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Would you like to apply your arts or applied sciences background to the conservation of fine art?. Northumbria University’s MA Conservation of Fine Art course is the only Master of Arts course in the UK that specialises in the conservation of easel painting and works of art on paper. Read more
Would you like to apply your arts or applied sciences background to the conservation of fine art?

Northumbria University’s MA Conservation of Fine Art course is the only Master of Arts course in the UK that specialises in the conservation of easel painting and works of art on paper.

Integrating a mix of fine art, science and forensic techniques, you will study a range of subjects including studio and work-based practice, conservation theory, science, technical examination, -preventive conservation and research training skills.

In addition to the core modules studied, you will have the option to undertake a work placement during years one and two in the UK or abroad.

Learn From The Best

This course is taught by a team of specialist academics who have extensive experience in the field of conservation, science and the Fine Art sectors.

Applying their specialist knowledge to their day-to-day teaching, the members of our staff are actively involved in research and consultancy - activities which are helping to define this exciting and complex profession.

We also engage with the wider conservation sector to ensure that the content of this course is in-line with professional standards and employer expectations.

Throughout the duration of this course you will receive ongoing support from our teaching staff to ensure you leave equipped with - the necessary skills and knowledge to successfully pursue a career within conservation or a related discipline.

Teaching And Assessment

Offering the opportunity for you to specialise in either works of art on paper or easel paintings conservation, this course consists of modules that will explore a range of key areas including conservation theory and practice, conservation science, art history and preventive conservation

You will leave with the technical skills required to undertake examinations, cleaning, structural repairs and stabilisation of works of art, in addition to an in-depth understanding of the historic significance artistic practice and materials play-in understanding artworks.

Significant emphasis is also placed on ethics and developing your skills in research development.

This course is primarily delivered through practical workshops where you will develop a wide range of skills using especially prepared materials and case studies selected from our unique archive collection. These activities inform and run parallel with work conducted on project paintings and other challenging artefacts.

Assessment methods focus on you applying your practical skills, academic concepts and theories to your project documentation and the authentically constructed materials that mirror real life scenarios. You will also undertake a dissertation to further demonstrate your knowledge and understanding of this subject.

Learning Environment

When studying the MA Conservation of Fine Art course you will be housed in a Grade II listed building in the heart of Newcastle city centre. You will be able to utilise techniques such as x-ray, infra-red reflectography, and ultraviolet florescence and false colour infrared photography to examine materials and artworks spanning centuries, in addition to gaining access to intriguing archives and cutting edge technology.

You may also have access to other advanced technologies such as UV fluorescence microscopy, polarised light microscopy (PLM), UV/VIS spectrophotometry, fourier transform infrared (FTIR), gas chromatography-mass spectrometry (GC-MS), high performance liquid chromatography (HPLC), x-ray fluorescence (XRF) spectroscopy, x-ray diffraction (XRD) and scanning electron microscopy coupled with energy-dispersive x-ray spectroscopy (SEM/EDX).

You will also receive ongoing support through our innovative e-learning platform, Blackboard, which will allow you to access learning materials such as module handbooks, assessment information, online lectures, reading lists and virtual gallery tours.

Research-Rich Learning

Research-rich learning is embedded throughout all aspects of this course and our staff are continuously involved and informed by fast-moving emerging developments in conservation research and ethical debates.

All of our staff possess individual specialisms, in areas such as the development and evaluation of conservation treatments for paintings, characterisation of artists’ materials and techniques, studies in material deterioration and comprehensive documentation of works of art.

Our team also collaborate with national and international research organisations.

When studying this master’s degree, you are encouraged to develop your own individual research skills to ensure you graduate with confidence in your own practical and academic experience. These skills are further enhanced when you undertake your dissertation under the guidance of your assigned tutor.

Give Your Career An Edge

This course has been developed to reflect national guidelines and ensure that you graduate with the necessary skills and knowledge to kick-start your career within this profession. There are also many additional opportunities available to further enhance your career edge whilst you study.

Throughout the duration of this course you will create a professional portfolio, which will include examples of practical work and displays of your intellectual achievement to provide a demonstration of your skills and enhance your performance at interviews.

In addition to completing a placement to further enhance your development you will also have the opportunity to present research papers at an organised symposium.

We actively encourage you to engage with professional bodies and attend key conferences to allow you to network with professionals who are already working within the profession, and you may also have the opportunity to advantage of our partnership with Tyne and Wear Archives and Museums, whose collection supports a number of activities. Our long standing links with the National Trust, Tate Britain and the estate of Francis Bacon have created exciting projects for our MA and PhD students.

Your Future

This course will equip you with a deep understanding of both the skills and knowledge required to work effectively in fine art conservation laboratories or conservation jobs across the world.

You may choose to work in galleries or museums, or progress your research to PhD level.

Recent illustrious alumni list, include Virginia Lladó-Buisán Head of Conservation & Collection Care Bodleian Libraries, Britta New, Paintings Conservator at the National Gallery in London and Eleanor Hasler, Head of Paper Conservation at Kew Gardens.

As your professional development is in-line with the current postgraduate professional standards for the Conservation of Fine Art, your access to postgraduate professional jobs within the conservation sector is likely to be enhanced.

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The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. Read more
The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. The course consists of an intense program of lectures and workshops, followed by a short project and dissertation. Extensive use is made of the electronic learning environment "Blackboard" as used by NUI Galway. The course has been accredited by the Institute of Physics and Engineering in Medicine (UK).

Syllabus Outline. (with ECTS weighting)
Human Gross Anatomy (5 ECTS)
The cell, basic tissues, nervous system, nerves and muscle, bone and cartilage, blood, cardiovascular system, respiratory system, gastrointestinal tract, nutrition, genital system, urinary system, eye and vision, ear, hearing and balance, upper limb – hand, lower limb – foot, back and vertebral column, embryology, teratology, anthropometrics; static and dynamic anthropometrics data, anthropometric dimensions, clearance and reach and range of movement, method of limits, mathematics modelling.

Human Body Function (5 ECTS)
Biological Molecules and their functions. Body composition. Cell physiology. Cell membranes and membrane transport. Cell electrical potentials. Nerve function – nerve conduction, nerve synapses. Skeletal muscle function – neuromuscular junction, muscle excitation, muscle contraction, energy considerations. Blood and blood cells – blood groups, blood clotting. Immune system. Autonomous nervous system. Cardiovascular system – electrical and mechanical activity of the heart. – the peripheral circulation. Respiratory system- how the lungs work. Renal system – how the kidneys work. Digestive system. Endocrine system – how hormones work. Central nervous system and brain function.

