Training Applications of Laser Raman Spectroscopy and the Usage of Molybdenum


Training Course Description

Raman spectroscopy is a non-destructive analytical technique and is used in many different fields where, microscopic, chemical analysis and imaging is needed. Raman analysis can provid_pelatihane both qualitative and/or quantitative information easily and quickly.  It can be used to characterise the chemical composition and structure of the samples regardless of its physical satate, solid_pelatihan, powder, liquid_pelatihan, gas or slurry. Molybdenum and molybdenum-based materials have favorable properties such as good erosion-resistance, excellent thermal and electrical conductivities, high yielding strength and hardness at high temperatures. They are extensively used in various fields including agriculture, energy, military, chemical engineering, bio-medicine and electronics. Due to their unique electronic, optical and mechanical properties, molybdenum-based materials have potential applications in nano devices and functional materials. This course is designed to give information both on various usage of molybdenum and to provid_pelatihane practice and knowledge on Raman spectroscopy and its diverse range of applications. The training wil be in Arabic.

Course Objectives

  • Gain theoretical and practical knowledge on Raman spectrometers
  • Acquire knowledge for method development and analytical parameters
  • Learn how to establish an analytical strategy with an unknown sample
  • Obtain theoretical and practical knowledge on Surface Enhanced Raman Spectroscopy
  • Gain knowledge on interpretation of Raman results
  • Learn about the use of molibdenum and its related compounds in various applications

Who Should Attend?

  • Ph.D. students
  • Technicians
  • Engineers
  • Scientists
  • Laboratory managers

Course Details/Schedule

  • Raman spectroscopy
  • Theory of Raman spectroscopy
  • Instrumentation
  • Principle and advantages of raman spectroscopy
  • Scanning Probe Microscopy and Instrumentation
  • The different modes (AFM, STM, Tuning Fork) and signals
  • Resonance Raman Spectroscopy (RRS)
  • Principle of RRS
  • Key aspects of RRS
  • Instrumentation
  • Seelected Applications
  • Surface enhanced Raman Spectroscopy (SERS)
  • SERS principles
  • Plasmonics
  • Instrumentation
  • Applications
  • Tip Enhanced Raman Spectroscopy
  • Principle and requirements
  • Presentation of the different TERS tips
  • Alignment  of excitation laser on the TERS tip (rough and fine alignment)
  • Optimization of the TERS parameters (spectra and imaging)
  • Applications of Raman Spectroscopy in Chemical sciences
  • Polymers
  • Pharmaceuticals
  • Chemicals
  • Cosmetics
  • Optimization
  • Applications of Raman spectroscopy in Materials science
  • Carbon
  • Nano-materials
  • Semiconductors
  • Photovoltaics
  • Catalysis
  • Battery technology
  • Practical session: selection and optimization of parameters for Raman analysis and to perform data process
  • Description of the instrument
  • Alignment of the laser, the laser power, the grating, and the confocal hole
  • Methods of measurements
  • Generating a Raman spectrum
  • Generating a Raman image
  • Data evaluation
  • Applications in Analytical sciences
  • Investigations of art and cultural heritages
  • Contaminant id_pelatihanentification
  • Forensics
  • Food and Beverage
  • Applications in Life Sciences
  • Rapid_pelatihan micro-organism id_pelatihanentification
  • Cell biology
  • Tissue analysis
  • Applications in Earth sciences
  • Geological samples
  • Gemstone analysis
  • Introduction on Nano Technology
  • Meaning, Definition & Examples
  • Historical overview
  • General Uses of nanotechnology
  • Lessons from Nature
  • Overview of Research in Nanotechnology
  • Applications of Nano Technology
  • Energy
  • Medicine & Drugs
  • Nano Biotechnology
  • Nano Devices
  • Optical Engineering
  • Bio Engineering
  • Fabrics
  • Materials of Nano Technology
  • Types of Nano Materials
  • Properties of nanomaterial:
  • Physical/Chemical/Magnetic/Thermal/Optical/Electrical
  • One-Dimensional nanomaterial
  • Two-dimensional nanomaterial
  • Three-dimensional nanomaterial
  • Approaches & Synthesis of nanomaterials
  • Top-down
  • Bottom-up
  • Examples of nanomaterial
  • Molybdenum
  • Molybdenum and related compounds (Mo) – Properties and Applications
  • Molybdenum use by material (metal, Stainless steel, Alloy steels, Super alloy steels)
  • Molybdenum use by industry sector (Chemical, Pharmaceutical, and others)
  • Molybdenum Disulfid_pelatihane Nanoparticles
  • Molybdenum oxid_pelatihane nanowires
  • Molybdenum Nanopowder / Nanoparticles
  • General Discussion
  • Pitfalls of Nano technology
  • Issues & Future Directions
  • Nano Technology Journals & Conferences
================================================================================ General Notes All our courses can be facilitated as Customized In-House Training course. Course duration is flexible and the contents can be modified to fit any number of days. As for Open Enrolment Courses, we offer our clients the flexibility to chose the location, date, and time and our team of experts who are spread around the globe will assist in facilitating the course. The course fee includes facilitation, training materials, 2 coffee breaks, buffet lunch and a Certificate of successful completion of Training. FREE Consultation and Coaching provid_pelatihaned during and after the course. VENUE Yogyakarta, Jakarta, Bandung, Bogor, Cirebon, Solo, Semarang, Surabaya, Malang, Bali, Lombok, Samarinda, Balikpapan, Banjarmasin, Pontianak, Makassar, Medan, Palembang, Lampung, serta Timor Leste, Thailand, Singapore, dan Kuala Lumpur (dengan harga dan minimal kuota yang berbeda). Permintaan Brosur penawaran Training Pelatihan ( Harga, Waktu dan Tempat) silahkan Menghubungi kami.