語系:
繁體中文
English
說明(常見問題)
回圖書館首頁
手機版館藏查詢
登入
回首頁
切換:
標籤
|
MARC模式
|
ISBD
Next Generation Solar Cell: Spectral...
~
Lee, Ping.
FindBook
Google Book
Amazon
博客來
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism.
紀錄類型:
書目-語言資料,印刷品 : Monograph/item
正題名/作者:
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism./
作者:
Lee, Ping.
面頁冊數:
135 p.
附註:
Source: Dissertation Abstracts International, Volume: 74-10(E), Section: B.
Contained By:
Dissertation Abstracts International74-10B(E).
標題:
Alternative Energy. -
電子資源:
http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=3566506
ISBN:
9781303177682
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism.
Lee, Ping.
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism.
- 135 p.
Source: Dissertation Abstracts International, Volume: 74-10(E), Section: B.
Thesis (Ph.D.)--State University of New York at Stony Brook, 2013.
Every component of present era solar cells is superbly optimized leaving only one major loss mechanism, the poor utilization of solar spectrum. Nonetheless, solar electric power generation represents less than 1% of the electric power consumed globally. Photovoltaic solar cells must increase the power produced per unit cost. Spectral management that broaden the response without consuming useful light will lead to improved efficiency without increased production cost. Applying amplified Raman scattering to commercial solar cells was investigated in this dissertation. The portion of the solar spectrum with energy less than the photovoltaic band gap cannot be converted into electrical energy. By Raman scattering a portion of those un-used photons can be up-converted in energy and used by the photovoltaic devices. Small particle systems has been used to amplify the Raman scattering due to the extremely long optical path length (> km) are generated by the multiple scattering by the particulate systems. The understanding of excitonic-based energy conversion used by plants could also lead to improved photovoltaic devices. Exciton transfer mechanism was investigated for the improved next generation solar cells. The absorption of chlorophyllin, derivative of chlorophyll, in different environments was discussed. A better understanding of the absorption behavior of chlorophyllin provides new insights into photosynthesis and solar cell device.
ISBN: 9781303177682Subjects--Topical Terms:
1035473
Alternative Energy.
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism.
LDR
:02370nam a2200289 4500
001
1959505
005
20140520124320.5
008
150210s2013 ||||||||||||||||| ||eng d
020
$a
9781303177682
035
$a
(MiAaPQ)AAI3566506
035
$a
AAI3566506
040
$a
MiAaPQ
$c
MiAaPQ
100
1
$a
Lee, Ping.
$3
2094946
245
1 0
$a
Next Generation Solar Cell: Spectral Management and Exciton Transfer Mechanism.
300
$a
135 p.
500
$a
Source: Dissertation Abstracts International, Volume: 74-10(E), Section: B.
500
$a
Adviser: C.M. Fortmann.
502
$a
Thesis (Ph.D.)--State University of New York at Stony Brook, 2013.
520
$a
Every component of present era solar cells is superbly optimized leaving only one major loss mechanism, the poor utilization of solar spectrum. Nonetheless, solar electric power generation represents less than 1% of the electric power consumed globally. Photovoltaic solar cells must increase the power produced per unit cost. Spectral management that broaden the response without consuming useful light will lead to improved efficiency without increased production cost. Applying amplified Raman scattering to commercial solar cells was investigated in this dissertation. The portion of the solar spectrum with energy less than the photovoltaic band gap cannot be converted into electrical energy. By Raman scattering a portion of those un-used photons can be up-converted in energy and used by the photovoltaic devices. Small particle systems has been used to amplify the Raman scattering due to the extremely long optical path length (> km) are generated by the multiple scattering by the particulate systems. The understanding of excitonic-based energy conversion used by plants could also lead to improved photovoltaic devices. Exciton transfer mechanism was investigated for the improved next generation solar cells. The absorption of chlorophyllin, derivative of chlorophyll, in different environments was discussed. A better understanding of the absorption behavior of chlorophyllin provides new insights into photosynthesis and solar cell device.
590
$a
School code: 0771.
650
4
$a
Alternative Energy.
$3
1035473
650
4
$a
Energy.
$3
876794
650
4
$a
Engineering, Materials Science.
$3
1017759
690
$a
0363
690
$a
0791
690
$a
0794
710
2
$a
State University of New York at Stony Brook.
$b
Materials Science and Engineering.
$3
1680561
773
0
$t
Dissertation Abstracts International
$g
74-10B(E).
790
$a
0771
791
$a
Ph.D.
792
$a
2013
793
$a
English
856
4 0
$u
http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=3566506
筆 0 讀者評論
館藏地:
全部
電子資源
出版年:
卷號:
館藏
1 筆 • 頁數 1 •
1
條碼號
典藏地名稱
館藏流通類別
資料類型
索書號
使用類型
借閱狀態
預約狀態
備註欄
附件
W9254333
電子資源
11.線上閱覽_V
電子書
EB
一般使用(Normal)
在架
0
1 筆 • 頁數 1 •
1
多媒體
評論
新增評論
分享你的心得
Export
取書館
處理中
...
變更密碼
登入