The Department of Fuel Minerals and Metallurgical Engineering is one of the institute's oldest departments, having been formed in 1976 to handle metallic, non-metallic, and fuel mineral processing concerns. Metallurgical Engineering was added to the department in order to keep up with modern research trends, industrial requirements, and to promote high-end multidisciplinary research. Currently, the department offers a BTech in Mineral and Metallurgical Engineering, as well as two-year MTech and PhD programmes in Fuel Engineering and Mineral Engineering. In the near future, an APhD programme in Metallurgical Engineering will be launched. The Central Research Facility (CRF) and Central Workshop enhance the departmental facilities. There are now 33 doctorate students and one post-doctoral fellow on staff. Because the difficulties in the mineral processing and process metallurgy industries are multi-faceted, creative minds and multidimensional research facilities are required to approach and solve them. With this purpose in mind, the department is actively involved in addressing industrial concerns through research in several areas of fuel. Clean Coal Technology (CCT), Coal and Mineral Processing, Metallurgy, and Bio-mass Application are all mineral and process metallurgical areas. The department's purpose is to lead the country in mineral, metallurgy, and fuel research and development by supplying skilled technical staff, developing research directions, and offering technical consulting to industry partners. Use our paraphrasing tool which is the best tool for sentence rephrasing and essay rewriting.

The department studies all aspects of coal preparation, carbonization, and combustion, as well as mineral processing and process metallurgy, including agglomeration. Faculty members have extensive knowledge and experience developing process flowsheets for both metallic and non-metallic materials. Faculty members have written monographs, contributed chapters to internationally acclaimed books, and published their research findings in internationally and nationally acclaimed periodicals. Several patents for inventions that benefit industrial needs have been obtained. Get access our amazing Grammer checker tool

For a significant number of international and domestic industrial partners, the department is actively engaged in delivering technical advises and consulting projects. Tata Steel, SAIL, BHEL, CESC, McNally Bharat, Coal India Ltd. subsidiaries, NTPC, UCIL, CDE Asia, SGS, West Bengal Power Development Corporation, Delloite, PwC, and others are among them. All industrial processes that turn raw materials into functional products tailored to human requirements involve metallurgical and materials engineering. The Metallurgical and Materials Engineering program's major purpose is to equip students with a fundamental understanding of materials processing, characteristics, and selection and application. Use our Free Plagiarism checker tool

The department's focus is on materials processing operations, which include: converting mineral and chemical resources into metallic, ceramic, or polymeric materials; synthesis of new materials; refining and processing to produce high performance materials for applications ranging from consumer goods to automobiles, aerospace, and electronics; and the evolution of materials' mechanical, chemical, and physical qualities in relation to their processing and structure; and the selection of materials for certain purposes.

One of the strongest departments on campus is the MME Department. With high graduate enrolment, extraordinarily good funded research programmes, and expanding undergraduate enrollment, it has achieved all of its Pathways 2024 targets as early as FY19. The professors of the Department should be commended for their efforts.” -Mike Kaufman, Paul Johnson, and Tom Boyd.

Metallurgy is a branch of materials science and engineering that examines the physical and chemical properties of metallic elements, intermetallic compounds, and alloy mixes. Metallurgy refers to both the science and the technology of metals, or the application of science to the manufacture of metals. Metallurgy is distinct from metalworking as a craft. Metalworking is dependent on metallurgy in the same way that medicine is dependent on medical science for technological growth. A metallurgist is an expert in the field of metallurgy.

Chemical metallurgy and physical metallurgy are the two primary categories that make up the science of metallurgy. Chemical metallurgy is primarily concerned with metal reduction and oxidation, as well as metal chemical properties. Mineral processing, metal extraction, thermodynamics, electrochemistry, and chemical degradation (corrosion) are all topics covered in chemical metallurgy. Physical metallurgy, on the other hand, is concerned with metals' mechanical properties, physical qualities, and physical performance. Crystallography, material characterization, mechanical metallurgy, phase transitions, and failure mechanisms are some of the topics addressed in physical metallurgy.

Metallurgy has always been associated with the manufacture of metals. Metal manufacturing begins with the extraction of metal from ores and includes the mixing of metals to create alloys. Metal alloys are usually made up of at least two different metals. Non-metallic elements, on the other hand, are frequently added to alloys in order to attain qualities that are suited for a given purpose. Ferrous metallurgy (sometimes known as black metallurgy) and non-ferrous metallurgy are two branches of metal manufacturing research (also known as coloured metallurgy). Non-ferrous metallurgy deals with processes and alloys based on other metals, whereas ferrous metallurgy deals with processes and alloys based on iron. Ferrous metals account for 95 percent of all metal production worldwide.

As part of an interdisciplinary team with material scientists and other engineers, modern metallurgists work in both developing and conventional domains. Mineral processing, metal production, heat treatment, failure analysis, and metal joining are some of the classic topics (including welding, brazing, and soldering). Metallurgy comes from the Ancient Greek metallourgós, which means "worker in metal," and is derived from v, métallon, "mine, metal" + érgon, "labour." The ending -urgy denoted a process, notably manufacturing, and the word was treated in this meaning in the 1797 Encyclopaedia Britannica. 

The method of extracting valuable metals from an ore and refining the retrieved raw metals into a purer form is known as extractive metallurgy. The ore must be reduced physically, chemically, or electrolytically to convert a metal oxide or sulphide to a purer metal. Feed, concentrate (metal oxide/sulphide), and tailings are the three basic streams that extractive metallurgists are interested in (waste). After mining, big chunks of ore feed are crushed or ground into minute particles, with each particle containing either mostly valuable or mostly waste material. The needed metal can be extracted from waste products by concentrating the valuable particles in a condition that allows for separation.

If the ore body and physical environment are suited to leaching, mining may not be necessary. Minerals in an ore body are dissolved by leaching, resulting in an enriched solution. To extract valuable metals, the solution is collected and treated. Ore bodies frequently contain multiple precious metals.

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