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Dye-Sensitized Solar Cells Based on a Single-Crystalline TiO2 Nanorod Film

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(49),
21360-21365

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(11),
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(29),
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(26),
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(9),
4228-4236

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(51),
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(proofing),

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(8),
3359-3363

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The Journal of Physical Chemistry C 0
(proofing),

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(8),
4316-4319

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(4),
815-819

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(50),
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(45),
22652-22663

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(32),
15932-15938

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(16),
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(27),
275402

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(2),

N. Sriharan, N. Muthukumarasamy, T. S. Senthil, Misook Kang

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(3),
743-752

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(8),
085605

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(2),
56

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(1),
016802

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(1),
21

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2018,150-181

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(1),

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(12),
456

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(10),
5837-5847

Selma M.H. Al-Jawad

Materials Science in Semiconductor Processing 2017 67, 75-83

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Poulomi Roy

2017,147-197

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(6),
822-828

Chih-Hung Tsai, Wei-Chih Huang, Wun-Shiuan Wang, Chun-Jyun Shih, Wen-Feng Chi, Yu-Chung Hu, Yuan-Hsiang Yu

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Yuan-Hsiang Yu, I-Jang Teng, Yu-Chien Hsu, Wei-Chih Huang, Chun-Jyun Shih, Chih-Hung Tsai

Organic Electronics 2017 42, 209-220

S Wahyuningsih, L Rinawati, R M I Munifa, A H Ramelan, Eko Sulistyono

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Solar Energy Materials and Solar Cells 2017 160, 463-469

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(35),
21547-21555

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(18),
8155-8186

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Sustainable Energy & Fuels 2017 1
(3),
520-528

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Journal of Alloys and Compounds 2017 692, 1004-1009

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2016,1-6

K. Mohan Kumar, S. Godavarthi, T.V.K. Karthik, M. Mahendhiran, A. Hernandez-Eligio, N. Hernandez-Como, V. Agarwal, L. Martinez Gomez

Materials Letters 2016 183, 211-214

Yajie Wang, Chengbin Fei, Rong Zhang, Lixue Guo, Ting Shen, Jianjun Tian, Guozhong Cao

MRS Communications 2016 6
(03),
226-233

Chih-Hung Tsai, Wei-Chih Huang, Yu-Chien Hsu, Chun-Jyun Shih, I-Jang Teng, Yuan-Hsiang Yu

Electrochimica Acta 2016 213, 791-801

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Materials Letters 2016 174, 17-20

Sasipriya Kathirvel, Chaochin Su, Yung-Jen Shiao, Ya-Fen Lin, Bo-Ren Chen, Wen-Ren Li

Solar Energy 2016 132, 310-320

V.V. Burungale, V.V. Satale, A.J. More, K.K.K. Sharma, A.S. Kamble, J.H. Kim, P.S. Patil

Journal of Colloid and Interface Science 2016 470, 108-116

José D. Costa, Paula Quitério, Arlete Apolinário, Célia T. Sousa, João Azevedo, João Ventura, Luísa Andrade, Adélio Mendes, João P. Araújo

Materials Letters 2016 171, 224-227

Yuan-Hsiang Yu, Wen-Feng Chi, Wei-Chih Huang, Wun-Shiuan Wang, Chun-Jyun Shih, Chih-Hung Tsai

Organic Electronics 2016 31, 207-216

Masoud Iraj, Fatemeh Dehghan Nayeri, Ebrahim Asl-Soleimani, Keyvan Narimani

Journal of Alloys and Compounds 2016 659, 44-50

Md. Mahbubur Rahman, Sang Hyuk Im, Jae-Joon Lee

Nanoscale 2016 8, 5884-5891

Jinghua Hu, Jiejie Cheng, Shengqiang Tong, Yingping Yang, Mengwei Chen, Shiwu Hu

International Journal of Photoenergy 2016,1

Yue-Sheng LI, Zhi-Yong SONG, Jiang-Tao QIN, Hai-Tao HUANG, Yan HAN

Chinese Journal of Analytical Chemistry 2016 44
(1),
61-67

Qiqian Gao, Shihan Sun, Xuesong Li, Xueyu Zhang, Lianfeng Duan, Wei Lü

Nanoscale Research Letters 2016,

Zhichun Yang, Waqar Ahmad, Liang Chu, Majid Raissan Al-bahrani, Fanfan Tu, Yumei Wang, Hang Zhang, Xi Wang, Jun Su, Nishuang Liu, Luying Li, Changping Yang, Yihua Gao

