Ÿþm I C R O S O F T W O R

Total Page:16

File Type:pdf, Size:1020Kb

Ÿþm I C R O S O F T W O R 1 기조강연 through the reaction with water 도진영 김대식, 경주대 문화재보존학과 (Plenary Lecture) 좌장 강용수 16:40 나노소재를 함유한 에폭시 접착제 연구 PRES1-8 원종옥, 세종대 화학과 목(14일)M회장 좌장 이남수 11:00 Compensated Heat, Uncompensated Heat, PLEN-1 Generalized Thermodynamics, and Generalized 4 녹색 화학과 녹색 성장 Hydrodynamics (Green Chemistry and Green Growth) Byung Chan Eu, McGill University, Canada 좌장 김기문 <대한화학회 심포지엄 II > 11:45 Carbon nanotubes in materials science and PLEN-2 nanomedicine 금(15일)J회장 Maurizio Prato, University of Trieste, Italy 좌장 이규호 14:00 녹색 화학과 녹색 성장 - 소개, 녹색 성장과 화학자 PRES2-1 의 역할 도춘호, 순천대 나노신소재응용공학부 2 기념강연 좌장 이규호 PRES2-2 (Award Lecture) 14:10 Present and Future of Advance Secondary Batteries in Korea <이태규학술상 수상 기념강연> 박정기, KAIST 화학공학과 좌장 이규호 목(14일)A회장 14:35 화학산업과 녹색화학기술 PRES2-3 좌장 김진흥 이규호, 한국화학연구원 그린화학연구단 AWARD-1 13:30 Molecular Engineering of Highly Efficient Dye- 좌장 이규호 Sensitized Solar Cells 15:00 정삼투 공정 연구 개발 현황 PRES2-4 고재중 최현봉 김철우 백상현 조나라 임기민 도광석 홍승관, 고려대 건축사회환경공학부 최혜주 소슬기 김경준 최홍식 정반석 유태정 송주만, 고려대 소재화학과 15:25 Coffee Break <한국과학상 수상 기념강연> 좌장 이규양 15:45 바이오매스 기반 바이오리파이너리 기술과 화학산업 PRES2-5 목(14일)M회장 장종산 황동원 황인택 황진수, 한국화학연구원 바이 좌장 이남수 오리파이너리 연구센터 AWARD-2 17:00 Organization of Nano and Micro Building Blocks into 좌장 이규양 Functional Materials 16:10 Green chemical reactions; use of natural PRES2-6 윤경병, 서강대 화학과 biocatalysts for biotechnological applications 장윤석, 포항공과대 환경공학부 좌장 이규양 3 문화재 보존과 화학 16:35 저탄소 녹색성장 추진정책 방향 PRES2-7 우기종, 대통령 직속 녹색성장위원회 기획단장 (Conservation of Cultural Heritage and Chemistry) <대한화학회 심포지엄 I > 목(14일)J회장 5 화학과 뉴스미디어의 역할 좌장 원종옥 (Role of News Media and Chemistry) 14:00 문화재보존과 화학 - 소개 PRES1-1 도춘호, 순천대 나노신소재응용공학부 <대한화학회 심포지엄 III > 좌장 원종옥 금(15일)J회장 Cultural heritage know means to protect14:10 PRES1-2 좌장 윤웅찬 Luigi Campanella, Italian Chemical Society 09:00 화학과 뉴스미디어의 역할 - 소개, 일반인의 화학에 PRES3-1 좌장 원종옥 대한 이해와 화학자의 역할 14:40 A Novel Method to Measure the Penetration Depth PRES1-3 도춘호, 순천대 나노신소재응용공학부 of Silicate Consolidants for Stone Conservation 좌장 윤웅찬 강용수, 한양대 화학공학과 09:10 과학 잡지에서 화학 기사의 내용과 범위 PRES3-2 좌장 원종옥 이충환, 동아사이언스 PRES1-4 15:00 칠백의총 중봉조헌선생일군순의비의 과학적 보존처리 좌장 윤웅찬 와 복원 09:40 을 중심으로 한 과학 윤리, 도덕, 그리고 과학사 이 PRES3-3 김사덕, 국립문화재연구소 문화재보존과학센터 야기 김형근, 사이언스 타임스 15:20 Coffee Break 좌장 강용수 10:10 Coffee Break PRES1-5 15:40 미술과 화학의 융합 좌장 윤웅찬 전창림, 홍익대 화학시스템공학과 10:30 대한화학회의 새로운 임무 PRES3-4 좌장 강용수 손동운, 국제신문 과학문화연구소 PRES1-6 16:00 석조문화재 손상도 평가를 위한 비파괴 초정밀 안전 좌장 윤웅찬 진단 및 모니터링 기술 11:00 화학, 언론과 친해지기 PRES3-5 이찬희 *서만철 조영훈, 공주대 문화재보존과학과 *공 김요셉, 대덕넷 주대 지질환경과학과 좌장 윤웅찬 좌장 강용수 11:30 화학 산업과 방송뉴스의 친해지기 PRES3-6 16:20 물반응 실험을 통한 석조문화재 보수 무기질바인더의 PRES1-7 선우석, ubc 울산방송 안정성 연구 Study on the stability of inorganic binder as repair material of stone monuments 정준호, 한국기계연구원 나노융합기계연구본부 좌장 이승준 17:10 나노임프린팅 기술을 응용한 NWGP(nano-wire grid POLY2-7 6 고분자 화학 첨단연구 polarizer)Film 제조기술 (Frontier Research on Polymer Chemistry) 허종욱, 미래나노텍㈜ <고분자화학분과 학술진보상 수상기념강연> 목(14일)B회장 8 녹색공업화학: 이산화탄소 자원화 기술 I 좌장 조창기 14:00 Reverse Thermogelling Biodegradable Polymers and POLY1-1 (Industrial Utilization of