Occupational Hygiene (5 ECTS)
Historical development of Occupational Hygiene, Safety and Health at Work Act. Hazards to Health, Surveys, Noise and Vibrations, Ionizing radiations, Non-Ionizing Radiations, Thermal Environments, Chemical hazards, Airborne Monitoring, Control of Contaminants, Ventilation, Management of Occupational Hygiene.

Medical Informatics (5 ECTS)
Bio statistics, Distributions, Hypothesis testing. Chi-square, Mann-Whitney, T-tests, ANOVA, regression. Critical Appraisal of Literature, screening and audit. Patient and Medical records, Coding, Hospital Information Systems, Decision support systems. Ethical consideration in Research.
Practicals: SPSS. Appraisal exercises.

Clinical Instrumentation (6 ECTS)
Biofluid Mechanics: Theory: Pressures in the Body, Fluid Dynamics, Viscous Flow, Elastic Walls, Instrumentation Examples: Respiratory Function Testing, Pressure Measurements, Blood Flow measurements. Physics of the Senses: Theory: Cutaneous and Chemical sensors, Audition, Vision, Psychophysics; Instrumentation Examples: Evoked responses, Audiology, Ophthalmology instrumentation, Physiological Signals: Theory Electrodes, Bioelectric Amplifiers, Transducers, Electrophysiology Instrumentation.

Medical Imaging (10 ECTS)
Theory of Image Formation including Fourier Transforms and Reconstruction from Projections (radon transform). Modulation transfer Function, Detective Quantum Efficiency.
X-ray imaging: Interaction of x-rays with matter, X-ray generation, Projection images, Scatter, Digital Radiography, CT – Imaging. Fundamentals of Image Processing.
Ultrasound: Physics of Ultrasound, Image formation, Doppler scanning, hazards of Ultrasound.
Nuclear Medicine : Overview of isotopes, generation of Isotopes, Anger Cameras, SPECT Imaging, Positron Emitters and generation, PET Imaging, Clinical aspects of Planar, SPECT and PET Imaging with isotopes.
Magnetic Resonance Imaging : Magnetization, Resonance, Relaxation, Contrast in MR Imaging, Image formation, Image sequences, their appearances and clinical uses, Safety in MR.

Radiation Fundamentals (5 ECTS)
Review of Atomic and Nuclear Physics. Radiation from charged particles. X-ray production and quality. Attenuation of Photon Beams in Matter. Interaction of Photons with Matter. Interaction of Charged Particles with matter. Introduction to Monte Carlo techniques. Concept to Dosimetry. Cavity Theory. Radiation Detectors. Practical aspects of Ionization chambers

The Physics of Radiation Therapy (10 ECTS)
The interaction of single beams of X and gamma rays with a scattering medium. Treatment planning with single photon beams. Treatment planning for combinations of photon beams. Radiotherapy with particle beams: electrons, pions, neutrons, heavy charged particles. Special Techniques in Radiotherapy. Equipment for external Radiotherapy. Relative dosimetry techniques. Dosimetry using sealed sources. Brachytherapy. Dosimetry of radio-isotopes.

Workshops / Practicals
Hospital & Radiation Safety [11 ECTS]
Workshop in Risk and Safety.
Concepts of Risk and Safety. Legal Aspects. Fundamental concepts in Risk Assessment and Human Factor Engineering. Risk and Safety management of complex systems with examples from ICU and Radiotherapy. Accidents in Radiotherapy and how to avoid them. Principles of Electrical Safety, Electrical Safety Testing, Non-ionizing Radiation Safety, including UV and laser safety.
- NUIG Radiation Safety Course.
Course for Radiation Safety Officer.
- Advanced Radiation Safety
Concepts of Radiation Protection in Medical Practice, Regulations. Patient Dosimetry. Shielding design in Diagnostic Radiology, Nuclear Medicine and Radiotherapy.
- Medical Imaging Workshop
Operation of imaging systems. Calibration and Quality Assurance of General
radiography, fluoroscopy systems, ultrasound scanners, CT-scanners and MR scanners. Radiopharmacy and Gamma Cameras Quality Control.

Research Project [28 ECTS]
A limited research project will be undertaken in a medical physics area. Duration of this will be 4 months full time

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The aim of the course is to provide experience in a wide range of laboratory techniques and enhance specialist knowledge in chemistry. Read more
The aim of the course is to provide experience in a wide range of laboratory techniques and enhance specialist knowledge in chemistry. Research projects may be chosen from any area of computational, physical, inorganic or organic chemistry.

Course components include:
• An advanced chemistry practical unit
• Two research projects in areas of choice
• Taught units in advanced chemistry
• Optional taught units in chemistry, biological sciences and management
• Modules in transferable skills, including scientific presentations and report writing.

Why study Chemistry with us?

- Outstanding facilities: X-ray powder diffraction, single crystal X-ray diffraction, Mass spectrometry, NMR (250/300/400/500 MHz, multinuclear facility)
- Programmes accredited by the Royal Society of Chemistry
- Outstanding publications, substantial grant income from research councils and industrial partners has resulted in a strong demand for our postgraduates and postdoctoral workers

What will I learn?

The MRes is a self-contained qualification, and graduates will be well-suited for posts in all sectors of the chemical industry, including the pharmaceutical industry and government institutions.

Students who complete a MRes degree will be well qualified to proceed to a three-year PhD programme or the MRes can be studied as the first year of our Integrated PhD programme. They should have a competitive edge in relation to undergraduate students applying for doctoral studies.

Career Opportunities

Career opportunities
Recent Bath graduates have gone on to employment or postdoctoral research in the UK, USA (Princeton, Harvard and Yale), the Netherlands, France, Luxembourg, Norway, Brunei and New Zealand.

Employers include the NIST Center for Neutron Research, Tocris, EPSRC and the Royal Society of Chemistry.

