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한국산학기술학회논문지 = Journal of the Korea Academia-Industrial cooperation Society, v.18 no.6, 2017년, pp.37 - 43
김동신 (전자부품연구원 융복합전자소재연구센터) , 구용성 (전자부품연구원 융복합전자소재연구센터) , 김주희 (전자부품연구원 융복합전자소재연구센터) , 강소연 (전자부품연구원 융복합전자소재연구센터) , 오원욱 (전자부품연구원 융복합전자소재연구센터) , 천성일 (전자부품연구원 융복합전자소재연구센터)
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This review investigates the basic principle of physical interactions and failure mechanisms introduced in the materials and inner parts of semiconducting components under electromagnetic pulses (EMPs). The transfer process of EMPs at the semiconducting component level can be explained based on thre...
| 핵심어 | 질문 | 논문에서 추출한 답변 |
|---|---|---|
| 고출력전자기파는 어떻게 분류되는가? | 고출력전자기파(Electromagnetic Pulse, EMP)는 핵폭발로 인해 발생되는 핵 전자기파(Nuclear EMP, NEMP)와 전자폭탄이나 고출력 전자파 발생기에 의해 직접적으로 전자파를 발생시키는 비핵 전자기파(Non-nuclear EMP, NNEMP)로 분류 된다. NEMP 중에서는 핵폭발에 의한 고고도 핵 전자기파(High Altitude EMP, HEMP)가 대표적이다. | |
| 고출력전자기파가 반도체 부품에 커플링 되는 과정에 대하여 발생되는 고장 매커니즘은 어떤 것이 있는가? | (1) 반도체 부품에 전자기파가 커플링 되는 과정은 3층(공기/유전체/도체) 구조로 설명할 수 있으며, 이론적으로 흡수되는 에너지는 복소반사계수에의하여 예상할 수 있다. (2) 반도체 부품에 전달된 전자기파는 반도체 내부 물질과 상호작용을 하며, 전기장에 의해 쌍극자분극과 이온 전도 현상이 동시에 발생하며, 칩 P-N 접합 부분에 과도한 역 전압이 형성되어 P-N 접합 파괴를 유발한다. | |
| NNEMP는 파형에 따라 어떻게 구분할 수 있는가? | NEMP 중에서는 핵폭발에 의한 고고도 핵 전자기파(High Altitude EMP, HEMP)가 대표적이다. 반면, NNEMP는 파형에 따라 초광대역(Ultra Wide Band, UWB), 광대역(Damped Sinusoidal,DS), 협대역(High Power Microwave, HPM) 전자기파로 구분할 수 있으며[1], 전자기파의 주파수 성분 및 세기를 비교하면 Fig. 1과 같이 나타낼 수 있다[2]. |
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