Carbon Dioxide I) Their Biomedical Applications to Drug Delivery and <공업화학분과 심포지엄 I > Tissue Engineering 정병문, 이화여자대 화학나노과학과 금(15일)G회장 좌장 정민석 Converting CO to a Valuable Polymer09:00 IND1-1 <고분자화학분과 심포지엄 I > 2 이분열 Anish Cyriac, 아주대 분자과학기술학과 목(14일)B회장 좌장 정민석 좌장 백종범 09:30 미세조류를 이용한 생물학적 이산화탄소의 고정화 IND1-2 14:30 산소부화막, OLED, OTFT, Solar cell용 기능성 고분자 POLY1-2 심상준, 성균관대 화학공학과 의 합성 좌장 정민석 권순기, 경상대 나노신소재공학부 10:00 Biological Sequestration of Carbon Dioxide by IND1-3 좌장 백종범 Photosynthetic Microalgae 15:00 Protein detection using aqueous/LC interfaces POLY1-3 이철균, 인하대 decorated with SGLCP-b-polyacrylic acid block copolymers 좌장 이분열 IND1-4 박수영, 경북대 고분자공학과 10:30 미세조류의 CO2 고정화 및 biodiesel 생산 기술현황 좌장 백종범 및 전망 15:30 분자조립 연성나노소재 POLY1-4 오희목, 한국생명공학연구원 환경바이오연구센터 김상욱, KAIST 신소재공학과 좌장 이분열 11:00 이산화탄소를 활용한 유기카보네이트의 합성 및 활용 IND1-5 16:00 Coffee Break 이현주, KIST 청정에너지연구센터 좌장 김상욱 16:10 “Direct” Grafting of Linear Macromolecular POLY1-5 ‘Wedges’ to the Edge of Pristine Graphite: A Precursor toward Exfoliation of Graphite into Two- 9 녹색공업화학: 이산화탄소 자원화 기술 II Dimensional Graphene (Industrial Utilization of Carbon Dioxide II ) 백종범, 울산과학기술대 에너지공학부 좌장 김상욱 <공업화학분과 심포지엄 II > 16:40 Self-assembled processing of siloxane block POLY1-6 copolymers for nanolithography 금(15일)G회장 정연식, Kaist 신소재공학과 좌장 정광덕 13:00 이산화 탄소 활용을 통한 폴리카보네이트 제조 기술 IND2-1 권오성 *장복남 **지준호 ***허종찬, 제일모직(주) 케미 칼연구소 *제일모직 케미칼 연구소 **제일모직 케미칼 7 나노임프린팅 기술과 기능성 소재 연구소 ***제일모직(주) 케미칼연구소 PC그룹 (Advanced Materials for Nano Imprinting Technology) 좌장 정광덕 13:30 제철산업에서의 이산화탄소 포집 및 자원화 기술개발 IND2-2 <고분자화학분과 심포지엄 II > 전희동,(재)포항산업과학연구원 CO2 연구단 좌장 정광덕 금(15일)B회장 14:00 SK energy ’ s New CO2-Embeded Polymer IND2-3 좌장 도이미 Technology: GreenPolTM POLY2-1 14:00 TFT-LCD 적용 임프린팅 기능성 소재 옥명안, SK에너지 기술원 화학연구소 김진욱 채기성 황용기 정인재, 엘지디스플레이 재료1 팀 좌장 옥명안 좌장 도이미 14:30 일 10톤 DME 생산플랜트 기술개발 IND2-4 POLY2-2 14:30 Fabrication of an All-Layer-Printed TFT-LCD Device 조원준, 한국가스공사 연구개발원 DME연구개발 via Large-Area UV Imprinting Lithography 좌장 옥명안 이승준, SAMSUNG ELECTRONICS LCD R&D Center 15:00 이산화탄소저감 메탄올 제조촉매 및 공정기술 IND2-5 좌장 도이미 CAMERE-II POLY2-3 15:00 나노임프린트 리소그래피 시스템 기술 정광덕, KIST, 청정에너지센터 이재종, 한국기계연구원 좌장 옥명안 좌장 도이미 15:30 호남석유화학의 이산화탄소 활용 및 연구 방향 IND2-6 POLY2-4 Silicate Replica Molds for Nanoimprint Lithography15:30 김창규, 호남석유화학(주) 소장실 김동표, 충남대 공업화학과 16:00 Coffee Break 좌장 이승준 10 에너지변환 광동력학 16:10 발광다이오드 소자의 광추출 효율 향상을 위한 기능 POLY2-5 (Photodynamics for Energy Conversion) 성 물질의 직접 나노 패터닝 기술 연구 이 헌, 고려대 신소재공학과 <무기화학분과 젊은 무기화학자상 수상기념강연> 좌장 이승준 16:40 Photo-induced hybrid nanopatterning of titanium POLY2-6 금(15일)A회장 dioxide via direct imprint lithography 좌장 김진흥 Self-crystallization of fullerene09:00 INOR1-1 최희철, 포항공과대 화학과 <무기화학분과 심포지엄 I > 12 바이오메디컬 이미징 기술 금(15일)A회장 (Bio-medical Imaging Techniques) 좌장 박강현 09:30 Photoinduced Electron Transfer in Heteroleptic Ir(III) INOR1-2 <물리화학분과 특별초청강연> Complexes with Light-Harvesting Carbazole 목(14일)H회장 dendrimers 좌장 이진용 조대원, 고려대 신소재화학과 13:30 Volume, Statistical Mechanics, and Molecular PHYS1-1 좌장 박강현 Representation of Molar Volume Energy transfer dynamics in OLED devices10:00 INOR1-3 Byung Chan Eu, McGill