Find out more about the department here - http://www.bath.ac.uk/chemistry/

Find out how to apply here - http://www.bath.ac.uk/science/graduate-school/taught-programmes/how-to-apply/

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– Mammography Theory. – Mammography Practice. – Mammography Image Interpretation(double credits). Students may select from other units available in the scheme to identify a route to award. Read more

Course units

– Mammography Theory
– Mammography Practice
– Mammography Image Interpretation(double credits)

Students may select from other units available in the scheme to identify a route to award. For example:
– Specialist Skills Development: Work-based Learning (in the area of choice e.g Breast Ultrasound, Ultrasound guided biopsy & X-ray guided interventional procedures)
– Leadership Skills for Allied Health Professionals
– Understanding Cancer Care and Management for Allied Health Professionals
– An Introduction to Counselling Skills for Health Care Professionals
– Practice Educators Course
– Intravenous Administration of Pharmaceutical Substances for Diagnostic or Therapeutic Purposes
– Understanding Research and Evidence based Practice
– Preparation for Dissertation
– Research Dissertation

Course description

This course is provided through a partnership between LSBU and King’s College Hospital National
Breast Screening Training Centre. Applicants will normally be a HPC registered radiographer, with a relevant professional qualification, or in possession of a first degree in a science, biomedical or health and social care subject. The Mammographic Studies Programme is designed to address the increasingly specialised needs of radiographers for education to underpin professional practice in breast diagnosis. The programme includes provision for developing a high standard of mammography skills, but also caters for those wishing to move into advanced and consultant practice to meet the evolving requirements of breast screening and diagnostic services.

A major feature of this programme is the option for you to pursue specific knowledge and skills development in your area of practice through the use of work-based learning e.g. breast ultrasound, ultrasound guided biopsy and x-ray guided interventional procedures.

Career opportunities

Requirements in respect of Continuing Professional Development (CPD) linked to professional regulation and Knowledge Skills Framework (KSF) requirements, means that flexible
and responsive education and training provision is increasingly important to practitioners and their managers. This programme will assist in developing your career options as a practitioner, or into specialist, advanced and consultant practice, research or management areas.

Professional contacts/industry links

Approved by the College of Radiographers.

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Scientific analysis is a key tool in the interpretation of archaeological artefact and assemblages. Read more
Scientific analysis is a key tool in the interpretation of archaeological artefact and assemblages. This MSc offers detailed training in the use of scientific techniques for the analysis of archaeological and heritage materials, and a solid background in the archaeology and anthropology of technology allowing students to design and implement archaeologically meaningful scientific projects.

Degree information

This degree aims to bridge the gap between archaeology and science by integrating both a detailed training in the use of scientific techniques for the analysis of inorganic archaeological materials and a solid background in the anthropology of technology. By the end of the degree, students should have a good understanding of the foundations of the most established analytical techniques, practical experience in their application and data processing, as well as the ability to design research projects that employ instrumental analyses to address archaeological questions.

Students undertake modules to the value of 180 credits.

The programme consists of one core module (15 credits), four optional modules (75 credits) and a research dissertation (90 credits).

Core modules
-Laboratory and instrumental skills in archaeological science

Optional modules - you are then able to choose further optional modules to the value of 75 credits. At least 15 credits must be made up from the following:
-Technology within Society
-Archaeological Data Science

At least 30 credits must be made up from the following list below:
-Technology within Society
-Archaeological Data Science
-Archaeological Ceramic Analysis
-Archaeological Glass and Glazes
-Archaeometallurgy 1: Mining and Extractive Metallurgy
-Archaeometallurgy 2: Metallic Artefacts
-Geoarchaeology: Methods and Concepts
-Interpreting Pottery
-Working with Artefacts and Assemblages

In order to allow for a flexible curriculum, students are allowed to select up to 30 credits from any of the postgraduate courses offered at the UCL Institute of Archaeology under other Master's degrees.

Dissertation/report
All students undertake an independent research project which culminates in a dissertation of 15,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, practical demonstrations and laboratory work. A popular aspect of this programme is its extensive use of analytical facilities. Assessment is through essays, practicals, projects, laboratory reports and oral presentations depending on the options chosen, and the dissertation.

Careers

Given our strong emphasis on research training, many of our MSc graduates take up further research positions after their degree, and over half of our MSc students progress to PhD research. Their projects are generally concerned with the technology and/or provenance of ceramics, metals or glass in different regions and periods, but most of them involve scientific approaches in combination with traditional fieldwork and/or experimental archaeology.

Some of our graduates are now teaching archaeometry or ancient technologies at different universities in the UK and abroad. Others work as conservation scientists in museums and heritage institutions, or as finds specialists, researchers and consultants employed by archaeological field units or academic research projects.

Employability
Due largely to an unparalleled breadth of academic expertise and laboratory facilities, our graduates develop an unusual combination of research and transferable skills, including critical abilities, team working, multimedia communication, numerical thinking and the use of advanced analytical instruments. On completion of the degree, graduates should be as comfortable in a laboratory as in a museum and or an archaeological site. They become acquainted with research design and implementation, ethical issues and comparative approaches to world archaeology through direct exposure to an enormous variety of projects. The range of options available allows students to tailor their pathways towards different career prospects in archaeology and beyond.

Why study this degree at UCL?

The UCL Institute of Archaeology is the largest and most diverse department of archaeology in the UK. Its specialist staff, outstanding library and fine teaching and reference collections provide a stimulating environment for postgraduate study.

The excellent in-house laboratory facilities will provide direct experience of a wide range of techniques, including electron microscopy and microphone analysis, fixed and portable X-ray fluorescence, X-ray diffraction, infra-red spectroscopy, petrography and metallography under the supervision of some of the world's leading specialists.

The institute houses fine teaching and reference collections that are extensively used by MSc students including ceramics, metals, stone artefacts and geological materials from around the world. In addition, the institute has a wide network of connections to museums and ongoing projects offering research opportunities for MSc students.

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The aim of the course is to provide experience and training in the chemical aspects of the drug discovery process, and involves a combination of lecture-based units, research training and a research project. Read more
The aim of the course is to provide experience and training in the chemical aspects of the drug discovery process, and involves a combination of lecture-based units, research training and a research project.

The course is ideal for someone considering a career in the pharmaceutical industry, or as a stepping stone to a PhD in a related area.

Why study chemistry with us?

- programmes accredited by the Royal Society of Chemistry
- outstanding publications, substantial grant income from research councils and industrial partners has resulted in a strong demand for our postgraduates and postdoctoral workers
- outstanding facilities: X-ray powder diffraction, single crystal X-ray diffraction, Mass spectrometry, NMR (250/300/400/500 MHz, multinuclear facility)

Visit the website - http://www.bath.ac.uk/science/graduate-school/taught-programmes/msc-chemistry-drug-discovery/

At a glance

Our drug discovery postgraduate course gives students an understanding of the development of new drugs; from the cellular processes that are important to target, through to the synthesis of new medicinal compounds. You will be given advanced training in our teaching laboratories, which will lead to your individual Masters Drug Discovery research project.

The course is made up of three semesters over 12 months. Over this time students cover 90 credits worth of units, which include 12 credits of optional units per semester.

The first two semesters consist of taught material, including Advanced Practical Laboratories, with exams at the end of each semester.

The third semester is focused on the student’s practical project which is carried out in our research labs.

