4,264 research outputs found
Figure_S2 – Supplemental material for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour
Supplemental material, Figure_S2 for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour by Abir Dutta, Kaushik Mukherjee, Venkata Sundeep Seesala, Kaushik Dutta, Ranjan Rashmi Paul, Santanu Dhara and Sanjay Gupta in Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine</p
Figure_S4 – Supplemental material for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour
Supplemental material, Figure_S4 for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour by Abir Dutta, Kaushik Mukherjee, Venkata Sundeep Seesala, Kaushik Dutta, Ranjan Rashmi Paul, Santanu Dhara and Sanjay Gupta in Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine</p
Figure_S3 – Supplemental material for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour
Supplemental material, Figure_S3 for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour by Abir Dutta, Kaushik Mukherjee, Venkata Sundeep Seesala, Kaushik Dutta, Ranjan Rashmi Paul, Santanu Dhara and Sanjay Gupta in Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine</p
Figure_S1 – Supplemental material for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour
Supplemental material, Figure_S1 for Load transfer across a mandible during a mastication cycle: The effects of odontogenic tumour by Abir Dutta, Kaushik Mukherjee, Venkata Sundeep Seesala, Kaushik Dutta, Ranjan Rashmi Paul, Santanu Dhara and Sanjay Gupta in Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine</p
Comparative compression ignition engine performance, combustion, and emission characteristics, and trace metals in particulates from Waste cooking oil, Jatropha and Karanja oil derived biodiesels
In the present study, comparison of performance, combustion and emission characteristics of a single cylinder compression ignition (CI) genset engine fueled by biodiesels derived from Waste cooking oil (WCO), Jatropha and Karanja oils vis-a-vis baseline mineral diesel has been carried out. Performance and combustion investigations were carried out at constant engine speed (1500 rpm) and six engine loads (0-100%). WCO biodiesel showed slightly higher heat release rate (HRR) than baseline mineral diesel, while it was slightly lower for Karanja and Jatropha biodiesels. Hydrocarbons (HC) and oxides of nitrogen (NOX) emissions were lower, while carbon monoxide (CO) emission was relatively higher for biodiesels compared to baseline diesel. Smoke opacity was higher for Karanja and Jatropha biodiesels compared to baseline diesel. WCO biodiesel exhibited comparable smoke opacity with baseline mineral diesel except at full load, where it was relatively lower. Particulates were collected from the engine exhaust on a quartz filter paper using a partial flow dilution tunnel at 50 and 100% engine loads, for trace metal analysis using inductively coupled plasma optical emission spectroscopy (ICP-OES). It was found that trace metals such as Ca, Cu, Fe, K, Mg, Na, Zn and Al showed higher concentrations in particulates from all test fuels, while Ba, Cd, Cr, Mn and Mo showed relatively lower concentrations in the particulates collected.
In-Cylinder Spray and Combustion Investigations in a Heavy-Duty Optical Engine Fueled With Waste Cooking Oil, Jatropha, and Karanja Biodiesels
In this experimental study, spray and combustion characteristics of a single cylinder optical engine were evaluated by varying the fuel injection pressure (FIP) (40, 80, and 120 MPa). Karanja, Jatropha, and waste cooking oil (WCO) biodiesels were the test fuels and their results were compared with baseline mineral diesel. There was no significant difference observed in the spray tip penetration amongst all test fuels, however the spray cone angles of biodiesels were slightly higher than baseline mineral diesel. Mineral diesel showed relatively shorter injection delay compared to biodiesels at 40 and 80 MPa FIP. Jatropha and Karanja biodiesels showed higher flame luminosity at all FIPs, while WCO biodiesel showed lower flame luminosity, especially at higher FIPs of 80 and 120 MPa, primarily due to lower viscosity of WCO biodiesel. Flame spatial fluctuation (FSF) and flame nonhomogeneity (FNH) were also found to be higher for biodiesels at lower FIP of 40 MPa. Karanja and Jatropha biodiesels showed higher FSF and FNH at higher FIPs compared to WCO biodiesel.
Data for Gupta et al., "Estimating the Meridional Extent of Adiabatic Mixing in the Stratosphere using Age-of-Air", JGR:Atmospheres,
Model data and post-processed data supporting the creation of the manuscript "Estimating the Meridional Extent of Adiabatic Mixing in the Stratosphere using Age-of-Air" submitted to JGR:Atmospheres in August 2022.
1) The netCDF files created through post-processing of full model data in FORTRAN are shared in the /data/ directory. These file contains the zonal mean circulation statistics based on Gupta et al. (2020), age-of-air transport diagnostics based on Linz et al. (2021), and the novel \Gamma-\Theta circulation streamfunction introduced in this study. The /data/ directory also contains MATLAB .mat data files for the transport diagnostics obtained from WACCM. 150 days of actual GFDL-FV3 model data in the northern hemisphere, between 0.1 hPa-500 hPa pressure levels is also provided to support external computations and validation.
2) The Jupyter notebook used for final computation and figures production is provided in .ipynb, .html and .pdf formats in /code/. All the files referred to in the notebook are stored in the /data/ directory.
Corresponding author : Aman Gupta, [email protected], [email protected], [email protected]
Corrigendum: Capital Inflows and House Prices: Aggregate and Regional Evidence from China
In the paper ‘Capital Inflows and House Prices: Aggregate and Regional Evidence from China’ by H. An, et al., printed in the December 2016 issue, there was a missing acknowledgement section for funding resources.
On page 451, the acknowledgement section should appear after the corresponding information as:
“Correspondence: Rakesh Gupta, Department of Accounting, Finance and Economics, Griffith Business School, Griffith University, Nathan Campus QLD 4111. [email protected]
*This work was financially supported by the Humanities and Social Science Foundation of Ministry of Education of China (16YJA790001).”
The author apologises for this error and any confusion it may have caused.No Full Tex
sj-docx-1-ggm-10.1177_23337214231194965 – Supplemental material for Association Between Cognitive Performance and Nutritional Status: Analysis From LASI-DAD
Supplemental material, sj-docx-1-ggm-10.1177_23337214231194965 for Association Between Cognitive Performance and Nutritional Status: Analysis From LASI-DAD by Manjusha Bhagwasia, Abhijith R. Rao, Joyita Banerjee, Swati Bajpai, Aruna V. Raman, Arunanshu Talukdar, Arvind Jain, Chhaya Rajguru, Lalit Sankhe, Debabrata Goswami, Ganapathy Sankaralingam Shanthi, Govind Kumar, Mathew Varghese, Minakshi Dhar, Monica Gupta, Parvaiz A-Koul, Rashmi Ranjan Mohanty, Sankha Shubhra Chakrabarti, Sathyanarayana Raju Yadati, Sharmistha Dey and Aparajit Ballav Dey in Gerontology and Geriatric Medicine</p
- …