University, Canada 송재규, 경희대 화학과 좌장 박강현 <물리화학분과 심포지엄 I > INOR1-4 10:30 Unique Photo-electronic Properties of Mesoporous 목(14일)H회장 TiO2 Single Nanofiber Including Au Quantum Dot 좌장 이태걸 김용록 임지은 왕강균 오승임 김봉진 신언필 민경명, Polymer nanotechnology for optical imaging14:00 PHYS1-2 연세대 화학과 권익찬, KIST 의과학센터 좌장 이태걸 좌장 옥강민 14:30 Fluorescence-SERS Dual Modal Nanoprobes: PHYS1-3 11:00 Molecular Structure and Chemical Reaction: INOR1-5 Application to Molecular Imaging of Cancer Cells Physical Chemist's view Expressing Multiplex Biomarkers 김상규, KAIST 화학과 주재범, 한양대 생명나노공학과 좌장 옥강민 좌장 이태걸 11:30 Photodynamic Studies of TiO -Nanostructure INOR1-6 2 15:00 Multiplex coherent anti-Stokes Raman scattering PHYS1-4 Composites toward Solar Energy Conversion microscopy for fast imaging and spectroscopic Systems analysis of lipid-rich structures 윤민중, 충남대 화학과 이재용, 한국표준과학연구원 미래융합기술부 <외국인과학자 초청강연> 좌장 옥강민 15:30 Coffee Break INOR1-7 12:00 Interfacial Electron Transfer in Quantum Dot 좌장 주재범 Modified with Pyromellitimide 15:40 Design and Synthesis of Nanostructured Materials PHYS1-5 Tetsuro Majima, Institute of Scientific and Industrial for Biomedical Imaging and Therapy Research, Osaka University 정봉현, 한국생명공학연구원 좌장 주재범 16:10 Nanomedical Technology in Personalized Cancer PHYS1-6 11 무기 나노 재료의 발전 방향 Medicine 허용민, 연세대 의료원 (Current Advances in Nanosciences of Inorganic Materials) 좌장 주재범 16:40 An Ionic liquid matrix for MALDI Imaging Mass PHYS1-7 <무기화학분과 심포지엄 II> Spectrometry of Phospholipids 목(14일) A회장 김광표, 건국대 분자생명공학과 <외국인과학자 초청강연> 좌장 허남회 14:00 Metal Nanocrystal Synthesis: Past, Present, and INOR2-1 Future Younan Xia, Washington University 13 생물리화학의 최신 동향 좌장 허남회 (Recent Progress in Biophysical Chemistry) 14:30 Chemical Design of Nanoparticles for Bio-Medical INOR2-2 Applications <물리화학분과 젊은 물리화학자상 수상기념강연> 천진우, 연세대 화학과 금(15일)H회장 좌장 이진용 <외국인과학자 초청강연> 좌장 허남회 09:00 Contact Mechanics of Atomic Force Microscope PHYS2-1 15:00 Nanocrystal Solids: A Modular Approach to Materials INOR2-3 Tip: Molecular Simulation and Theory Design 장준경, 부산대 나노소재공학과 Dmitri Talapin, University of Chicago <물리화학분과 심포지엄 II > 좌장 천진우 15:30 Designed Assembly of Uniform-sized Magnetite INOR2-4 금(15일)H회장 Nanocrystals for Multifunctional Biomedical 좌장 황현석 PHYS2-2 Applications 09:30 Structural and dynamical characteristics of β- 현택환 이지은 이노현 김병효 박미현, amyloid fibrils revealed by two-dimensional infrared 서울대 화학생물공학부 spectroscopy 김영삼, 울산과학기술대 나노생명화학공학부 <외국인과학자 초청강연> 좌장 천진우 좌장 황현석 PHYS2-3 16:00 D-Penicillaminato Metalloligand Systems That Lead INOR2-5 09:55 Biological Imaging by Broadband Coherent Anti- to a Variety of Chiral Heterometallic Aggregates Stokes Raman Scattering Microsopy 성지하 *Bi-Chang Chen *Sang-Hyun Lim, 동덕여자 Takumi Konno, Osaka University, Japan * 좌장 천진우 대 응용화학과 University of Texas at Austin, United States 16:30 Porous Coordination Polymers for Hydrogen Storage INOR2-6 좌장 황현석 and Carbon Dioxide Capture PHYS2-4 백명현, 서울대 화학부 10:20 Single-Molecule and Single Cell Approach to Biological Systems * ** *** 17:00 무기화학분과회 총회 이남기 김재열 최봉규 신연균, 포항공과대 시스 템생명공학부/물리학 *포항공과대 물리학과 **포항공 과대 I-BIO/시스템생명공학부 ***Iowa State University 15 최근의 분석화학 분야 연구현황 10:45 Coffee Break (Current research trends in Analytical Chemistry) 좌장 정연준 11:05 Controlling Neuronal Function via Silicon-Based PHYS2-5 <분석화학분과 심포지엄 II > Nanostructures 금(15일)C회장 윤명한, 광주과학기술원 신소재공학부 좌장 송규석 좌장 정연준 09:20 High-sensitive absorption spectroscopy using a ANAL2-1 11:30 Dynamic heterogeneity and cooperativity in protein PHYS2-6 capillary cell for the chemical speciation of actinides folding 조혜륜 박경균 정의창 송규석, 한국원자력연구원 원 정성호 *유우경 *장익수, 서울대 화학부 *부산대 물리 자력화학연구부 학과 좌장 송규석 좌장 정연준 09:45 Structural Characterization of Small Biomolecules ANAL2-2 11:55 DNA stretch approaching to full contour length in PHYS2-7 Using Ion Mobility Spectrometric Techniques nanochannels 김준곤, 포항공과대 화학과 조규봉, 서강대 화학과 좌장 송규석 10:10 Identification of benzalkonium chloride from ANAL2-3 stainless steel MALDI plates 14 Micro분석에의 접근 김정권, 충남대 화학과 (Approaches to Microanalysis) 10:35 Coffee Break 좌장 김정권 <분석화학분과 심포지엄 I > 10:45 Development of LC/MS-based reference methods ANAL2-4 목(14일)C회장 for food analysis 좌장 정봉철 김병주 안성희 이준희, 한국표준과학연구원 삶의질측 13:30 Azithromycin as a novel antibiotic chiral selector in ANAL1-1 정표준본부 chiral separation by capillary electrophoresis 좌장 김정권 박정학 *A.
Recommended publications
  • PRAJNA - Journal of Pure and Applied Sciences ISSN 0975 2595 Volume 19 December 2011 CONTENTS
    PRAJNA - Journal of Pure and Applied Sciences ISSN 0975 2595 Volume 19 December 2011 CONTENTS BIOSCIENCES Altered energy transfer in Phycobilisomes of the Cyanobacterium, Spirulina Platensis under 1 - 3 the influence of Chromium (III) Ayya Raju, M. and Murthy, S. D. S. PRAJNA Volume 19, 2011 Biotransformation of 11β , 17 α -dihydroxy-4-pregnene-3, 20-dione-21-o-succinate to a 4 - 7 17-ketosteroid by Pseudomonas Putida MTCC 1259 in absence of 9α -hydroxylase inhibitors Rahul Patel and Kirti Pawar Influence of nicking in combination with various plant growth substances on seed 8 - 10 germination and seedling growth of Noni (Morinda Citrifolia L.) Karnam Jaya Chandra and Dasari Daniel Gnana Sagar Quantitative analysis of aquatic Macrophytes in certain wetlands of Kachchh District, 11 - 13 Journal of Pure and Applied Sciences Gujarat J.P. Shah, Y.B. Dabgar and B.K. Jain Screening of crude root extracts of some Indian plants for their antibacterial activity 14 - 18 Purvesh B. Bharvad, Ashish R. Nayak, Naynika K. Patel and J. S. S. Mohan ________ Short Communication Heterosis for biometric characters and seed yield in parents and hybrids of rice 19 - 20 (Oryza Sativa L.) M. Prakash and B. Sunil Kumar CHEMISTRY Adsorption behavior and thermodynamics investigation of Aniline-n- 21 - 24 (p-Methoxybenzylidene) as corrosion inhibitor for Al-Mg alloy in hydrochloric acid V.A. Panchal, A.S. Patel and N.K. Shah Grafting of Butyl Acrylate onto Sodium Salt of partially Carboxymethylated Guar Gum 25 - 31 using Ceric Ions J.H. Trivedi, T.A. Bhatt and H.C. Trivedi Simultaneous equation and absorbance ratio methods for estimation of Fluoxetine 32 - 36 Hydrochloride and Olanzapine in tablet dosage form Vijaykumar K.
