• Title/Summary/Keyword: field-emission scanning electron microscopy

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Relationship of the Distribution Thickness of Dielectric Layer on the Nano-Tip Apex and Distribution of Emitted Electrons

  • Al-Qudah, Ala'a M.;Mousa, Marwan S.
    • Applied Microscopy
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    • v.46 no.3
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    • pp.155-159
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    • 2016
  • This paper analyses the relationship between the distribution of a dielectric layer on the apex of a metal field electron emitter and the distribution of electron emission. Emitters were prepared by coating a tungsten emitter with a layer of epoxylite resin. A high-resolution scanning electron microscope was used to monitor the emitter profile and measure the coating thickness. Field electron microscope studies of the emission current distribution from these composite emitters (Tungsten-Clark Electromedical Instruments Epoxylite resin [Tungsten/CEI-resin emitter]) have been carried out. Two forms of image have been observed: bright single-spot images, thought to be associated with a smooth substrate and a uniform dielectric layer; and multi-spot images, though to be associated with irregularity in the substrate or the dielectric layer.

Deposition of Carbon Thin Film using Laser Ablation and Its Field Emission Properties (레이저 증착법에 의한 탄소계 박막의 구조 및 전계방출특성)

  • ;Kenjiro Oura
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.15 no.7
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    • pp.634-639
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    • 2002
  • Using laser ablation technique carbon thin films were deposited on Si(100) substrate as a function of substrate temperature. In this study, the surface morphologic, structural and field emission properties of these carbon thin films were investigated using Raman spectroscopy, scanning electron microscopy, and a diode technique, respectively. With increasing of the substrate temperature, the surface morphologies were changed significantly. Moreover, the intensity of D-band and the full width at half maximum of these bands were dependent on substrate temperatures. As the substrate temperature was increased, the field emission properties were improved. As the result, we find that the field emission properties of the films were changed significantly with the substrate temperature and structural features of carbon than films.

Specimen Preparation for Scanning Electron Microscope Using a Converted Sample Stage

  • Kim, Hyelan;Kim, Hyo-Sik;Yu, Seungmin;Bae, Tae-Sung
    • Applied Microscopy
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    • v.45 no.4
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    • pp.214-217
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    • 2015
  • This study introduces metal coating as an effective sample preparation method to remove charge-up caused by the shadow effect during field emission scanning electron microscope (FE-SEM) analysis of dynamic structured samples. During a FE-SEM analysis, charge-up occurs when the primary electrons (input electrons) that scan the specimens are not equal to the output electrons (secondary electrons, backscattered electrons, auger electrons, etc.) generated from the specimens. To remove charge-up, a metal layer of Pt, Au or Pd is applied on the surface of the sample. However, in some cases, charge-up still occurs due to the shadow effect. This study developed a coating method that effectively removes charge-up. By creating a converted sample stage capable of simultaneous tilt and rotation, the shadow effect was successfully removed, and image data without charge-up were obtained.

Improvement of field emission character by surface treatment of carbon thin film (탄소계 박막의 표면 처리에 의한 전계전자방출 특성의 개선)

  • ;K.-Y. Lee;S.-I. Honda;M. Katayama;;K. Oura
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2002.07a
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    • pp.147-150
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    • 2002
  • The electron field emission properties of amorphous carbon (a-C) films deposited using a RF magnetron sputtering system have been improved by introducing a simple method of argon plasma treatment at room temperature. Surface morphologies and structural properties of the a-C films were investigated by scanning electron microscopy and Raman spectroscope, respectively. Structural properties and surface morphologies of the a-C films were changed by argon plasma treatment. The emission properties improved with the plasma treatment.

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Ambient Variable Pressure Field Emission Scanning Electron Microscopy for Trichome Profiling of Plectranthus tomentosa by Secondary Electron Imaging

  • Kim, Ki Woo
    • Applied Microscopy
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    • v.43 no.1
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    • pp.34-39
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    • 2013
  • Glandular and nonglandular trichomes on the leaf surface of Plectranthus tomentosa were investigated by variable pressure field emission scanning electron microscopy (VP-FESEM). The segments of the plant's leaves were directly mounted without any specimen preparation, and examined at ambient temperature using a variable pressure secondary electron (SE) detector under ca. 15 Pa. Foliar trichomes maintained their shapes and structures without severe surface collapse or charging. The adaxial leaf surface was abundantly covered with different types of trichome. Nonglandular trichomes consisted of a basal cell and a long (up to ca. $300{\mu}m$) stalk. Meanwhile, capitate glandular trichomes had a secretory head and a short or long stalk. Peltate glandular trichomes with globose secretory heads were observed in close contact with the leaf epidermis. Spherical projections on the secretory head showed the secretion process of glandular trichomes. In addition to the trichomes, oval stomata were distributed on the abaxial leaf surface. These results suggest that ambient VP-FESEM can be used to classify the dehydration-sensitive foliar trichomes of succulent plants by SE imaging. At the FESEM resolution, this approach facilitates the rapid and detailed morphological analysis of a variety of trichomes in diverse plant taxa with reduced labor and preparation.

