Will “Atomic Spectroscopist” be Replaced By Robots? 🤔

Job Description

Conduct research into physical phenomena, develop theories on the basis of observation and experiments, and devise methods to apply physical laws and theories.

Job Details

• The SOC (Standard Occupational Classification) code is 19-2012.00
• The Mean Annual Wage in the U.S. is $ 121,770.00
• The Mean Hourly Wage is $ 58.00
• Currently, there are 16,680 people on this job

☝️ Information based on the reference occupation “Physicists”.

Also Known As…

• Physicists
• Scientist
• Research Scientist
• Research Physicist
• Research Consultant
• Physicist
• Health Physicist
• Biophysics Scientist
• Weapons Engineer
• Weapons Designer
• Thermodynamicist
• Thermodynamic Physicist
• Theoretical Physicist
• Space Physicist
• Scientist Electronics
• Rocket Scientist
• Rheologist
• Research Professor
• Radiation Protection Technician
• Radiation Control Health Physicist
• Physics Professor
• Physical Aerodynamicist
• Optical Scientist
• Optical Instrument Specialist
• Nuclear Spectroscopist
• Nuclear Scientist
• Nuclear Physicist
• Nanotechnologist
• Molecular Spectroscopist
• Molecular Physicist
• Medical Physicist
• Mathematical Physicist
• Mass Spectroscopist
• Laser Engineer
• Fluid Dynamicist
• Experimental Physicist
• Electrodynamicist
• Electro-Optical Engineer
• Electro Optical Engineer
• Consultant Electronics
• Cloud Physicist
• Atmospheric Physicist
• Astrophysicist
• Aerophysicist
• Aerodynamicist

Tasks for “Atomic Spectroscopist”

• Perform complex calculations as part of the analysis and evaluation of data, using computers.
• Teach physics to students.
• Report experimental results by writing papers for scientific journals or by presenting information at scientific conferences.
• Conduct research pertaining to potential environmental impacts of atomic energy-related industrial development to determine licensing qualifications.
• Observe the structure and properties of matter, and the transformation and propagation of energy, using equipment such as masers, lasers, and telescopes to explore and identify the basic principles governing these phenomena.
• Advise authorities of procedures to be followed in radiation incidents or hazards, and assist in civil defense planning.
• Design computer simulations to model physical data so that it can be better understood.
• Develop standards of permissible concentrations of radioisotopes in liquids and gases.
• Describe and express observations and conclusions in mathematical terms.
• Collaborate with other scientists in the design, development, and testing of experimental, industrial, or medical equipment, instrumentation, and procedures.
• Conduct application evaluations and analyze results to determine commercial, industrial, scientific, medical, military, or other uses for electro-optical devices.
• Direct testing and monitoring of contamination of radioactive equipment, and recording of personnel and plant area radiation exposure data.
• Develop manufacturing, assembly, and fabrication processes of lasers, masers, infrared, and other light-emitting and light-sensitive devices.
• Analyze data from research conducted to detect and measure physical phenomena.
• Develop theories and laws on the basis of observation and experiments, and apply these theories and laws to problems in areas such as nuclear energy, optics, and aerospace technology.