    [Show full text]
  • INVESTIGATIONS on STRUCTURE and PROPERTIES of Ge-As-Se CHALCOGENIDE GLASSES Ting Wang April 2017 a Thesis Submitted for the Degr
    INVESTIGATIONS ON STRUCTURE AND PROPERTIES OF Ge-As-Se CHALCOGENIDE GLASSES Ting Wang April 2017 A thesis submitted for The degree of Doctor of Philosophy of The Australian National University The Laser Physics Centre Research School of Physics & Engineering The Australian National University STATEMENT I declare that the work presented in this thesis is, to the best of my knowledge, the result of original research. The thesis has not been submitted for a degree or diploma to any other university or institution. Part of the research included in this thesis has been performed jointly with Professor Pierre Lucas. Signed Ting Wang ACKNOWLEDGEMENTS I would like to sincerely thank my supervisor and advisors, Professor Barry Luther-Davis, Dr. Rongping Wang and Dr. Xin Gai for their guidance, advice and thoughtful comments throughout this work. I would like to express my thanks to Dr. Zhiyong Yang, Dr. Duk-Yong Choi, Dr. Steve Madden, Dr. Vu Khu for sharing their knowledge and expertise in glass science. I would also like to thank Professor Ian Jackson, Mr Sukanta Debbarma and Mrs Maryla Krolikowska for their help in experiments. Particularly thanks to Professor Pierre Lucas and Mr Ozgur Gulbiten for providing useful samples, valuable suggestions and great assistance on the interpretation of the thermal data. Thanks to all students who work in the laser physics center: Yi Yu, Pan Ma, Kunlun Yan, Joseph Sudhakar Paulraj and Yue Sun. Thanks to my parents, for their encouragement and great support during my PhD. I TABLE OF CONTENTS TABLE OF CONTENTS ................................................................................................. i LIST OF FIGURES........................................................................................................iii LIST OF TABLES ........................................................................................................viii LIST OF ABBREVIATIONS .......................................................................................
    [Show full text]
  • LAP Scope of Accreditation
    TESTING AND CALIBRATION LABORATORY ACCREDITATION PROGRAM (LAP) Scope of Accreditation Accredited Laboratory No. 474 Legal Name of Accredited Laboratory: National Research Council Canada, Metrology Research Centre GDMS TEST UNIT, CHEMICAL METROLOGY Location Name or Operating as (if applicable): Ottawa, ON Contact Name: Bradley Methven Address: 1200 Montreal Road Ottawa, ON K1A 0R6 Telephone: +1 613 998 4237 FAX: +1 613 993 2451 Website: https://nrc.canada.ca/en/research- development/products-services/technical- advisory-services/glow-discharge-mass- spectrometry-gdms-analysis Email: [email protected] SCC File Number: 15592 Accreditation Standard(s): ISO/IEC 17025:2017 Fields of Testing: Chemical/Physical Initial Accreditation: 2002-10-24 Most Recent Accreditation: 2020-02-26 Accreditation Valid to: 2022-10-24 CHEMICALS AND CHEMICAL PRODUCTS 1 | ASB_JA_LAP-Scope-Template-Testing_v1_2019-09-29 Chemical Compounds: (not elsewhere specified) Inorganic Glow discharge mass spectrometric analysis of high purity metals and semiconductor materials Silver, Aluminum, Arsenic, Gold, Bismuth Oxide, Bismuth Telluride, Bismuth, Beryllium, Carbon, Cadmium, Cadmium Selenide, Cadmium Telluride, Cadmium Tellurium Selenide, Cadmium Zinc Telluride, Cobalt, Chromium, Copper, Iron, Gallium, Gallium Arsenide, Gallium Oxide, Gallium Phosphide, Gallium Antimonide, Germanium, Germanium Oxide, Germanium Selenide, Mercury Telluride, Indium, Indium Arsenide, Indium Phosphide, Indium Antimonide, Magnesium, Manganese, Molybdenum, Nickel, Lead, Lead/Tin, PMN-PT, Rhenium, Antimony, Selenium, Silicon, Silica, Tin, Tantalum, Tellurium Oxide, Tellurium, Titanium, Thallium, Tungsten, Vanadium, Zinc, Zinc Oxide, Zinc Selenide, Zinc Telluride, Zirconium Purity analysis of metals (Al, Ag, As, Au, Be, Cd, Co, Cr, Cu, Fe, Mg, Mn, Mo, Ni, Pb, Sb, Se, Sn, Te, Ti, V, Zn) having amount content in the range 0.999 kg/kg to 0.9999999 kg/kg with associated expanded uncertainties (k=2) of 0.005 kg/kg to 0.0000005 kg/kg.
    [Show full text]
  • Applications of Chalcogenide Glasses: an Overview
    International Journal of ChemTech Research CODEN (USA): IJCRGG ISSN : 0974-4290 Vol.6, No.11, pp 4682-4686, Oct-Nov 2014 Applications of Chalcogenide Glasses: An Overview Suresh Sagadevan*1 and Edison Chandraseelan2 *1Department of Physics, Sree Sastha Institute of Engineering and Technology, Chennai-600 123, India 2 Department of Mechanical Engineering, Sree Sastha Institute of Engineering and Technology, Chennai--600 123, India *Corres.author: [email protected] Abstract: Chalcogenides are compounds formed predominately from one or more of the chalcogen elements; sulphur, selenium and tellurium. Although first studied over fifty years ago, interest in chalcogenide glasses has, over the past few years, increased significantly as glasses, crystals and alloys find new life in a wide range of optoelectronic devices applications. Following the development of the glassy chalcogenide field, new optoelectronic materials based on these materials have been discovered. Several non-oxide glasses have been prepared and investigated in the last several decades, thus widening the groups of chalcogen materials used in various optical, electronic and optoelectronic glasses. This paper reviews the development of chalcogenide glasses, their physical properties and applications in electronics and optoelectronics. The glassy, amorphous and disordered chalcogenide materials, which are important for optoelectronic applications, are discussed. This paper also deals with an overview of representative applications these exciting optoelectronic materials. 1. Introduction The name chalcogenide originates from the Greek word “chalcos” meaning ore and “gen” meaning formation, thus the term chalcogenide is generally considered to mean ore former [1]. The elements of group sixteen of the periodic table is known as the chalcogens. The group consists of oxygen, sulphur, selenium, tellurium and polonium though oxygen is not included in the chalcogenide category.