Biological applications of the NanoSuit for electron imaging and X-microanalysis of insulating specimens

  • Ki Woo Kim
    • Applied Microscopy
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    • v.52
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    • pp.4.1-4.11
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    • 2022
  • Field emission scanning electron microscopy (FESEM) is an essential tool for observing surface details of specimens in a high vacuum. A series of specimen procedures precludes the observations of living organisms, resulting in artifacts. To overcome these problems, Takahiko Hariyama and his colleagues proposed the concept of the "nanosuit" later referred to as "NanoSuit", describing a thin polymer layer placed on organisms to protect them in a high vacuum in 2013. The NanoSuit is formed rapidly by (i) electron beam irradiation, (ii) plasma irradiation, (iii) Tween 20 solution immersion, and (iv) surface shield enhancer (SSE) solution immersion. Without chemical fixation and metal coating, the NanoSuit-formed specimens allowed structural preservation and accurate element detection of insulating, wet specimens at high spatial resolution. NanoSuit-formed larvae were able to resume normal growth following FESEM observation. The method has been employed to observe unfixed and uncoated bacteria, multicellular organisms, and paraffin sections. These results suggest that the NanoSuit can be applied to prolong life in vacuo and overcome the limit of dead imaging of electron microscopy.

SPEM & PEEM (Scanning Photoelectron Microscopy & PhotoEmission Electron Microscopy)

  • Sin, Hyeon-Jun
    • Proceedings of the Korean Vacuum Society Conference
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    • 2012.02a
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    • pp.83-83
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    • 2012
  • 본 강연에서는 방사광 연X-선 분광현미경학(spectro-microscopy) 중에서, 표면에서 방출되는 광전자를 이용하는 SPEM (Scanning Photoelectron Microscopy)과 PEEM (Photoemission Electron Microscopy)을 소개하고자 한다. SPEM은 입사하는 X-선을 작은 크기로 집속하여 특정의 작은 공간에서 광전자분광학(XPS) 데이터를 얻거나 특정 광전자에너지의 공간분포를 얻게 해주며, PEEM은 입사한 X-선에 의해 발생한 광전자를 전자렌즈 원리로 영상을 맺히게 하여 광전자의 발생 분포를 구하게 한다. 이들은 균일하지 아니한 이종의 표면 연구에 매우 유용한 측정기법들이지만, 그 원리 및 구성은 많은 차이점들을 가지고 있다. 예를 들어, SPEM은 시료를 scanning하면서 XPS에 보다 충실한 타입이고 PEEM은 full field imaging 타입으로 표면변화의 동역학 연구에 강점이 있다. 본 강의에서는 이들 각각의 원리, 장점들에 대해서 설명하고, 활용 예를 제시하고자 한다. 활용 분야에 있어서, SPEM의 경우는 포항가속기연구소의 SPEM으로 수행되었던 DMS, graphene, nano-lithography, OLED, 등 반도체 및 나노 소재, 소자에의 활용에 대한 예를 제시할 것이다. PEEM의 경우는 포항가속기연구소의 응용 예와 박막 형태의 magnetic material에 대한 예들을 제시할 것이다.

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RF power dependence on field emission property from carbon thin film grown by PECVD (PECVD에 의해 작성된 탄소계 박막의 전계전자방출특성에 대한 RF power 의존성에 관한 연구)

  • ;;K. Oura
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2000.11a
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    • pp.519-523
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    • 2000
  • Using plasma-enhanced chemical vapor deposition (PECVD), carbon thin film as electron field emitter were fabricated. These carbon thin film were deposited on Si(100) substrate at several RF power. These film were estimated by raman spectroscopy, scanning electron microscopy, and field emission. The field electron emission property of these carbon thin film was estimated by a diode technique. As the result, we observed that the field emission properties of these films were promoted by higher RF power. These results are explained as change of surface morphology and structural properties of carbon thin film

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Enhanced Field Electron Emission from Dielectric Coated Highly Emissive Carbon Fibers

  • Almarsi, Ayman M.;Hagmann, Mark J.;Mousa, Marwan S.
    • Applied Microscopy
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    • v.47 no.1
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    • pp.55-62
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    • 2017
  • This paper describes experiments aimed at characterizing the behavior of field electron emitters fabricated by coating carbon fibers with epoxylite resin. Polyacrylonitrile carbon fibers of type VPR-19, thermally treated at $2,800^{\circ}C$, were used. Each was initially prepared in a "uncoated" state, by standard electro polishing and cleaning techniques, and was then examined in a scanning electron microscope. The fiber was then baked overnight in a field electron microscope (FEM) vacuum chamber. Current-voltage characteristics and FEM images were recorded on the following day or later. The fiber was then removed from the FEM, coated with resin, "cured" by baking, and replaced in the FEM. After another overnight bake, the FEM characterization measurements were repeated. The coated fibers had significantly better performance than uncoated fibers. This confirms the results of earlier experiments, and is thought to be due in part to the formation of a conducting channel in the resin over layer. For the coated fiber, lower voltages were needed to obtain the same emission current. The coated fibers have current-voltage characteristics that show smoother trends, with greater stability and repeatability. No switch-on phenomena were observed. In addition, the emission images on the phosphor-coated FEM screen were more concentrated, and hence brighter.