Career Opportunities

Career opportunities
Recent Bath graduates have gone on to employment or postdoctoral research in the UK, USA (Princeton, Harvard and Yale), the Netherlands, France, Luxembourg, Norway, Brunei and New Zealand.

Employers include the NIST Center for Neutron Research, Tocris, EPSRC and the Royal Society of Chemistry.

Find out how to apply here - http://www.bath.ac.uk/science/graduate-school/taught-programmes/how-to-apply/

Find out about the department here - http://www.bath.ac.uk/chemistry/

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Research degrees may be undertaken in the three main areas of research interest in the Laboratory. The growing number of academic staff are supported in their research by the technical staff and post-doctoral research fellows. Read more
Research degrees may be undertaken in the three main areas of research interest in the Laboratory. The growing number of academic staff are supported in their research by the technical staff and post-doctoral research fellows.

We make every attempt to allocate you to a supervisor directly in your field of interest, consistent with available funding and staff loading. When you apply, please give specific indications of your research interest – including, where appropriate, the member(s) of staff you wish to work with – and whether you are applying for a studentship or propose to be self-funded.

Visit the website https://www.kent.ac.uk/courses/postgraduate/212/physics

About The School of Physical Sciences

The School offers postgraduate students the opportunity to participate in groundbreaking science in the realms of physics, chemistry, forensics and astronomy. With strong international reputations, our staff provide plausible ideas, well-designed projects, research training and enthusiasm within a stimulating environment. Recent investment in modern laboratory equipment and computational facilities accelerates the research.

The School maintains a focus on progress to ensure each student is able to compete with their peers in their chosen field. We carefully nurture the skills, abilities and motivation of our students which are vital elements in our research activity. We offer higher degree programmes in chemistry and physics (including specialisations in forensics, astronomy and space science) by research. We also offer taught programmes in Forensic Science, studied over one year full-time, and a two-year European-style Master’s in Physics.

Our principal research covers a wide variety of topics within physics, astronomy and chemistry, ranging from specifically theoretical work on surfaces and interfaces, through mainstream experimental condensed matter physics, astrobiology, space science and astrophysics, to applied areas such as biomedical imaging, forensic imaging and space vehicle protection. We scored highly in the most recent Research Assessment Exercise, with 25% of our research ranked as “world-leading” and our Functional Materials Research Group ranked 2nd nationally in the Metallurgy and Materials discipline.

Study support

- Postgraduate resources

The University has good facilities for modern research in physical sciences. Among the major instrumentation and techniques available on the campus are NMR spectrometers (including solutions at 600 MHz), several infrared and uvvisible spectrometers, a Raman spectrometer, two powder X-ray diffractometers, X-ray fluorescence, atomic absorption in flame and graphite furnace mode, gel-permeation chromatography, gaschromatography, analytical and preparative highperformance liquid chromatography (including GC-MS and HPLC-MS), mass spectrometry (electrospray and MALDI), scanning electron microscopy and EDX, various microscopes (including hot-stage), differential scanning calorimetry and thermal gravimetric analysis, dionex analysis of anions and automated CHN analysis. For planetary science impact studies, there is a two-stage light gas gun.

- Interdisciplinary approach

Much of the School’s work is interdisciplinary and we have successful collaborative projects with members of the Schools of Biosciences, Computing and Engineering and Digital Arts at Kent, as well as an extensive network of international collaborations.

- National and international links

The School is a leading partner in the South East Physics Network (SEPnet), a consortium of seven universities in the south-east, acting together to promote physics in the region through national and international channels. The School benefits through the £12.5 million of funding from the Higher Education Funding Council for England (HEFCE), creating new facilities and resources to enable us to expand our research portfolio.

The School’s research is well supported by contracts and grants and we have numerous collaborations with groups in universities around the world. We have particularly strong links with universities in Germany, France, Italy and the USA. UK links include King’s College, London and St Bartholomew’s Hospital, London. Our industrial partners include British Aerospace, New York Eye and Ear Infirmary, and Ophthalmic Technology Inc, Canada. The universe is explored through collaborations with NASA, ESO and ESA scientists.

- Dynamic publishing culture

Staff publish regularly and widely in journals, conference proceedings and books. Among others, they have recently contributed to: Nature; Science; Astrophysical Journal; Journal of Polymer Science; Journal of Materials Chemistry; and Applied Optics.

- Researcher Development Programme

Kent's Graduate School co-ordinates the Researcher Development Programme (http://www.kent.ac.uk/graduateschool/skills/programmes/tstindex.html) for research students, which includes workshops focused on research, specialist and transferable skills. The programme is mapped to the national Researcher Development Framework and covers a diverse range of topics, including subjectspecific research skills, research management, personal effectiveness, communication skills, networking and teamworking, and career management skills.

Careers

All programmes in the School of Physical Sciences equip you with the tools you need to conduct research, solve problems, communicate effectively and transfer skills to the workplace, which means our graduates are always in high demand. Our links with industry not only provide you with the opportunity to gain work experience during your degree, but also equip you with the general and specialist skills and knowledge needed to succeed in the workplace.

Typical employment destinations for graduates from the physics programmes include power companies, aerospace, defence, optoelectronics and medical industries. Typical employment destinations for graduates from our forensic science and chemistry programmes include government agencies, consultancies, emergency services, laboratories, research or academia.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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The Department of Metallurgical and Materials Engineering offers a master of science in metallurgical engineering. Visit the website http://mte.eng.ua.edu/graduate/ms-program/. Read more
The Department of Metallurgical and Materials Engineering offers a master of science in metallurgical engineering.

Visit the website http://mte.eng.ua.edu/graduate/ms-program/

The program options include coursework only or by a combination of coursework and approved thesis work. Most on-campus students supported on assistantships are expected to complete an approved thesis on a research topic.

Plan I is the standard master’s degree plan. However, in exceptional cases, a student who has the approval of his or her supervisory committee may follow Plan II. A student who believes there are valid reasons for using Plan II must submit a written request detailing these reasons to the department head no later than midterm of the first semester in residence.

All graduate students, during the first part and the last part of their programs, will be required to satisfactorily complete MTE 595/MTE 596. This hour of required credit is in addition to the other degree requirements.

Course Descriptions

MTE 519 Principles of Casting and Solidification Processing. Three hours.
Overview of the principles of solidification processing, the evolution of solidification microstructure, segregation, and defects, and the use of analytical and computational tools for the design, understanding, and use of solidification processes.