    [Show full text]
  • The Handbook on Optical Constants of Semiconductors : In
    THE HANDBOOK ON OPTICAL CONSTANTS OF SEMICONDUCTORS In Tables and Figures Sadao Adachi Gunma University, Japan World Scientific NEW • • • JERSEY LONDON SINGAPORE BEIJING SHANGHAI • HONG KONG • TAIPEI CHENNA Contents Preface v 1 Introduction 1 1.1 Classification of Semiconductors: Grimm-Sommerfeld Rule 1 1.2 Crystal Structure 4 1.2.1 Atomic Bond 4 1.2.2 Crystal Structure 7 1.3 Dielectric Function: Tensor Representation 7 1.4 Optical Dispersion Relations 10 1.5 Optical Sum Rules 12 1.5.1 Inertial Sum Rule 12 1.5.2 dc-Conductivity Sum Rule 12 1.5.3 /-Sum Rule 13 1.6 Optical Spectra 16 1.6.1 Classification into Several Regions 16 1.6.2 The Reststrahlen Region 17 1.6.3 The Transparent and Interband Transition Regions 19 (a) Critical point 19 (b) The transparent region 21 (c) The interband transition region 24 References 28 vii viii Contents 2 Elemental Semiconductors 31 2.1 Group-IV Elemental Semiconductors 31 2.1.1 Diamond (C) 32 References 38 2.1.2 Silicon (Si) 38 References 45 2.1.3 Germanium (Ge) 45 References 54 2.1.4 Gray Tin (oc-Sn) 54 References 60 2.2 Group-VI Elemental Semiconductors 60 2.2.1 Selenium (Se) 61 References 68 2.2.2 Tellurium (Te) 68 References 76 3 Valence Binary Semiconductors I 77 3.1 IV-IV Binary Semiconductors 77 3.1.1 Cubic Silicon Carbide (3C-SiC) 78 References 85 3.1.2 Hexagonal Silicon Carbides (4H- and 6H-SiC) 85 References 94 3.1.3 Rhombohedral Silicon Carbide (15R-SiC) 95 References 95 3.2 III-V Binary Semiconductors 95 3.2.1 Cubic Boron Nitride (c-BN) 97 References 102 3.2.2 Hexagonal Boron Nitride (h-BN)
    [Show full text]
  • Yimin Wu Préparée Dans L’Equipe Verres & Céramiques UMR CNRS 6226 Institut De Sciences Chimiques De Rennes UFR Sciences Et Propriétés De La Matiére
    ANNÉE 2016 THÈSE / UNIVERSITÉ DE RENNES 1 sous le sceau de l’Université Bretagne Loire pour le grade de DOCTEUR DE L’UNIVERSITÉ DE RENNES 1 Mention : Sciences de Matériaux Ecole doctorale Science de la Matière présentée par Yimin Wu Préparée dans l’equipe Verres & Céramiques UMR CNRS 6226 Institut de Sciences Chimiques de Rennes UFR Sciences et Propriétés de la Matiére Thèse soutenue Céramiques le 16 Décembre 2016 devant le jury composé de : Sylvie Hebert semiconductrices à Directrice de recherche CNRS, Université de Caen / rapporteur base de séléniures Marcel PASQUINELLI Professeur, Université d’Aix-Marseille / rapporteur Jean Luc Adam Directeur de recherche CNRS, Université de Rennes pour des applications 1/examinateur Xianghua ZHANG Directeur de Recherche CNRS, Université de photovoltaïque et Rennes 1 / directeur de thèse XianPing Fan Professeur, Zhejiang University / co-directeur de thermoélectrique thèse Michel Cathelinaud Ingénieur de recherche CNRS, Université de Rennes 1/examinateur Acknowledgement Acknowledgement The research works presented here are accomplished in the Laboratoire de Verres et Céramiques of Université de Rennes 1. Firstly, I would like to express my gratitude to my PhD supervisor Mr. Xianghua Zhang for his patience and knowledgeability that directed me in the field of glass ceramics through the research experience. The sincere thanks are also given to my co-supervisor, Mr. Xianping Fan, for directing me in the field of nanocrystals synthesizing and recommending me to Université de Rennes 1. I would like to thank the members of jury for agreeing to judge the thesis. I wish to express my sincere thanks to Ms. Sylvie Hebert of Université de Caen and Mr.
