红外与激光工程
紅外與激光工程
홍외여격광공정
INFRARED AND LASER ENGINEERING
2015年
3期
974-978
,共5页
彭龙瑶%钟森城%朱礼国%孟坤%刘乔%彭其先%赵剑衡%张蓉竹%李泽仁
彭龍瑤%鐘森城%硃禮國%孟坤%劉喬%彭其先%趙劍衡%張蓉竹%李澤仁
팽룡요%종삼성%주례국%맹곤%류교%팽기선%조검형%장용죽%리택인
太赫兹波%石墨烯%太赫兹强度调制器%光生载流子%调制深度%透射率谱
太赫玆波%石墨烯%太赫玆彊度調製器%光生載流子%調製深度%透射率譜
태혁자파%석묵희%태혁자강도조제기%광생재류자%조제심도%투사솔보
THz waves%graphene%terahertz modulator%photo-induced carrier%modulation depth%transmittance spectrum
在太赫兹通信等系统中需要利用太赫兹波调制器对信号进行调制。基于GaAs等传统半导体材料设计和制作的调制器在太赫兹波段的响应过低,因而很难应用于太赫兹系统。为了弥补传统调制技术在带宽和调制深度不够的缺点,设计了一种全新的基于硅基石墨烯的全光控太赫兹强度调制系统。该调制系统利用材料中光生载流子对太赫兹波的吸收特性,通过调节照射到材料上的可见光光强来改变光生载流子浓度,从而实现对太赫兹波强度调制。从理论和实验两方面对这种新型太赫兹强度调制系统的调制深度和调制带宽进行了研究。研究结果表明,在泵浦光功率密度为18 mW/mm2时,该调制系统能在实验使用的THz- TDS测试系统(0.1~2.5 THz)的整个频谱范围内进行有效的调制,调制深度可达到12%。且随着泵浦光能量的增大,调制深度增大。
在太赫玆通信等繫統中需要利用太赫玆波調製器對信號進行調製。基于GaAs等傳統半導體材料設計和製作的調製器在太赫玆波段的響應過低,因而很難應用于太赫玆繫統。為瞭瀰補傳統調製技術在帶寬和調製深度不夠的缺點,設計瞭一種全新的基于硅基石墨烯的全光控太赫玆彊度調製繫統。該調製繫統利用材料中光生載流子對太赫玆波的吸收特性,通過調節照射到材料上的可見光光彊來改變光生載流子濃度,從而實現對太赫玆波彊度調製。從理論和實驗兩方麵對這種新型太赫玆彊度調製繫統的調製深度和調製帶寬進行瞭研究。研究結果錶明,在泵浦光功率密度為18 mW/mm2時,該調製繫統能在實驗使用的THz- TDS測試繫統(0.1~2.5 THz)的整箇頻譜範圍內進行有效的調製,調製深度可達到12%。且隨著泵浦光能量的增大,調製深度增大。
재태혁자통신등계통중수요이용태혁자파조제기대신호진행조제。기우GaAs등전통반도체재료설계화제작적조제기재태혁자파단적향응과저,인이흔난응용우태혁자계통。위료미보전통조제기술재대관화조제심도불구적결점,설계료일충전신적기우규기석묵희적전광공태혁자강도조제계통。해조제계통이용재료중광생재류자대태혁자파적흡수특성,통과조절조사도재료상적가견광광강래개변광생재류자농도,종이실현대태혁자파강도조제。종이론화실험량방면대저충신형태혁자강도조제계통적조제심도화조제대관진행료연구。연구결과표명,재빙포광공솔밀도위18 mW/mm2시,해조제계통능재실험사용적THz- TDS측시계통(0.1~2.5 THz)적정개빈보범위내진행유효적조제,조제심도가체도12%。차수착빙포광능량적증대,조제심도증대。
Most of terahertz (THz) systems and their application require THz modulator to modulate THz signals. Photoelectric modulators at present are made and producted by semiconductor- based, such as GaAs, materials. But unfortunately, due to their limited response to THz wave, these modulators based on traditional semiconductors are not suitable for THz systems. To overcome the limitation on modulation bandwidth and depth, a new scheme of THz wave intensity modulation system was proposed, which was based on all optically tuned graphene on silicon (GOS). This new modulation system was realized by photo- induced free carrier, which can absorb THz waves. By controlling light intensity which incident on modulator, photo- induced carrier density could be tuned, and even transmitted THz wave intensity was modulated. In this work, the fundamental properties of this THz intensity modulator was theoretically and experimentally studied , such as modulation depth and bandwidth. Our experiment results also show that it has a wide modulation bandwidth, which can modulate efficiently THz wave in THz- TDS of frequency range from 0.1 to 2.5 THz, and the typical modulation depth is 12%at an optical pump fluence of 18 mW/mm2. what's more, the modulation depth increases with increasing optical pump fluence.