RSC Advances 2016 6
(60),
55071-55078

Haitao Zhou, Lin Li, Dianli Jiang, Yingbing Lu, Kai Pan

RSC Advances 2016 6
(72),
67968-67975

S.A. Mozaffari, M. Ranjbar, E. Kouhestanian, H. Salar Amoli, M.H. Armanmehr

Materials Science in Semiconductor Processing 2015 40, 285-292

Jie Zhang, Yichuan Rui, Yaogang Li, Qinghong Zhang, Hongzhi Wang

Electrochimica Acta 2015 176, 480-487

Chih-Hung Tsai, Po-Hsi Fei, Chih-Han Chen

Materials 2015 8
(9),
5715-5729

Der-Ray Huang, Yan-Jang Jiang, Run-Lin Liou, Chih-Han Chen, Yi-An Chen, Chih-Hung Tsai

Applied Surface Science 2015 347, 64-72

Azam Mayabadi, Amit Pawbake, Sachin Rondiya, Avinash Rokade, Ravindra Waykar, Rupali Kulkarni, Ashok Jadhavar, Mahesh Kamble, Bharat Gabhale, Vaishali Waman, Vasant Sathe, Habib Pathan, Sandesh Jadkar

Thin Solid Films 2015 589, 493-502

Xinkai Wu, Yanru Zhao, Chongqing Yang, Gufeng He

Journal of Materials Science 2015 50, 4250-4257

Guanxi Wang, Wei Xiao, Jiaguo Yu

Energy 2015 86, 196-203

Chih-Hung Tsai, Chih-Han Chen, Po-Hsi Fei, Yu-Kuei Hsu

Electrochimica Acta 2015 167, 112-118

Chih-Hung Tsai, Po-Hsi Fei, Wei-Chien Wu

Electrochimica Acta 2015 165, 356-364

Jalal Rouhi, Mohamad Hafiz Mamat, C. H. Raymond Ooi, Shahrom Mahmud, Mohamad Rusop Mahmood

PLOS ONE 2015 10
(4),
e0123433

Zhenhuan Zhao, Jian Tian, Yuanhua Sang, Andreu Cabot, Hong Liu

Advanced Materials 2015 27
(10.1002/adma.v27.16),
2557-2582

Isabella Concina, Alberto Vomiero

Small 2015 11
(10.1002/smll.v11.15),
1744-1774

D. Maheswari, D. Sreenivasan

Applied Solar Energy 2015 51, 112-116

D. Maheswari, P. Venkatachalam

Acta Metallurgica Sinica (English Letters) 2015 28, 354-361

D. Maheswari, P. Venkatachalam

Journal of Electronic Materials 2015 44, 967-976

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Materials Chemistry and Physics 2015 151, 330-336

Mahboubeh Naeimi Sani Sabet, Maziar Marandi, Farzaneh Ahmadloo

The European Physical Journal Applied Physics 2015 69, 20401

Lijian Meng, Hong Chen, Can Li, M.P. dos Santos

Thin Solid Films 2015 577, 103-108

Wanyu Zhao, Wuyou Fu, Jingkuo Chen, Huayang Li, Hari Bala, Xiaodong Wang, Guang Sun, Jianliang Cao, Zhanying Zhang

Thin Solid Films 2015 577, 49-55

Hongxia Sun, Peng Ruan, Zhongqiu Bao, Lei Chen, Xingfu Zhou

Solid State Sciences 2015 40, 60-66

Chih-Hung Tsai, Chih-Han Chen, Yu-Chen Hsiao, Ping-Yuan Chuang

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Ping-Lin Kuo, Chun-Hou Liao

Journal of Power Sources 2015 275, 720-726

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D. Maheswari, P. Venkatachalam

