When i was in Medical school in the 1970's in India, my understanding interaction was limited to seeing a picture of a large instrument labeled Electron Microscope.
like the one shown below.
there was just one instrument in the whole state!
the first time i actually saw and touched one was when My elder brother who is a materials scientist in Houston Texas showed me the new SEM (Scanning electron Microscope his company bought and established a brand new materials research lab or a small private company dealing with Super hard materials used in oil drilling bits..
To see various metals and actually measure how much carbon iron Nickel etc are present in the specimens was like living Science fiction.
We used to see a few photographs of SEM pictures of some human tissues
like the ones below was all I was aware of.
How much progress has happened in just 3 decades?
now see we have bench top SEM
Efficiency has emerged as a top priority for labs in considering, not just the space issue, but for equipment performance, ease of use and maintenance, and compatibility with data processing streams as well. When it comes to high complexity analytical instruments, there is always a balance between performance and efficiency. This is particularly applicable to the electron microscope, a technology that has traditionally been associated with large, complex, custom suited facilities – a concept that runs in direct contrast to this new age of downsized efficiency
The scanning electron microscope or SEM microscope has evolved to meet many of the requirements discussed above. The instrument and accessories have been effectively miniaturized to benchtop scale without sacrificing the features that make the technology powerful for so many research applications.
SEM was commercialized in the 1960's, and since then has assisted researchers in exploring novel frontiers in biology and material science, uncovering a miniature world previously unknown to optical microscopy. There was traditionally a divide between the two techniques, optical versus electron microscopy. Tissue or live cells were imaged by light microscopy, and then prepared through rigorous sample treatment methods prior to more laborious SEM imaging.
Introduction of the NeoScope technology from JEOL instruments supported a new concept that complemented both optical microscopes and traditional SEMs in the lab. The technology brought SEM to the benchtop while enabling seamless integration of optical microscope features into a higher resolution platform with up to 60,000X magnification. The same samples that are examined via light microscopy can be interrogated with much higher depth of field and resolution, importantly without additional extensive sample preparation. Many optical microscope features such as simplicity of use and size footprint are maintained while offering advanced settings for pre-screening of biological and composite samples and others – applications which were traditionally the domain of larger SEM instruments.
The new JEOL JCM-6000 NeoScope Versatile Benchtop SEM features a modern design with state-of-the-art features. Operation is via a touchscreen and is simplified with auto focus, auto alignment, auto contrast, and auto brightness controls. The instrument functions under both low and high vacuum modes with three settings for voltage acceleration. These features enable a variety of applications which can be programmed via pre-stored recipe files.
This new NeoScope offers both an Everhart Thornley type SE detector as well a high sensitivity solid state back scattering electron (BSE) detector. A full-featured Energy-dispersive X-ray Spectroscopy (EDS) with SDD technology is available for advanced analytical applications.
This NeoScope SEM microscope incorporates many important features and
functions that make it both an efficient and powerful device. The
touchscreen access and easy to use application software make it
accessible by a variety of users and streamlined for processing of rich
sample throughput and data streams. Tilting and rotating functions
permit viewing at different angles, resulting in 3-D information on the
sample. Many additional capabilities make this platform valuable for a
variety of uses from neuroscience, to materials science, to
manufacturing processes.
Whether used by trained electron microscopists as a simple screening instrument, or by lab technicians as a higher resolution alternative to the light microscope, the NeoScope accelerates the overall pace of research as is a model of imaging efficiency.
View JEOL NeoScope listings on LabX.com
The resolution of the electron microscope, scanning electron magnification, sem microscope uses, and specimen preparation for scanning electron microscopy are topics for other articles. Take a closer look at the LabX microscopy resources for more insight:
like the one shown below.
there was just one instrument in the whole state!
the first time i actually saw and touched one was when My elder brother who is a materials scientist in Houston Texas showed me the new SEM (Scanning electron Microscope his company bought and established a brand new materials research lab or a small private company dealing with Super hard materials used in oil drilling bits..
To see various metals and actually measure how much carbon iron Nickel etc are present in the specimens was like living Science fiction.
We used to see a few photographs of SEM pictures of some human tissues
like the ones below was all I was aware of.
How much progress has happened in just 3 decades?
now see we have bench top SEM
Versatile and Efficient Benchtop Scanning Electron MicroscopesMicroscopy | Buying Guide | Technical Insight | microscope |
Downsizing has been a recent and growing trend in laboratory equipment. Not necessarily in the number or the scope of the instruments, rather, in the size of the instruments and the physical space in which they must operate. This is due to several reasons including the fact that laboratory space is becoming a precious commodity for cost reasons, forcing research staff to produce more and occupy less. In contrast, many labs are expanding both the number of instruments and the throughput of data acquisition, in part due to the nature of next generation applications such as deep sequencing and others. Furthermore, modern research labs encompass a greater scope of analytical techniques and specialty fields than ever before, adding yet another factor to the lab space equation.Efficiency has emerged as a top priority for labs in considering, not just the space issue, but for equipment performance, ease of use and maintenance, and compatibility with data processing streams as well. When it comes to high complexity analytical instruments, there is always a balance between performance and efficiency. This is particularly applicable to the electron microscope, a technology that has traditionally been associated with large, complex, custom suited facilities – a concept that runs in direct contrast to this new age of downsized efficiency
The scanning electron microscope or SEM microscope has evolved to meet many of the requirements discussed above. The instrument and accessories have been effectively miniaturized to benchtop scale without sacrificing the features that make the technology powerful for so many research applications.
SEM was commercialized in the 1960's, and since then has assisted researchers in exploring novel frontiers in biology and material science, uncovering a miniature world previously unknown to optical microscopy. There was traditionally a divide between the two techniques, optical versus electron microscopy. Tissue or live cells were imaged by light microscopy, and then prepared through rigorous sample treatment methods prior to more laborious SEM imaging.
Introduction of the NeoScope technology from JEOL instruments supported a new concept that complemented both optical microscopes and traditional SEMs in the lab. The technology brought SEM to the benchtop while enabling seamless integration of optical microscope features into a higher resolution platform with up to 60,000X magnification. The same samples that are examined via light microscopy can be interrogated with much higher depth of field and resolution, importantly without additional extensive sample preparation. Many optical microscope features such as simplicity of use and size footprint are maintained while offering advanced settings for pre-screening of biological and composite samples and others – applications which were traditionally the domain of larger SEM instruments.
The new JEOL JCM-6000 NeoScope Versatile Benchtop SEM features a modern design with state-of-the-art features. Operation is via a touchscreen and is simplified with auto focus, auto alignment, auto contrast, and auto brightness controls. The instrument functions under both low and high vacuum modes with three settings for voltage acceleration. These features enable a variety of applications which can be programmed via pre-stored recipe files.
This new NeoScope offers both an Everhart Thornley type SE detector as well a high sensitivity solid state back scattering electron (BSE) detector. A full-featured Energy-dispersive X-ray Spectroscopy (EDS) with SDD technology is available for advanced analytical applications.
Whether used by trained electron microscopists as a simple screening instrument, or by lab technicians as a higher resolution alternative to the light microscope, the NeoScope accelerates the overall pace of research as is a model of imaging efficiency.
View JEOL NeoScope listings on LabX.com
The resolution of the electron microscope, scanning electron magnification, sem microscope uses, and specimen preparation for scanning electron microscopy are topics for other articles. Take a closer look at the LabX microscopy resources for more insight:
No comments:
Post a Comment