MTE 520 Simulation of Casting Processes Three hours.
This course will cover the rationale and approach of numerical simulation techniques, casting simulation and casting process design, and specifically the prediction of solidification, mold filling, microstructure, shrinkage, microporosity, distortion and hot tearing. Students will learn casting simulation through lectures and hands-on laboratory/tutorial sessions.

MTE 539 Metallurgy of Welding. Three hours.
Prerequisite: MTE 380 or permission of the instructor.
Thermal, chemical, and mechanical aspects of welding using the fusion welding process. The metallurgical aspects of welding, including microstructure and properties of the weld, are also covered. Various topics on recent trends in welding research.

MTE 542 Magnetic Recording Media. Three hours.
Prerequisite: MTE 271.
Basic ferromagnetism, preparation and properties of magnetic recording materials, magnetic particles, thin magnetic films, soft and hard film media, multilayered magnetoresistive media, and magneto-optical disk media.

MTE 546 Macroscopic Transport in Materials Processing. Three hours.
Prerequisite: MTE 353 or permission of the instructor.
Elements of laminar and turbulent flow; heat transfer by conduction, convection, and radiation; and mass transfer in laminar and in turbulent flow; mathematical modeling of transport phenomena in metallurgical systems including melting and refining processes, solidification processes, packed bed systems, and fluidized bed systems.

MTE 547 Intro to Comp Mat. Science Three hours.
This course introduces computational techniques for simulating materials. It covers principles of quantum and statistical mechanics, modeling strategies and formulation of various aspects of materials structure, and solution techniques with particular reference to Monte Carlo and Molecular Dynamic methods.

MTE 549 Powder Metallurgy. Three hours.
Prerequisite: MTE 380 or permission of the instructor.
Describing the various types of powder processing and how these affect properties of the components made. Current issues in the subject area from high-production to nanomaterials will be discussed.

MTE 550 Plasma Processing of Thin Films: Basics and Applications. Three hours.
Prerequisite: By permission of instructor.
Fundamental physics and materials science of plasma processes for thin film deposition and etch are covered. Topics include evaporation, sputtering (special emphasis), ion beam deposition, chemical vapor deposition, and reactive ion etching. Applications to semiconductor devices, displays, and data storage are discussed.

MTE 556 Advanced Mechanical Behavior of Materials I: Strengthening Methods in Solids. Three hours. Same as AEM 556.
Prerequisite: MTE 455 or permission of the instructor.
Topics include elementary elasticity, plasticity, and dislocation theory; strengthening by dislocation substructure, and solid solution strengthening; precipitation and dispersion strengthening; fiber reinforcement; martensitic strengthening; grain-size strengthening; order hardening; dual phase microstructures, etc.

MTE 562 Metallurgical Thermodynamics. Three hours.
Prerequisite: MTE 362 or permission of instructor.
Laws of thermodynamics, equilibria, chemical potentials and equilibria in heterogeneous systems, activity functions, chemical reactions, phase diagrams, and electrochemical equilibria; thermodynamic models and computations; and application to metallurgical processes.

MTE 574 Phase Transformation in Solids. Three hours.
Prerequisites: MTE 373 and or permission of the instructor.
Topics include applied thermodynamics, nucleation theory, diffusional growth, and precipitation.

MTE 579 Advanced Physical Metallurgy. Three hours.
Prerequisite: Permission of the instructor.
Graduate-level treatments of the fundamentals of symmetry, crystallography, crystal structures, defects in crystals (including dislocation theory), and atomic diffusion.

MTE 583 Advanced Structure of Metals. Three hours.
Prerequisite: Permission of the instructor.
The use of X-ray analysis for the study of single crystals and deformation texture of polycrystalline materials.

MTE 585 Materials at Elevated Temperatures. Three hours.
Prerequisite: Permission of the instructor.
Influence of temperatures on behavior and properties of materials.

MTE 587 Corrosion Science and Engineering. Three hours.
Prerequisite: MTE 271 and CH 102 or permission of the instructor.
Fundamental causes of corrosion problems and failures. Emphasis is placed on tools and knowledge necessary for predicting corrosion, measuring corrosion rates, and combining this with prevention and materials selection.

MTE 591:592 Special Problems (Area). One to three hours.
Advanced work of an investigative nature. Credit awarded is based on the work accomplished.

MTE 595:596 Seminar. One hour.
Discussion of current advances and research in metallurgical engineering; presented by graduate students and the staff.

MTE 598 Research Not Related to Thesis. One to six hours.

MTE 599 Master's Thesis Research. One to twelve hours. Pass/fail.

MTE 622 Solidification Processes and Microstructures Three hours.
Prerequisite: MTE 519
This course will cover the fundamentals of microstructure formation and microstructure control during the solidification of alloys and composites.

MTE 643 Magnetic Recording. Three hours.
Prerequisite: ECE 341 or MTE 271.
Static magnetic fields; inductive head fields; playback process in recording; recording process; recording noise; and MR heads.

MTE 644 Optical Data Storage. Three hours.
Prerequisite: ECE 341 or MTE 271.
Characteristics of optical disk systems; read-only (CD-ROM) systems; write-once (WORM) disks; erasable disks; M-O recording materials; optical heads; laser diodes; focus and tracking servos; and signal channels.

MTE 655 Electron Microscopy of Materials. One to four hours.
Prerequisite: MTE 481 or permission of the instructor.
Topics include basic principles of operation of the transmission electron microscope, principles of electron diffraction, image interpretation, and various analytical electron-microscopy techniques as they apply to crystalline materials.

MTE 670 Scanning Electron Microscopy. Three hours
Theory, construction, and operation of the scanning electron microscope. Both imaging and x-ray spectroscopy are covered. Emphasis is placed on application and uses in metallurgical engineering and materials-related fields.

MTE 680 Advanced Phase Diagrams. Three hours.
Prerequisite: MTE 362 or permission of the instructor.
Advanced phase studies of binary, ternary, and more complex systems; experimental methods of construction and interpretation.

MTE 684 Fundamentals of Solid State Engineering. Three hours.
Prerequisite: Modern physics, physics with calculus, or by permission of the instructor.
Fundamentals of solid state physics and quantum mechanics are covered to explain the physical principles underlying the design and operation of semiconductor devices. The second part covers applications to semiconductor microdevices and nanodevices such as diodes, transistors, lasers, and photodetectors incorporating quantum structures.

MTE 691:692 Special Problems (Area). One to six hours.
Credit awarded is based on the amount of work undertaken.

MTE 693 Selected Topics (Area). One to six hours.
Topics of current research in thermodynamics of melts, phase equilibra, computer modeling of solidification, electrodynamics of molten metals, corrosion phenomena, microstructural evolution, and specialized alloy systems, nanomaterials, fuel cells, and composite materials.