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Applied Surface Science 2015 324, 532-537

Weiqi Wang, Jiazang Chen, Jianqiang Luo, Yuzhi Zhang, Lian Gao, Yangqiao Liu, Jing Sun

Applied Surface Science 2015 324, 143-151

K. Ahmadi, Ali Abdolahzadeh Ziabari, K. Mirabbaszadeh, S. Ahmadi

Superlattices and Microstructures 2015 77, 25-34

D. Maheswari, P. Venkatachalam

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RSC Adv. 2015 5
(73),
59314-59319

Baoyuan Wang, Jingshu Wan, Qingyun Liu, Jun Zhang, Hao Wang

RSC Advances 2015 5
(101),
82968-82976

Sambhaji S. Bhande, Dipak V. Shinde, Kailas K. Tehare, Supriya A. Patil, Rajaram S. Mane, Mu. Naushad, Z.A Alothman, K.N. Hui, Sung Hwan Han

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(15),
153107

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Thin Solid Films 2014 568, 122-130

Lijian Meng, Hong Chen, Can Li, Manuel Pereira dos Santos

Frontiers in Materials 2014 1,

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(10.1111/jace.2014.97.issue-9),
2873-2879

M.Y. Liao, L. Fang, C.L. Xu, F. Wu, Q.L. Huang, M. Saleem

Materials Science in Semiconductor Processing 2014 24, 1-8

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Materials Research Innovations 2014 18
(sup4),
S4-18-S4-21

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Thin Solid Films 2014 558, 1-19

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(17),
4916-4920

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RSC Advances 2014 4, 943

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Electrochimica Acta 2014 117, 268-275

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Journal of Materials Chemistry A 2014 2, 8749

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Eui-Hyun Kong, Yong-June Chang, Hyun Myung Jang

RSC Adv. 2014 4, 943-947

Shuping Huang, Dmitri S. Kilin

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L. Zhu, Y.L. Zhao, X.P. Lin, X.Q. Gu, Y.H. Qiang

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(37),
8756

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(87),
47031-47038

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(23),
8749-8757

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RSC Adv. 2014 4
(85),
45180-45184

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(28),
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Journal of Power Sources 2013 226, 94-100

Qin Hu, Congcong Wu, Liqiang Cao, Bo Chi, Jian Pu, Li Jian

Journal of Power Sources 2013 226, 8-15

Yu-Yen Kuo, Chao-Hsin Chien

Electrochimica Acta 2013 91, 337-343

Xudong Wang, Jian Shi

Journal of Materials Research 2013 28
(03),
270-279

Daesub Hwang, Horim Lee, Yongsok Seo, Dongho Kim, Seong Mu Jo, Dong Young Kim

J. Mater. Chem. A 2013 1, 1359-1367

Xiaoyan Wang, Lidong Sun, Sam Zhang, Xiu Wang, Kaifu Huo, Jijiang Fu, Hairong Wang, Dongliang Zhao

RSC Advances 2013 3, 11001

Xiao Yu, Hai Wang, Yong Liu, Xiang Zhou, Baojun Li, Ling Xin, Yu Zhou, Hui Shen

J. Mater. Chem. A 2013 1, 2110-2117

Wenguang Cheng, Wenzhe Li, Shaofei Ji, Dandan Yang, Liduo Wang, Xiaozhong Qu, Chengliang Zhang, Fuxin Liang, Qian Wang, Jiaoli Li, Zhenzhong Yang

Journal of Materials Chemistry A 2013 1, 8023

Daesub Hwang, Horim Lee, Yongsok Seo, Dongho Kim, Seong Mu Jo, Dong Young Kim

Journal of Materials Chemistry A 2013 1, 1359

Kazuhiro Manseki, Yosuke Kondo, Takayuki Ban, Takashi Sugiura, Tsukasa Yoshida

Dalton Transactions 2013 42, 3295

Yu Pin Lin, Sih Yin Lin, Yuan Ching Lee, Yui Whei Chen-Yang

Journal of Materials Chemistry A 2013 1, 9875

Xiao Yu, Hai Wang, Yong Liu, Xiang Zhou, Baojun Li, Ling Xin, Yu Zhou, Hui Shen

Journal of Materials Chemistry A 2013 ,

Luisa De Marco, Michele Manca, Roberto Giannuzzi, Maria R. Belviso, P. Davide Cozzoli, Giuseppe Gigli

