Sunday, July 24, 2011

Nanotechnology


Nano technology, shortened to   “Nano Tech” is the study of the control of matter on an    atomic   and molecular scale.  Generally  Nano technology  deals with  structure of  the size hundred nano meters  or smaller,  and involves  developing materials  or  devices  with in the system.
Where a nano meter is unit of length in the metric system equal to one billionth of meter.  Nano technology id\s extremely  diverse,  ranging from  naval extensions  of conventional devices  physics,  to completely new approaches  based upon  molecular  self  -  assembly.
Nano Technology is some times referred to as a general purpose technology.  That because in its advanced forms it will have significant impact on almost all industries and all of society,

Chemical Engineering Research and Design

Core topic areas

Distillation and absorption

  • Hydrodynamics, heat and mass transfer in separation equipment
  • Physical properties and thermodynamic models/methods
  • Process design, operation and intensification
  • Process equipment characterisation
  • Process modelling, simulation and optimisation

Fluid flow

  • All aspects of fluid flow in chemical and/or process vessels

Heat and mass transfer

  • Mechanisms of heat and mass transfer
  • Multicomponent mass transfer
  • Simulation of heat and mass transfer processes
  • Simultaneous heat and mass transfer

Materials processing and product development

  • Fundamental properties of interest to processing of materials
  • Injection moulding of materials
  • In-line measurement and control of material processes
  • Morphological development processes
  • Pre-processing, shaping, multi-layering and finishing of final product form
  • Product design based on chemical engineering tools
  • Structure-function relationships in products and relevant systems
  • Tailoring chemical products and materials for end-use applications

Oil and natural gas production

  • Economics of upstream oil and gas development
  • Facilities
  • Oil and gas transport
  • Well and reservoir oil, gas and water flow behaviour
  • Well treatments and fracturing

Particle technology

  • Crystallisation and precipitation
  • Design of particulate systems and processes
  • Formation and synthesis of particulates
  • Kinetics of particulate processes
  • Measurement and characterisation of particulate systems
  • Processing, handling and storage of powders and dispersions
  • Product formulation and rheology

Pharmaceutical engineering

  • Design, modelling, operation and control of pharmaceutical (bio)reactors, unit operators and process systems used in the production of (bio)pharmaceuticals.
  • Application of process analytical technology in pharmaceutical product and process design and characterisation.
  • Pharmacokinetic and pharmacodynamic modelling
    Design, characterisation and modelling of drug delivery systems.

Process systems engineering

  • Information modelling and analysis
  • Process design and integration
  • Process modelling, simulation and optimization
  • Process operations and control
  • Techno-economic analysis

Reaction engineering

  • Catalysis engineering
  • Process intensification
  • Reaction kinetics
  • Reactive flows
  • Reactor development, modelling and scale-up

Separation processes

  • Adsorption science and technology
  • Green processes
  • Intensification and integration of separation processes
  • Molecular separation: membranes, chromatography
  • Phase separation: clarification, flocculation, microfiltration
  • Reactive separation processes: hybrid and novel separation techniques
  • Separation by phase change

How To Safely Work at a Chemical Plant

The chemical process industry is a thriving one, what with the numerous products that you can get as an end consumer. It is small wonder if you are embarking on a career that involves working at a chemical plant. But just as the compensation and career growth opportunities are high, the safety risks are doubled or tripled as opposed to working more clerical jobs. Many a chemical tragedy has claimed lives needlessly, and often even affecting the very environment under which the chemical disaster took place. It is very important for you to learn how to safely work at a chemical plant to avoid getting a sizable income at the expense of your precious life. Here is how you can ensure safety in a chemical plant job:
  1. Get in touch with the chemical safety key person or team. There is often a person or team in charge of the safety policies and procedures of a chemical plant. You need to get to know these people so that you can also give them a heads up of certain policies that are not properly implemented, for your safety as well as everybody in the chemical plant. 
  2. Observe the classification and proper labeling of chemicals. Chemicals need to be labeled accordingly to prevent explosive tendencies between adverse chemical reactions. There are some chemicals that are fatal to place side by side in a shelf. Make sure that you are able to properly read the labels before making use of the chemicals in the plant, especially those which require large quantities.
  3. Have the right safety gear. Your attire will make or break your risk for getting hurt by toxic chemicals. There are chemicals that are caustic and not too friendly to the skin. Make sure that you are able to wear the right safety gear at all time. Scrub suits, goggles and even the right footwear may really save you in the most dangerous situations.
  4. Heed the chemical safety signs. These signs are often laminated to be durable even under the most severe chemical working conditions. The chemical safety signs often adhere to a global standard. Regardless of the language, the icons will speak of warnings and policies in certain areas.
  5. Properly fill out the material safety data sheet. If you are an individual worker for chemicals, you material safety data sheet is your best ally. Do not be slack in filling out these fields so that you will have less risks of endangering yourself.
  6. Be acquainted with emergency procedures and facilities. Certain procedures of emergencies and other unfavorable conditions are very vital. First aid kit locations, fire extinguishers and many other tools are something you need to know as well as the back of your hand.
  7. Familiarize yourself completely with the process flow of your chemical plant. The process flow will not just help you see the significance of your work, but you will also be able to quickly detect how to get out and stay safe when things get wrong or malfunction in one system.