    [Show full text]
  • Novel Passive Sampling Materials for the Determination of Priority Pollutants in Surface Waters
    Novel passive sampling materials for the determination of priority pollutants in surface waters. by Rachel NicArdgháil 53345505 Thesis submitted for the Degree of Doctor of Philosophy Supervisor: Prof. Fiona Regan Dublin City University December 2011 Declaration I hereby certify that this material, which I now submit for assessment on the programme of study leading to the award of PhD is entirely my own work, that I have exercised reasonable care to ensure that the work is original, and does not to the best of my knowledge breach any law of copyright, and has not been taken from the work of others save and to the extent that such work has been cited and acknowledged within the text of my work. Signed: _____________________________________________________ (Candidate) ID No.: ___________________ Date: ____________________ ii Rachel NicArdgháil Index ACKNOWLEDGEMENTS Firstly I’d like to thank Prof. Fiona Regan for giving me the opportunity to work within her research group in Dublin City University and for all her help within this project. I would also like to thank all the friends I have made along the way both in my undergraduate degree who joined me in the undertaking of a PhD and also to the friends I made during my time as a postgraduate researcher. I want to make special mention of the friends I made within the group, both past and present; Lisa, Aga, James, Louise, Tim, Ciprian, Imogene and Li Li. They were there for me both with cups of tea and a friendly ear to chat to but also to help me when I needed it.
    [Show full text]
  • 1. General Classification for Presenting the Experimental Results
    CHAPTER V X-RAY ABSOHPTION SPECTRA OF S01V1E IN'l'hRME'l'ALLIC COMPOUr\DS 1. General classification For presenting the experimental results obtained on the selenides, the present chapter has been divided into three parts for the convenience of discussion. The first part describes the results on some group I selenides (Ag2Se, CuSe and CU3Se2) and the second describes the work on group II selenides (ZnSe, CdSe and HgSe). In the last part of the chapter is described the work on germanium selenides (GeSe and GeSe2). GROUP I SELENIDES 2. Results Fig. 17 shows the diffraction patterns of the samples of Ag2Se, CuSe and CU3Se2 prepared in the laboratory follow­ ing the general method outlined in Chapter II, along with those of silver, selenium and copper. Cu Ka radiation was 55 56 used to record the diffraction patterns which were taken on a Philips powder camera of diameter 114.6 mm. The radiation was filtered by a nickel foil in order to render the beam monochromatic. Exposures ranging between 4-6 hours were gi vena The diffraction patterns, which are consistent with the crystal structures52 ,85,86 of the three compounds indi­ cate the formation of the respective lattices and therefore of the compounds. In Table 6 below are given the wavelengths, v/R values and the corresponding energies of the Se K discontinuity in metallic selenium and in the compounds Ag2Se, Cu:Se, and TABLE 6 DA TA ON Se K ABJOHPTION DISCON TINUI frf Absorber A v/R Energy(E) L\E X.U eV eV Metallic selenium 977.82 931.94 12651.1 .:to.07 .:t 0.5 Ag 2Se 977.62 932.13 12653.7 2.6 +0.08 .:t 0.5 CuSe 977.59 932.16 12654.1 3.0 +0.06 .:!: 0.5 CU3Se2 977.45 932.29 12655.9 4.8 .:to•07 + 0.5 It is seen from the last column of Table 6 that the Se K V.
    [Show full text]
  • B. B. Nariya, A. K. Dasadia, M. K. Bhayani, A. J. Patel, A. R. Jani
    Chalcogenide Letters Vol. 6, No. 10, October 2009, p. 549 – 554 ELECTRICAL TRANSPORT PROPERTIES OF SnS AND SnSe SINGLE CRYSTALS GROWN BY DIRECT VAPOUR TRANSPORT TECHNIQUE B. B. NARIYA*, A. K. DASADIA, M. K. BHAYANI, A. J. PATEL, A. R. JANI Department of Physics, Sardar Patel University, Vallabh Vidyanagar-388 120, Gujarat, India Tin monosulphide and Tin monoselenide single crystals have been grown by a direct vapour transport technique. Confirmation of stoichiometric proportion of constituent elements and determination of crystal structure of grown crystals were done by EDAX and powder X-ray diffraction analysis. The resistivity and thermoelectric power measurements were carried out in the temperature range 308 K to 573 K. The Hall coefficient, carrier concentration and Hall mobility were determined from Hall effect measurements at room temperature. (Received September 14, 2009; accepted September 30, 2009) Keywords: SnS, SnSe, Single crystal, Vapour transport technique 1. Introduction Among the IV-VI semiconductor compounds, tin sulphide (SnS), tin selenide (SnSe), germanium sulphide (GeS) and germanium selenide (GeSe) have the layered orthorhombic structure with eight atoms per unit cell forming biplaner layers normal to the largest c axis [1-4]. In unit cell of SnS and SnSe, atoms in a single layer are joined to three nearest neighbors by covalent bonds which forms zigzag chains along the b axis while there is only van der Walls bonding between the layers. This typical crystalline structure results in strong anisotropic optical properties at low energies and more isotropic optical properties at higher energies, which makes them interesting materials intermediate between two dimensional and three-dimensional semiconductors.