Energy & Environmental Science 2013 6, 1791

Brijesh Tripathi, Pankaj Yadav, Manoj Kumar

Results in Physics 2013 3, 182-186

Na Li, Nengqian Pan, Danhong Li, Shiwei Lin

International Journal of Photoenergy 2013 2013, 1-5

Jie Qu, Chao Lai

Journal of Nanomaterials 2013 2013, 1-11

Chih-Hung Tsai, Yu-Tang Tsai, Tsung-Wei Huang, Sui-Ying Hsu, Yan-Fang Chen, Yuan-Hsuan Jhang, Lun Hsieh, Chung-Chih Wu, Yen-Shan Chen

Journal of Nanomaterials 2013 2013, 1-12

Dharani Sabba, Nripan Mathews, Julianto Chua, Stevin S. Pramana, Hemant K. Mulmudi, Qing Wang, Subodh G. Mhaisalkar

Scripta Materialia 2012 ,

Dajiang Zheng, Miaoqiang Lv, Shiping Wang, Wenxi Guo, Lan Sun, Changjian Lin

Electrochimica Acta 2012 83, 155-159

Yuan-Hsuan Jhang, Yu-Tang Tsai, Chih-Hung Tsai, Sui-Ying Hsu, Tsung-Wei Huang, Chun-Yang Lu, Ming-Che Chen, Yan-Fang Chen, Chung-Chih Wu

Organic Electronics 2012 13, 1865-1872

Yichuan Rui, Yaogang Li, Hongzhi Wang, Qinghong Zhang

Chemistry – An Asian Journal 2012 7, 2313-2320

Runbang Tao, Takahiro Tomita, Raymond Albert Wong, Keiko Waki

Journal of Power Sources 2012 214, 159-165

M.R. Mohammadi, R.R.M. Louca, D.J. Fray, M.E. Welland

Solar Energy 2012 86, 2654-2664

Jae Hong Kim, Hee Suk Jung, Yong Seung Chi, Tae Jin Kang

Solar Energy 2012 86, 2606-2612

Jinsoo Lee, Junghwan Yoon, Minhea Jin, Myeongkyu Lee

Journal of Applied Physics 2012 112
(4),
043110

Min Wang, Shouli Bai, Aifan Chen, Yandong Duan, Qiuping Liu, Dianqing Li, Yuan Lin

Electrochimica Acta 2012 77, 54-59

Sujatha Singh, Harjeet Kaur, V.N. Singh, Kiran Jain, T.D. Senguttuvan

Sensors and Actuators B: Chemical 2012 171-172, 899-906

Meng Cui, Sha Tian, Hua Zhao, Rong Jin, Yan Chen, Bin Liu, Heqing Yang

Physica E: Low-dimensional Systems and Nanostructures 2012 44, 2110-2117

Menglei Chang, Liangpeng Wu, Xinjun Li, Wei Xu

Journal of Materials Science & Technology 2012 28, 594-598

Guotian Dai, Li Zhao, Shimin Wang, Jinhua Hu, Binghai Dong, Hongbing Lu, Jing Li

Journal of Alloys and Compounds 2012 ,

Z.G. Shang, Z.Q. Liu, P.J. Shang, J.K. Shang

Journal of Materials Science & Technology 2012 28, 385-390

Sui-Ying Hsu, Chih-Hung Tsai, Chun-Yang Lu, Yu-Tang Tsai, Tsung-Wei Huang, Yuan-Hsuan Jhang, Yan-Fang Chen, Chung-Chih Wu, Yen-Shan Chen

