A. R. Pradeep Kumar scite author profile

First, second, third, and fourth-generation biofuels are continuously evolving as a promising substitute to petrodiesel catalyzed by energy depletion, economic and environmental considerations. Bio-diesel can be synthesized from various biomass sources, which are commonly divided into FAME and renewable biodiesel. FAME biodiesel is generally produced by the transesterification of vegetable oils and fats while renewable diesel is produced by hydro-deoxygenation of vegetable and waste oils and fats. The different generation, processing technologies and standards for FAME and renewable biodiesel are reviewed. Finally, the life cycle analysis and production cost of conventional and renewable biodiesel are described.

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A review of conventional and renewable biodiesel production

Vignesh¹,

Kumar

Ganesh

et al. 2021

Chinese Journal of Chemical Engineering

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Scanning electron microscopic and energy dispersive spectrometric investigations on the effect of XeCl excimer laser on human dentin with smear layer

Kumar¹,

Rao²,

Parameswaran³

et al. 2002

J of Oral Rehabilitation

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The purpose of this study was to study the effect of XeCl excimer laser on smear layer covered dentine of extracted human teeth. Twenty-four freshly extracted human molar teeth were collected and randomly divided into one control group and three experimental groups of six teeth each (groups A-D). The teeth in the experimental groups were irradiated with XeCl 308-nm excimer laser at a fluence of 0.4 J cm-2 and a constant pulse repetition rate of 25 Hz. Group A was used as the control, while groups B, C and D were irradiated at different exposure times of 3, 5 and 7 s, respectively. Subsequently these teeth specimens were subjected to scanning electron microscopic (SEM) examination and energy dispersive X-ray (EDX) spectrometric analysis. The SEM examination revealed melting of the smear layer covered dentin to conceal the underlying dentinal tubules. At a longer exposure time (7 s), dentin melted to form large grains and this resulted in non-uniform closure of underlying dentinal tubules. Under the conditions of this study, it is concluded that the pulsed XeCl 308-nm excimer laser at a fluence of 0.4 J cm-2, with an exposure time of 5 s uniformly occluded exposed smear layer covered dentine with no conspicuous variation in chemical structure.

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Effect of Thermal Barrier Coating on DI Diesel Engine Fuelled with P20 Biodiesel

Kumar

Annamalai

Premkartikkumar³

2012

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Analytical investigations on heat transfer in a low heat rejection DI diesel engine

Kumar

Annamalai

Prabhakar

et al. 2010

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A. R. Pradeep Kumar

Biodiesel and green diesel generation: an overview

A review of conventional and renewable biodiesel production

Scanning electron microscopic and energy dispersive spectrometric investigations on the effect of XeCl excimer laser on human dentin with smear layer

Effect of Thermal Barrier Coating on DI Diesel Engine Fuelled with P20 Biodiesel

Analytical investigations on heat transfer in a low heat rejection DI diesel engine

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