Modern Chemical Engineering

Modern Chemical Engineering
Most universities that offer Chemical Engineering as a degree train students regarding the field in its widest sense. The reason for that is most chemical engineering jobs require a wide knowledge in the application of the study.
A lot of chemical engineering jobs today require production of high performance materials for automotive, aerospace, electronic, biomedical, space, environmental, and military applications. These include products like:
  • Ultra strong fabrics and fibers
  • Composites and adhesives for vehicles
  • Bio-compatible materials for prosthetics and implants
  • Gels used in medical applications

New Research in Chemical Engineering

New research opens up new opportunities. Be it a discovery or a solution to a problem, they are all because of starting a new study. This is basically the reason why most governments and organizations fund these processes. And much more priority is given to research in Chemical Engineering. This field is given attention because chemical engineers are pioneers in processing raw materials or chemicals that they convert into a more useful and valuable form. They are also behind software engineering, where they start new techniques and technologies like nanotechnology and biomedical engineering.
Research completed by chemical engineers gave rise to the production of products like:
  • Industrial chemicals
  • Ceramics
  • Fuels
  • Agrochemicals
  • Plastics
  • Explosives
  • Detergent products
  • Fragrances and flavors
  • Pharmaceuticals
Because of the known contributions of the products of their research, engineering universities and some companies always look for new discoveries. They usually use current techniques and new design ideas in all aspects of theory, development, and experimentation to come up with useful materials.

New Breakthroughs in Chemical Engineering

To better advance in the field of chemical engineering, new research studies are being started and worked on. For example, students getting a degree in Chemical Engineering in universities yearly work on research ideas. This is where simple and complex discoveries in the field usually come from.
However, studies don’t only come from Chemical Engineering universities. A company with specific goals also starts projects like these through opening chemical engineering jobs. With chemical engineers’ help, they are able to introduce new products for the market, which have proven helpful to the majority of the public.
Though there are already a lot of studies made in the field, some new research ideas are being conceptualized. Some even come from the results of previous studies that need to be improved or redesigned. Some of the topics for research nowadays include:
  1. Distillation and Absorption
  2. Fluid Flow
  3. Heat and Mass Transfer
  4. Materials Processing and Product Development
  5. Oil and Natural Gas Production
  6. Particle Technology
  7. Pharmaceutical Engineering
  8. Process Systems and Software Engineering
  9. Reaction Engineering
  10. Separation Process
All the topics for research may have been touched by previous studies already. However, as the technology advances, more and more demands from the public are challenging the field. This is the reason why chemical engineer jobs focus on discovering new breakthroughs to cater to the needs of the people.
Indeed, the world owes a lot to the results of chemical engineering research. Each individual company and all the chemical engineers behind every project should be thanked for the jobs they are doing. Without their pioneering research, the world’s technology might not be advancing up to the present.

ONGC Previous papers

Thursday, July 21, 2011

Solving The Mystery Of Sugar Chain Growth




Mycobacterium tuberculosis, the microbe responsible for tuberculosis, uses an unusually strong cell wall, fortified with a carbohydrate called galactan, to protect itself from harsh environments and its host's immune system. Sugar polymers like galactan are built by enzymes called glycosyltransferases, which add successive sugar molecules to a chain, like beads on a string. Now researchers have developed an assay based on mass spectrometry to answer a long-standing question about the mechanism of these enzymes (J. Am. Chem. Soc., DOI: 10.1021/ja204448t).
Understanding how M. tuberculosis builds galactan could allow researchers to design drugs that interfere with the process, allowing infected people to mount an effective immune response, says Laura Kiessling, a chemical biologist at the University of Wisconsin, Madison.
Kiessling and her colleagues wanted to know whether GlfT2, one of the glycosyltransferases that synthesize galactan, uses what biochemists call a processive or distributive mechanism. Processive enzymes remain bound to the carbohydrate chain as they add monomers, while distributive enzymes fall off the sugar chain after each addition and then bind another chain. Drug designers would like to exploit such a mechanistic understanding in developing enzyme inhibitors, Kiessling says.
To distinguish between the two mechanisms, the researchers designed an assay that detects how often GlfT2 swaps polymer partners during elongation of the sugar chain. Initially, the team exposed GlfT2 to a lipid-linked oligosaccharide that mimics the base of the growing galactan chain. After allowing the enzyme to bind this molecule and start adding sugar monomers, the scientists introduced a deuterium-labeled version of the lipid-linked molecule. After the enzyme continued working to add monomers, the researchers analyzed the reaction products with matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry to measure the length of the sugar chains and to determine whether or not they were labeled with deuterium.
Kiessling expected that if the enzyme was processive, the longest carbohydrate chains would be unlabeled, because the enzyme would tightly latch onto the initial, unlabeled base molecule and wouldn't get distracted when the labeled one appeared. In contrast, a distributive mechanism would produce labeled and unlabeled carbohydrate chains of roughly equal lengths because the two lipid-linked molecules would have equal access to the enzyme each time it fell off a chain.
When Kiessling and her colleagues examined the mass spectrometry data, they found that none of the longest chains were labeled, suggesting to them that GlfT2 used a processive mechanism. Moreover, the researchers quantified the degree of processivity, or the probability that an enzyme bound to the chain would add another sugar before it fell off the chain. They determined that GlfT2's processivity increased as the sugar chain grew, suggesting that the enzyme, like some other polymer-building enzymes, binds more tightly to longer chains.

"This elegant, straightforward approach will be widely used by researchers studying carbohydrate polymerization, and could be applied to other polymers as well," says Todd Lowary, a chemist at the University of Alberta. The knowledge that GlfT2 shows greater affinity for longer sugar chains could be used to design inhibitors for use as antibiotics, he adds, although a crystal structure of the enzyme would better aid drug design.
Chemical & Engineering News
ISSN 0009-2347
Copyright © 2011 American Chemical Society