1.
Delignification Of Rice Husk By Organic Solvent Treatment To Increase It’s In Vitro Digestibility
by Awais Alam (2012-VA-604) | Dr. AbuSaeed Hashmi | Miss Huma Mujahid | Dr. Asif Nadeem.
Material type: ; Literary form:
not fiction
Publisher: 2014Dissertation note: The major constituent of plant cell wall is lignocellulose. Plant biomass mostly consist of cellulose, hemicellulose and lignin alongside little measures of pectin, protein, extractives (dissolvable nonstructural materials, for example, sugars, nitrogenous material, chlorophyll, waxes) and ash. Lignocellulosic biomass is the most abundant organic material in nature. There is an expected yearly overall production of 10–50 billion dry tons representing about 50% of the worldwide biomass yield (Parveen et al. 2009).
Numerous physicochemical, structural and compositional variables decrease the digestibility of cellulose present in lignocellulosic material. So a treatment is required to increase the digestibility of lignocellulose biomass by exposing the cellulose present in plant fibers. Different techniques have been utilized for treatment, including chemical treatment, ammonia fiber explosion, biological treatment and steam explosion to modify the cellulosic structure to increase the availability of cellulose for digestion (Haoran et al. 2013). At that point, acids, bases and enzymes might be utilized to break down the cellulose into its respective sugars. Cellulolytic enzymesare broadly used to break down cellulose into its constituent sugars.
Among various agricultural wastes a broadly available waste is Rice husk (RH) which is rich in lignocellulosic material. Internationally, roughly 600 million tons of rice paddy is delivered every year. By and large 20% of the rice paddy is husk, giving a yearly aggregate generation of 120 million tons (Abbas et al. 2010). Pakistan is a rice producing country a great part of the husk produced from processing of rice is either blazed or dumped as waste. Rice husk yield in Pakistan is more than 1780 thousand tons every year (Asif et al. 2013).
Rice husk produced during rice refining, makes disposal issue because of less business interest. Additionally, handling and transportation of RH is hazardous because of its low density. Rice husk ash (RHA) is an incredible environmental risk bringing about harm to land and encompassing range here it is dumped. Thus, business utilization of rice husk and its ash is the option answer for disposal problem (Dilip et al. 2014).
RH are essentially made up of lignocellulose (60wt. %) and silica (11wt. %). The greater part of past investigations concentrated on the preparation of silica or other silicon based materials from RH, while the lignocellulose in RH was mostly glazed and then wasted. Thus, a methodology for comprehensive usage of RH has been produced to expand its digestibility by the breakdown of lignocellulosic mass. (Ajay et al. 2012)
Numerous techniques have been adopted for treating lignocellulosic feedstocks. However just a few of them appear to be encouraging. These treatment techniques include dilute acid treatment, steam blast (CO2 blast), pH controlled water treatment, ammonia fiber expension, ammonia recycle percolation (ARP) and lime treatment. Some survey articles have been appeared for microbial biomass treatment. But the present study gave presentations on organosolv treatment process. Despite the fact that organosolv treatment is more expensive at present than the leading treatment forms, it can give some significant side products. It appears that organosolv treatment is more practical for biorefinery of lignocellulosic biomass which considers the usage of every bit of biomass parts. An essential streamlining and usage of side products may lead the organosolv treatment to be a guaranteeing one for bio refining lignocellulosic feedstock in future. Organosolv treatment yields three different parts: dry lignin, a watery hemicellulose stream and a moderately pure cellulose division (Xuebing et al. 2009).
Availability: Items available for loan: UVAS Library [Call number: 2230-T] (1).
2.
Detection And Analysis Of Improvised Explosive Devices Used In Terrorism Activities In Pakistan
by Arslan Nazar (2012-VA-630) | Dr. Sehrish Firyal | Dr. Muhammad Sarwar | Dr. Muhammad Wasim | FaizaMasood.