MTE 694 Special Project. One to six hours.
Proposing, planning, executing, and presenting the results of an individual project.

MTE 695:696 Seminar. One hour.
Presentations on dissertation-related research or on items of current interest in materials and metallurgical engineering.

MTE 698 Research Not Related to Dissertation. One to six hours.

MTE 699 Doctoral Dissertation Research. Three to twelve hours. Pass/Fail.

Find out how to apply here - http://graduate.ua.edu/prospects/application/

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Innovative pharmaceutical processing technologies are becoming highly important. Read more
Innovative pharmaceutical processing technologies are becoming highly important. This exciting, brand-new interdisciplinary MSc has been developed taking into consideration the requirements of the growing global pharmaceutical industry and the strong infrastructure and expertise available across the School of Life Sciences and the School of Engineering Design and Technology.

The programme is designed to enable you to develop a comprehensive understanding and knowledge in the area of pharmaceutical formulation development and its underpinning science and processing technologies. Particularly notable features include theoretical and practical aspects of advanced analytical methods, Process Analytical Technology (PAT), and Quality by Design (QbD).

It will also facilitate the development of professional skills such as good laboratory practice and transferable skills. Students will receive hands-on experience using technologies such as supercritical fluid processing, hot melt extrusion, nano-milling and characterisation techniques such as X-ray diffractometry, Scanning Electron Microscopy, NIR or NMR and Raman Spectrometry and online rheology.

Overall, this programme will widen your thinking horizons and improve your professional abilities.

Why Bradford?

-Strong interdisciplinary approach provides expertise across pharmaceutical sciences and process engineering
-It provides strong practical and research-based components and exposes students to advanced analytical techniques, in-line spectroscopy, computational techniques and particle engineering techniques
-This course will be supported by the Bradford School of Pharmacy, the Centre for Pharmaceutical Engineering and the Analytical Centre with their state-of-the-art infrastructure and expertise

Modules

Core modules
-Fundamentals of Drug Delivery
-Science of Solid Dosage Form and Advanced Pharmaceutical Technologies
-X-Ray Diffraction
-Critical Appraisal of a Current Topic in Pharmaceutical Sciences
-Process Analytical Technologies (PAT) and Quality by Design (QbD)
-Computational Pharmaceutics and Knowledge Management
-Research Project

Option modules
-Separation Science
-Vibrational Spectroscopy

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

Graduates from the Bradford School of Pharmacy have an excellent employment record, and graduates can rise to be leaders in pharmaceutical organisations and businesses in the UK and around the world.

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There is a growing concern for environmental conservation and sustainable development across the globe. To achieve long-term environmental sustainability, it requires innovative solutions to many problems caused by human. Read more
There is a growing concern for environmental conservation and sustainable development across the globe. To achieve long-term environmental sustainability, it requires innovative solutions to many problems caused by human. These problems include the presence of micropollutants in drinking water, noxious aerosols and fumes in the air, heavy metals and toxic organics in solid wastes that will eventually overwhelm our landfill sites. The scarcity of water resources, the ever-deteriorating air quality in many metropolises, the threat of mounting volumes of waste without suitable disposal sites, and a long list of other critical issues must be resolved through the innovations of scientists and engineers.

Environmental problems are essentially interdisciplinary issues. These issues include the physical process of mixing and dilution, chemical and biological processes, mathematical modeling, data acquisition and measurement. The Environmental Engineering (EVNG) Program offered by the School of Engineering at the Hong Kong University of Science and Technology (HKUST) is one of the most successful interdisciplinary research programs in this field of study. The faculty members are leading experts committed to innovative research in a broad range of environmental engineering areas. The Environmental Engineering Program offers a comprehensive curriculum that provides a solid foundation on which students may build careers in research.

The MPhil program seeks to strengthen students’ knowledge of environmental engineering and to expose them to issues in environmental pollution and conservation, and sustainable development. Students are required to undertake coursework and successfully complete a thesis to demonstrate competence in research.

Research Foci

The program focuses on innovative technologies for different applications in the environmental engineering area and seeks to provide research students with an understanding of effective environmental management strategies.

The main research areas include:
-Innovative Water and Wastewater Treatment Technologies
-Solid/Hazardous Waste Management and Waste Recycling/Reuse
-Contaminated Land and Groundwater Remediation
-Indoor and Outdoor Air Quality
-Environmental Sustainability and Renewable Energy

Facilities

The facilities of the Environmental Engineering Laboratories are divided into standard instruments and advanced stationary equipment, as required for different environmental studies. Standard instruments can provide accurate measurements of routine environmental analyses, such as DO, pH, COD, BOD5, ORP, salinity, conductivity, and turbidity.

Advanced equipment includes: a FTIR system with MIR and DTGS detectors for the analyses of functional groups in solid or non-aqueous liquid samples, total organic halogen with ion chromatography system to measure the amount of TOX in liquid or solid samples, UV/Vis spectrophotometer for measuring absorbance or transmittance of liquid samples, florescence spectrometer for analyzing luminescence samples, programmable tube furnace with three control zones for various degree of combustion of different materials, and BET system for the characterization of surface area and pore volume of solid samples.

A relevant central facility is the Material Characterization and Preparation Facility comprising 10 main research groups: surface science, electron microscopy, scanning probe microscopy, x-ray diffraction, nuclear magnetic resonance, thin film deposition, optical characterization, electrical and magnetic characterization, thermal analysis, and sample preparation. Each research group houses state-of-the-art multidisciplinary instrumentation, supported by a team of experienced staff. Major items include X-ray diffraction systems, transmission electron microscopes, scanning electron microscopes, thin film sputtering and evaporation systems, a multi-technique surface analysis system (XPS Auger, ISS), a TOF-SIMS system, a Dynamic SIMS system, scanning probe microscopes (STM, AFM and MFM), FTIR/Raman spectrometers, thin film measurement systems, thermal analysis instruments.

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With more than 90 faculty members and over 200 graduate students, ours is among the largest and most diverse graduate physics & astronomy programs in the world. Read more
With more than 90 faculty members and over 200 graduate students, ours is among the largest and most diverse graduate physics & astronomy programs in the world. our faculty are seeking outstanding students who are interested in performing advanced research in
pursuit of the MSc and PhD degrees in physics & astronomy. Our faculty are recognized worldwide for leadership and innovation in physics research and in teaching. the Herzberg and Brockhouse Medals, the Premiers Research Excellence Award/Early Researcher award, the Sloan Fellowship, and the Nobel Prize in Physics are some of the awards our faculty have received.