Related Technology & Tools

• Optical beamsplitting devices
• High-resolution semiconductor detectors
• Helium lasers
• Scintillation probes
• Pistonphones
• Desktop computers
• Prism spectrometers
• Scanning electron microscopes SEM
• Microwave interferometers
• Helium refrigerators
• Semiconductor parameter analyzers
• Single frequency dye lasers
• Signal generators
• Optical choppers
• Gas chromatography GC injectors
• Neutron detectors
• Conditioning amplifiers
• Geiger-Muller counters
• High-speed video cameras
• Headspace autosamplers
• High intensity UV sources
• Optical tweezers
• Vibrating sample magnetometers
• High vacuum equipment
• Charge-coupled device CCD cameras
• Grating monochromators
• Gamma ray spectrometers
• Programmable phase modulators
• Laser power meters
• Gaussmeters
• Ionization chambers
• Isotope ratio mass spectrometers
• Annealing furnaces
• Diffusion-pumped vacuum systems
• High-energy accelerators
• Spectrum analyzers
• Atomic absorption AA spectrometers
• Nanovoltmeters
• Atomic force microscopes
• Measuring microscopes
• Cyclotrons
• Argon ion lasers
• Laboratory tube furnaces
• Zeeman split lasers
• High-resolution spectrometers
• Digital plotters
• X ray photoemission spectrometers
• Friction-force microscopes
• Surface profilometers
• Digital multimeters
• Vibration exciters
• Diode lasers
• Scanning tunneling microscopes STM
• Monochromators
• Two-channel network analyzers
• Sound intensity probes
• Radiation detecting film badges
• Personal computers
• Safety goggles
• Power amplifiers
• Atomic emission detectors AED
• Portable fast Fourier transform FFT analyzers
• Optical tables
• Double monochromators
• Galvanostats
• Pinhole filters
• Visible spectrometers
• Scanning monochromators
• Liquid helium level sensors
• Interferometers
• Fourier transform infrared FTIR spectrometers
• Laptop computers
• Vernier force sensors
• Function generators
• Multiple diode lasers
• Big G torsion balances
• Digital voltmeters DVM
• Analog frequency analyzers
• Telescopes
• Nuclear magnetic resonance NMR spectroscopes
• Gas chromatography equipment
• Magnetic resonance imaging MRI systems
• Photometers
• Optical detectors
• Laboratory box furnaces
• Light scattering devices
• Turbo-pumped vacuum systems
• Digital oscilloscopes
• Photon counting systems
• Particle counters
• X ray crystallography equipment
• Radiofrequency RF generators
• Computed tomography CT scanners
• Linear accelerators
• Magnetic force microscopes
• Photodetectors
• Diffusion pumps
• Analog sound level meters
• Positive ion accelerators
• Two-channel dynamic signal analyzers
• Pulsed nitrogen lasers
• Mass spectrometers
• Cryostats
• Thermoluminescent dosimeters
• Transmission electron microscopes TEM
• Two-channel fast Fourier transform FFT analyzers
• Leak detection equipment
• Laboratory electromagnets
• Spring scales
• Mickelson interferometers
• Cavity dumpers or drivers
• Analytical balances
• Vacuum stations
• Spectrophotometers
• Accelerometers
• Electron microscopes
• Arbitrary function generators
• Digital sound level meters
• Laboratory centrifugal pumps
• Capacitance bridges
• Betatrons

• GNU Octave
• Aptech Systems GAUSS
• MySQL
• Spectroscopy software
• Adobe Systems Adobe Audition
• Wolfram Research Mathematica
• Synergy Software KaleidaGraph
• GNU Image Manipulation Program GIMP
• Sun Microsystems Java
• Microsoft Visual Basic
• Scribus
• The MathWorks MATLAB
• Gnuplot
• Vector Fields OPERA-3d
• C
• Experimental Physics and Industrial Control System EPICS
• Video analysis software
• Assembler
• JavaScript
• SciGraphica
• Pascal
• Microsoft Excel
• Systat Software SigmaPlot
• Radiation dose calculation software
• CERN Physics Analysis Workstation PAW
• Xfig
• OriginLab Origin
• Maplesoft Maple
• Microsoft Access
• SciLab
• COMSOL Multiphysics
• Practical extraction and reporting language Perl
• Microsoft Visual J++
• Statistical software
• Ploticus
• Microsoft PowerPoint
• Linux
• Dose modeling software
• REDUCE
• Microsoft Word
• Lenox Softworks VideoPoint
• RibbonSoft QCad
• UNIX
• XV
• CERN ROOT
• Criss Software XRF11
• Microsoft Office
• SQLite
• Mathsoft Mathcad
• RSI interactive data language IDL software
• Formula translation/translator FORTRAN
• Microsoft Visual C++
• National Instruments LabVIEW
• Autodesk AutoCAD
• Spectral Dynamics STAR
• Python
• Adobe Systems Adobe Photoshop