Material type: ; Literary form:
not fiction
Publisher: 2014Dissertation note: Defence and security organizations are in steadyrequirement of finding new options for the detection of explosives. Fundamental applied research in this area focuses on uncovering of highly energetic substances as well as home-basedexplosives that could be a weapon of mass devastation (Marshal and oxley, 2009 yinon and Zitrin 1996, Scubert and Rimiski-Korsakove, 2006). Current methods of detection for explosives or highly energetic materials are based on a wide variety of technologies that focus on either massexplosives or little portions of explosives. Mass explosives can be distinguishedin some way by imaging features,character of the explosives charge, wires and detonators or unswervingly by spotting the chemistry and dielectric characteristics of the explosive substance. Trace recognition method relay on revealing of vapours given off by the explosives or on explosive’sconstituent part that are set down on nearbyexteriors (national Academy of sciences Committee, 2004). Even though, numerous published material is available about methods of sensing of explosives present in air,water, clothing,soiletc and these put forward the benefit of providing traceconfines of sensation at ppb intensities (Caron et al,. 2010; Hilimi and Luonge). Inthe bulk of the criminal acts, sampling is done at the scene trailed by a sample preparationmove, to be shortly processed by a particular technique for analysis. Sampling and samples preparation are amidmajor, shortcomings in explosive uncovering in many cases frightening the physical condition and life of examiner and the responding officer.
Improvised explosive devices are widely used by military in wars and police to keep up regulation and command. Gush of terrorist activities and increase in criminal conduct have been a matter of great concern worldwide and particularly for Pakistan. There have been motiveless
annihilation of private and community properties as well as industrial centres, causing irretrievabledamages to state and local markets and imperillinghumanexistence(Shen et al. 2005). Potentially perilous explosives like dynamite, varied military explosives havingnitroglycerine (NG), Cyclotrimethylenetrinitramine commonly known as RDX, Cyclotetramethylenetetranitramine and alternativehome-produced low explosives and provocative devices are now currently promptly obtainable to scandalous and terrorists. The haphazard and deliberate uses of these explosives consist ofextortion of cash and taking vengeance, unlawful transportation of prohibited substances, assassinations, terrorist and delinquent activities in numerous regions of the country (Sharma and Lahiri 2005).
Recognition of detonating method, estimating the path ways taken by explosive transportation andarresting the anti-social charactersconnected with unstable materials and explosions is primary aim of explosive analysis. For this purpose various explosive substances and explosive remains are to be examined qualitatively and the ingredients are to be approximated quantitatively using primarily by thin layer chromatography (TLC). TLC is a technique employed for the screening of organic constituents at hand in the post blast samples. The identification of explosives containing alkylammonium nitrate is done by TLC. Secondly Gas chromatography with mass spectrometry (GC-MS) technique with the benefit of anelevated resolving supremacy is avitalapparatus for the analysis of chemical composition of explosives. The extremelyproficient GC analysis withcapillary columns authorizes the examination of explosive hydrocarbons, identical substances of nitroaromatics, hexogen (RDX) and the high explosive pentaerythritoltetranitrate (PETN) in a single run. The spectroscopic identification of explosive materials by FTIR is striking due to the intrinsicpotential of real-time detection, non-vicious analysis, and nominal sample preparation, thirdly the scanning electron microscope (SEM) produces an increased image of the sample based on the contact of an electron beam with the sample’s exterior. Finding of minutemasses of explosive remains play an important part in forces, inhabitant, and counter terrorism requests(Pacheco-Londono et al. 2005). To press on explosives sensor methods, present methods need to become affordable and transportable without disturbing the integrity of the devices. The uncovering of ordinary explosives as well as trinitrotoluene (TNT), RDX, HMX, 2,4,6 Trinitrophenyl-N-methylnitramine (TETRYL)Pentaerythritoltetranitrate (PENT), and NG were carried out using diverseprocedures(Sanchez et al. 2007).
Detection of explosives is anparticularly relevant analytical concern for law enforcement personals and for the environmental protection agencies. As the use of explosive substances have been increased by the terrorists, problems have increased for law enforcement and environment and security agencies regarding the detection ofexplosives residues in baggage, parcels vehicles, aeroplane, on travellers, etc. In bomb scene investigations, it is important to find debris that includes detection of explosive residues. Mobile and hand held explosives detectors, similar to those used for detecting hidden explosives, can be of great help in detecting such residues. Several methods i.e. GC/MS, SEM, FTIR were used in Punjab Forensic Science Agency (PFSA) to analyze residues of explosives. The detection of landmines is an acute, urgent worldwide problem that needs specific and effective detection methods (Yinon 2002). Keeping in mind the above said situations, the project was designed with following objectives
Availability: Items available for loan: UVAS Library [Call number: 2235-T] (1).
