Content Type ◽  
Impact Reduction ◽  
Imaging Department ◽  
Process Energy

Purpose The purpose of this paper is to provide a detailed accounting of energy and materials consumed during magnetic resonance imaging (MRI). Design/methodology/approach The first and second stages of ISO standard (ISO 14040:2006 and ISO 14044:2006) were followed to develop life cycle inventory (LCI). The LCI data collection took the form of observations, time studies, real-time metered power consumption, review of imaging department scheduling records and review of technical manuals and literature. Findings The carbon footprint of the entire MRI service on a per-patient basis was measured at 22.4 kg CO2eq. The in-hospital energy use (process energy) for performing MRI is 29 kWh per patient for the MRI machine, ancillary devices and light fixtures, while the out-of-hospital energy consumption is approximately 260 percent greater than the process energy, measured at 75 kWh per patient related to fuel for generation and transmission of electricity for the hospital, plus energy to manufacture disposable, consumable and reusable products. The actual MRI and standby energy that produces the MRI images is only about 38 percent of the total life cycle energy. Research limitations/implications The focus on methods and proof-of-concept meant that only one facility and one type of imaging device technology were used to reach the conclusions. Based on the similar studies related to other imaging devices, the provided transparent data can be generalized to other healthcare facilities with few adjustments to utilization ratios, the share of the exam types, and the standby power of the facilities’ imaging devices. Practical implications The transparent detailed life cycle approach allows the data from this study to be used by healthcare administrators to explore the hidden public health impact of the radiology department and to set goals for carbon footprint reductions of healthcare organizations by focusing on alternative imaging modalities. Moreover, the presented approach in quantifying healthcare services’ environmental impact can be replicated to provide measurable data on departmental quality improvement initiatives and to be used in hospitals’ quality management systems. Originality/value No other research has been published on the life cycle assessment of MRI. The share of outside hospital indirect environmental impact of MRI services is a previously undocumented impact of the physician’s order for an internal image.

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