Our students explore physical phenomena from the subatomic world of quarks and quantum foam, to the collective behavior of quantum and soft materials, to the universe of galaxies and brane worlds. We offer collaborative programs in biophysics, quantum
information, and nanotechnology. if you wish to pursue an MSc or PhD in one of our focus areas, or an MSc in theoretical physics though perimeter scholars international, this may be the right graduate program for you.

Facilities

We work collaboratively with the department of physics and astronomy at the university of Waterloo, the perimeter institute for theoretical physics and the institute for Quantum computing. our faculty and students have access to state-of the-art, in-house laboratory facilities including the nuclear Magnetic resonance centre at Guelph, sophisticated X-ray diffraction and scattering equipment, and a suite of instruments used to study biological and soft interfaces. our faculty are guest investigators at international facilities including, the canadian institute for neutron scattering, the tri-university Meson Facility (triuMF), the canadian light source, and several others. our students access telescope time on ground and earth-orbiting telescopes including the hubble space telescope, the chandra X-ray observatory, the Gemini observatories, the herschel telescope, and the alMa telescope.

We have first-rate computing facilities, which enables large-scale numerical simulations, including the shared hierarchical academic research computing network (sharcnet).

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This programme is designed for graduates in chemistry or closely related discipline who wish to contribute to drug development in the pharmaceutical industry. Read more
This programme is designed for graduates in chemistry or closely related discipline who wish to contribute to drug development in the pharmaceutical industry.

The programme provides training in pharmacokinetics, drug metabolism, drug synthesis, methods to identify potential drug targets and drug candidates, and methods to assess the biological activities of drug compounds.

Additional modules cover the key techniques in analytical chemistry used to support the pharmaceutical sciences.

Core study areas include research methods, pharmacokinetics and drug metabolism, drug targets, drug design and drug synthesis, spectroscopy and structural analysis, professional skills and dissertation and a research training project.

Optional study areas include separation techniques, mass spectrometry and associated techniques, innovations in analytical science and medicinal chemistry.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/pharmaceutical-science-medicinal-chemistry/

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Pharmacokinetics and Drug Metabolism
- Drug Targets, Drug Design and Drug Synthesis

Semester 2:
- Spectroscopy and Structural Analysis
- Professional Skills and Dissertation
- Research Training Project

Selected Optional Modules
Semester 1:
- Separation Techniques
- Mass Spectrometry and Associated Techniques

Semester 2:
- Innovations in Analytical Science
- Innovations in Medicinal Chemistry

Assessment

Examination and coursework.

Careers and further study

Careers in a variety of industries, particularly the pharmaceutical and related industries, including drug metabolism, medicinal chemistry (organic synthesis), drug screening (action / toxicity), patents and product registration; also as preliminary study for a PhD.

Scholarships and sponsorship

A number of bursaries and scholarships are available to UK and EU students towards tuition fees (excluding Environmental Studies MSc).
Departmental bursaries, in the form of fee reduction, are available to self-funded international students.
The programmes also benefit from industrial sponsorship which provides support in the form of equipment, materials, presenters and project placements.

Why choose chemistry at Loughborough?

The Department of Chemistry has about 350 students studying taught programmes, including around 50 on MSc courses, 10 postdoctoral research fellows, 50 research students (MPhil / PhD), and 25 academic staff, many of whom have strong links with industry.

In recent years, the Chemistry building has undergone extensive refurbishment and provides modern facilities and laboratories for the teaching and research needs of analytical, organic, inorganic and physical chemistry, as well as specialist laboratories for radiochemistry, environmental chemistry, microbiology and molecular pharmacology.

- Facilities
The Department has a number of specialist instruments and facilities, including: 2 x 400 MHz, 500 MHz and solid-state NMR spectrometers, single crystal and powder X-ray diffractometers, a high resolution inductively coupled plasma mass spectrometer, sector field organic MS, GC-MS and linear ion trap LC-mass spectrometers, ion mobility spectrometers and gas and liquid chromatographs.

- Research
The Department typically has well over 50 research students and a dozen postdoctoral researchers. In addition there are usually around 50 MSc students in the department. Many students come to study from abroad, and there are research students and visitors from all over the world currently studying and carrying out research in the department.
The Department is very well equipped to carry out research spanning all the traditional branches of chemistry (analytical, environmental, inorganic, organic and physical) and which contributes to four active research themes (Energy, Environment, Security and Health).

- Career Prospects
90% of our graduates were in employment and/or further study six months after graduating. Graduates can expect to develop their careers in the pharmaceutical and food industry, analytical and environmental laboratories, public and regulatory utilities, industrial laboratories, or go on to study for a PhD.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/pharmaceutical-science-medicinal-chemistry/

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Developed in response to the Engineering and Physical Sciences Research Council (EPSRC), and after extensive consultation with industry, this programme is designed for graduates in chemistry or closely related disciplines who wish to contribute to drug development and analysis, a process that requires multidisciplinary skills. Read more
Developed in response to the Engineering and Physical Sciences Research Council (EPSRC), and after extensive consultation with industry, this programme is designed for graduates in chemistry or closely related disciplines who wish to contribute to drug development and analysis, a process that requires multidisciplinary skills.

The programme comprises a broad range of modules covering the major aspects of analytical and pharmaceutical chemistry, complemented by studies in transferable and professional skills.

Core study areas include research methods, separation techniques, pharmacokinetics and drug metabolism, spectroscopy and structural analysis, professional skills and dissertation and a research training project.

Optional study areas include mass spectrometry and associated techniques, drug targets, drug design and drug synthesis, sensors, innovations in analytical science and medicinal chemistry.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/analytical-pharmaceutical-science/

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Separation Techniques
- Pharmacokinetics and Drug Metabolism

Semester 2:
- Spectroscopy and Structural Analysis
- Professional Skills and Dissertation
- Research Training Project

Selected Optional Modules
Semester 1:
- Mass Spectrometry and Associated Techniques
- Drug Targets, Drug Design and Drug Synthesis
- Sensors

Semester 2:
- Innovations in Analytical Science
- Innovations in Medicinal Chemistry

Assessment

Examination and coursework.

Careers and further study

The programme is for those who wish to extend their knowledge in a particular area or broaden their field in order to increase their career prospects.

Scholarships and sponsorship

A number of bursaries and scholarships are available to UK and EU students towards tuition fees (excluding Environmental Studies MSc).
Departmental bursaries, in the form of fee reduction, are available to self-funded international students.
The programmes also benefit from industrial sponsorship which provides support in the form of equipment, materials, presenters and project placements.

Why choose chemistry at Loughborough?