    [Show full text]
  • Forming Glasses from Se and Te
    Molecules 2009, 14, 4337-4350; doi:10.3390/molecules14114337 OPEN ACCESS molecules ISSN 1420-3049 www.mdpi.com/journal/molecules Review Forming Glasses from Se and Te Bruno Bureau 1,*, Catherine Boussard-Pledel 1, Pierre Lucas 2, Xianghua Zhang 1 and Jacques Lucas 1 1 UMR 6226 Sciences Chimiques de Rennes – Verres & Céramiques, Université de Rennes 1–CNRS, Campus de Beaulieu, 35042 Rennes Cedex, France 2 Department of Material Science and Engineering, University of Arizona, AZ 85721, USA * Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.: +33 223 236 573; Fax: +33 223 235 611. Received: 27 July 2009; in revised form: 1 September 2009 / Accepted: 23 October 2009 / Published: 26 October 2009 Abstract: Despite being close neighbors on the Periodic Table, selenium and tellurium present a totally different abilities to form glasses. Se is a very good glass former, and gives rise to numerous glass compositions which are popular for their transparency in the infrared range and their stability against crystallization. These glasses can be shaped into sophisticated optical devices such as optical fibers, planar guides or lenses. Nevertheless, their transparencies are limited at about 12 µm (depending on the thickness of the optical systems) due to the relatively small mass of the Se element. On the other hand, tellurium is heavier and its use in substitution for Se permits to shift the IR cutoff beyond 20 µm. However, the semimetallic nature of Te limits its glass formation ability and this glass family is known to be unstable and consequently has found application as phase change material in the Digital Versatile Disk (DVD) technology.
    [Show full text]
  • Free Download
    ALB Materials Inc 2360 Corporate Circle . Suite 400 Website: www.albmaterials.com Henderson, NV 89074-7739 E-mail: [email protected] Item No. Product Name CAS Number Formula Purity ALB‐semi‐AlSb Aluminum Antimonide [25152‐52‐7] AlSb 5N ALB‐semi‐Al2Se3 Aluminum Selenide [1302‐82‐5] Al2Se3 5N ALB‐semi‐Al2S3 Aluminum Sulfide [1302‐81‐4] Al2S3 5N ALB‐semi‐Al2Te3 Aluminum Telluride [12043‐29‐7] Al2Te3 5N ALB‐semi‐Sb Antimony [7440‐36‐0] Sb 5N, 6N ALB‐semi‐Sb2Se3 Antimony Selenide [1315‐05‐5] Sb2Se3 5N ALB‐semi‐Sb2S3 Antimony Sulfide [1345‐04‐6] Sb2S3 5N ALB‐semi‐Sb2Te3 Antimony Telluride [1327‐50‐0] Sb2Te3 4N, 5N ALB‐semi‐SbI3 Antimony(III) Iodide [7790‐44‐5] SbI3 4N ALB‐semi‐Sb2O3 Antimony(III) Oxide [1309‐64‐4] Sb2O3 5N ALB‐semi‐Sb2O5 Antimony(V) Oxide [1314‐60‐9] Sb2O5 5N ALB‐semi‐As2Se3 Arsenic Selenide [1303‐36‐2] As2Se3 5N ALB‐semi‐As2S3 Arsenic Sulfide [1303‐33‐9] As2S3 5N ALB‐semi‐Bi2O3 Bismuth Oxide [1304‐76‐3] Bi2O3 5N ALB‐semi‐Bi2Se3 Bismuth Selenide [12068‐69‐8] Bi2Se3 5N ALB‐semi‐Bi2S3 Bismuth Sulfide [1345‐07‐9] Bi2S3 5N ALB‐semi‐Bi2Te3 Bismuth Telluride [1304‐82‐1] Bi2Te3 4N, 5N ALB‐semi‐Cd Cadmium [7440‐43‐9]Inc Cd 5N, 6N, 7N ALB‐semi‐CdSb Cadmium Antimonide [12050‐27‐0] CdSb 5N ALB‐semi‐Cd3As2 Cadmium Arsenide [12006‐15‐4] Cd3As2 5N ALB‐semi‐CdSe Cadmium Selenide [1306‐24‐7] CdSe 4N, 5N ALB‐semi‐Cd2SnO4 Cadmium Stannate [12185‐56‐7] Cd2SnO4 5N ALB‐semi‐CdS Cadmium Sulfide [1306‐23‐6] CdS 4N, 5N ALB‐semi‐CdTe Cadmium Telluride [1306‐25‐8] CdTe 5N ALB‐semi‐Cu2S Copper Sulfide [22205‐45‐4] Cu2S 5N ALB‐semi‐GaSb Gallium Antimonide
    [Show full text]
  • Sem Icond Uctors: Data Handbook
    Otfried Madelung Sem icond uctors: Data Handbook 3rdedition Springer Short table of contents (for a more detailed table of contents see the following pages) A Introduction 1 General remarks to the structure of the volume .................................................................................... 1 2 Physical quantities tabulated in this volume ......................................................................................... 2 B Tetrahedrally bonded elements and compounds 1 Elements ofthe IVth group and IV-IV compounds ................................................ ....................... 7 2 111-V compounds .................................................................. 3 11-VI compounds ..................................................................................................... 4 I-VI1 compounds .................................................. ...................................................... 245 5 II12-V13 compounds .................................................................................................. 6 I-III-V12 compounds ..................................................................... 7 II-IV-V2 compounds ......................... ............................................................................... 329 8 I2-IV-VI3 compounds .......................................................................... ............................. 359 9 13-V-vI4 compounds ......................... ...................................................................................... 367
    [Show full text]