The Department of Chemistry has about 350 students studying taught programmes, including around 50 on MSc courses, 10 postdoctoral research fellows, 50 research students (MPhil / PhD), and 25 academic staff, many of whom have strong links with industry.

In recent years, the Chemistry building has undergone extensive refurbishment and provides modern facilities and laboratories for the teaching and research needs of analytical, organic, inorganic and physical chemistry, as well as specialist laboratories for radiochemistry, environmental chemistry, microbiology and molecular pharmacology.

- Facilities
The Department has a number of specialist instruments and facilities, including: 2 x 400 MHz, 500 MHz and solid-state NMR spectrometers, single crystal and powder X-ray diffractometers, a high resolution inductively coupled plasma mass spectrometer, sector field organic MS, GC-MS and linear ion trap LC-mass spectrometers, ion mobility spectrometers and gas and liquid chromatographs.

- Research
The Department typically has well over 50 research students and a dozen postdoctoral researchers. In addition there are usually around 50 MSc students in the department. Many students come to study from abroad, and there are research students and visitors from all over the world currently studying and carrying out research in the department.
The Department is very well equipped to carry out research spanning all the traditional branches of chemistry (analytical, environmental, inorganic, organic and physical) and which contributes to four active research themes (Energy, Environment, Security and Health).

- Career Prospects
90% of our graduates were in employment and/or further study six months after graduating. Graduates can expect to develop their careers in the pharmaceutical and food industry, analytical and environmental laboratories, public and regulatory utilities, industrial laboratories, or go on to study for a PhD.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/analytical-pharmaceutical-science/

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This programme is designed to provide comprehensive training in analytical chemistry and its implementation in a variety of fields including biomedical, pharmaceutical, food and environmental analysis. Read more
This programme is designed to provide comprehensive training in analytical chemistry and its implementation in a variety of fields including biomedical, pharmaceutical, food and environmental analysis.

The programme comprises a broad range of modules covering all the major analytical techniques, complemented by studies in transferable and professional skills, with the option to study aspects of medicinal and pharmaceutical chemistry if desired.

Core study areas include research methods, separation techniques, mass spectrometry and associated techniques, spectroscopy and structural analysis, professional skills and dissertation and a research training project.

Optional study areas include sensors, pharmacokinetics and drug metabolism, drug targets, drug design and drug synthesis and innovations in analytical science.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/analytical-chemistry/

Programme modules

Compulsory Modules
Semester 1:
- Research Methods
- Separation Techniques
- Pharmacokinetics and Drug Metabolism

Semester 2:
- Spectroscopy and Structural Analysis
- Professional Skills and Dissertation
- Research Training Project

Selected Optional Modules
Semester 1:
- Mass Spectrometry and Associated Techniques
- Drug Targets, Drug Design and Drug Synthesis
- Sensors

Semester 2:
- Innovations in Analytical Science
- Innovations in Medicinal Chemistry

Assessment

Examination and coursework.

Careers and further study

Careers in a variety of industries including pharmaceuticals, chemicals, food, environmental management, contract analysis laboratories, public laboratories, regulatory authorities and instrument manufacturers in either technical or marketing functions or preliminary study for a PhD.

Scholarships and sponsorship

A number of bursaries and scholarships are available to UK and EU students towards tuition fees (excluding Environmental Studies MSc).
Departmental bursaries, in the form of fee reduction, are available to self-funded international students.
The programmes also benefit from industrial sponsorship which provides support in the form of equipment, materials, presenters and project placements.

Why choose chemistry at Loughborough?

The Department of Chemistry has about 350 students studying taught programmes, including around 50 on MSc courses, 10 postdoctoral research fellows, 50 research students (MPhil / PhD), and 25 academic staff, many of whom have strong links with industry.

In recent years, the Chemistry building has undergone extensive refurbishment and provides modern facilities and laboratories for the teaching and research needs of analytical, organic, inorganic and physical chemistry, as well as specialist laboratories for radiochemistry, environmental chemistry, microbiology and molecular pharmacology.

- Facilities
The Department has a number of specialist instruments and facilities, including: 2 x 400 MHz, 500 MHz and solid-state NMR spectrometers, single crystal and powder X-ray diffractometers, a high resolution inductively coupled plasma mass spectrometer, sector field organic MS, GC-MS and linear ion trap LC-mass spectrometers, ion mobility spectrometers and gas and liquid chromatographs.

- Research
The Department typically has well over 50 research students and a dozen postdoctoral researchers. In addition there are usually around 50 MSc students in the department. Many students come to study from abroad, and there are research students and visitors from all over the world currently studying and carrying out research in the department.
The Department is very well equipped to carry out research spanning all the traditional branches of chemistry (analytical, environmental, inorganic, organic and physical) and which contributes to four active research themes (Energy, Environment, Security and Health).

- Career Prospects
90% of our graduates were in employment and/or further study six months after graduating. Graduates can expect to develop their careers in the pharmaceutical and food industry, analytical and environmental laboratories, public and regulatory utilities, industrial laboratories, or go on to study for a PhD.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemistry/analytical-chemistry/

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The aim of this MSc programme is to provide advanced training in all major aspects of product design from conceptual design, product modelling to prototyping to a high level of competence. Read more
The aim of this MSc programme is to provide advanced training in all major aspects of product design from conceptual design, product modelling to prototyping to a high level of competence. This programme will train you to develop reliable, high quality products with true market appeal, within the budgets and tight timescales demanded by competitive businesses.

You'll gain detailed expertise in product design's key concepts, tools and methodologies, including:-

innovative product development and design techniques
advanced CAD/CAM and modelling
materials selection
industrial design
rapid prototyping
total quality management
marketing

There's a strong practical element and you'll develop your skills through individual and group projects, using facilities that include:-

CAD (ProE)
CAM (Vericut, Machining Strategist)
rapid prototyping (3D Printing, FDM, SLM and vacuum casting)
reverse engineering (laser scanner and x-ray scanner).

As well as receiving excellent tuition from our world-renowned academics you'll be able to listen to visiting product designers and professors from the Royal Academy of Engineering talk about advanced concepts and case studies.

This programme is fully accredited by the Institution of Mechanical Engineers.

This 12-month programme consists of compulsory and optional taught modules over two semesters and a major design project in the summer. PROJECTS Project work contributes 60 credits, which will be based on a topic of industrial or scientific relevance, and will be carried out in laboratories in the University or at an approved placement in industry. The project is examined by dissertation, and award of the MSc (Eng) degree will require evidence of in-depth understanding, mastery of research techniques, ability to analyse assembled data, and assessment of outcomes.

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