Organic Electronics 2012 13, 856-863

Chieko Shimada, Koji Kitamura, Seimei Shiratori

Japanese Journal of Applied Physics 2012 51, 044106

XIANWEI HUANG, PING SHEN, XIAOMING FENG, ZHUO TAN, BIN ZHAO, SONGTING TAN

Nano 2012 07
(02),
1250010

2012,151-197

R. S. Chen, C. A. Chen, H. Y. Tsai, W. C. Wang, Y. S. Huang

Applied Physics Letters 2012 100
(12),
123108

Ning Liu, Kiyoung Lee, Patrik Schmuki

Electrochemistry Communications 2012 15, 1-4

Jincheng Liu, Yinjie Wang, Darren Sun

Renewable Energy 2012 38, 214-218

Ke Chen, Jingyi Li, Wenxi Wang, Yumin Zhang, Xiaojing Wang, Haiquan Su

Materials Science in Semiconductor Processing 2012 15, 20-26

Guotian Dai, Li Zhao, Jing Li, Li Wan, Fan Hu, Zuxun Xu, Binghai Dong, Hongbing Lu, Shimin Wang, Jiaguo Yu

Journal of Colloid and Interface Science 2012 365, 46-52

Yongseok Jun, Jong Hyeok Park, Man Gu Kang

Chemical Communications 2012 48, 6456

Chih-Hung Tsai, Sui-Ying Hsu, Chun-Yang Lu, Yu-Tang Tsai, Tsung-Wei Huang, Yan-Fang Chen, Yuan-Hsuan Jhang, Chung-Chih Wu

Organic Electronics 2012 13, 199-205

Weiguang Yang, Yali Wang, Weimin Shi

CrystEngComm 2012 14, 230-234

Xiao Wang, Feng Hao, Huiyuan Chen, Gang Wang, Jianbao Li, Hong Lin

Pure and Applied Chemistry 2012 , 1

Tianci Zhang, Xiaoye Hu, Ming Fang, Lide Zhang, Zhaoming Wang

CrystEngComm 2012 14, 7656

Zhenhuan Zhao, Hong Liu, Shaowei Chen

Nanoscale 2012 4, 7301

Eui-Hyun Kong, Yong-June Chang, Yoon-Cheol Park, Yeon-Hee Yoon, Hyun-Jin Park, Hyun Myung Jang

Physical Chemistry Chemical Physics 2012 14, 4620

Ning Han, Fengyun Wang, Johnny C. Ho

Nanomaterials and Energy 2012 1
(1),
4-17

H. J. Cho, D. Jung

Bulletin of the Korean Chemical Society 2011 32, 4382-4386

Susana LA Andrade, Yilin Hu, Markus W Ribbe, Oliver Einsle

2011,

Li Zhang, Yaogang Li, Qinghong Zhang, Guoying Shi, Hongzhi Wang

Chemistry Letters 2011 40
(12),
1371-1373

Motonari Adachi, Katsuya Yoshida, Takehiro Kurata, Jun Adachi, Katsumi Tsuchiya, Yasushige Mori, Fumio Uchida

Journal of Materials Research 2011 , 1-8

Tsai Chih-Hung, Hsu Sui-Ying, Huang Tsung-Wei, Tsai Yu-Tang, Chen Yan-Fang, Yuan Hsuan Jhang, Lun Hsieh, Wu Chung-Chih, Chen Yen-Shan, Chen Chieh-Wei, Li Chung-Chun

Organic Electronics 2011 12, 2003-2011

Jang-Yul Kim, Tohru Sekino, Shun-Ichiro Tanaka

International Journal of Applied Ceramic Technology 2011 8
(10.1111/ijac.2011.8.issue-6),
1353-1362

A. P. Caricato, M. R. Belviso, M. Catalano, M. Cesaria, P. D. Cozzoli, A. Luches, M. G. Manera, M. Martino, R. Rella, A. Taurino

Applied Physics A 2011 105, 605-610

Jiang Sheng, Linhua Hu, Wenxin Li, Li’e Mo, Huajun Tian, Songyuan Dai

Solar Energy 2011 85, 2697-2703

Qiaoying Jia, Wenxiu Que, Jin Zhang

physica status solidi (a) 2011 208
(10.1002/pssa.v208.10),
2313-2316

Jiajie Fan, Weiquan Cai, Jiaguo Yu

Chemistry – An Asian Journal 2011 6, 2481-2490

Eun-Yi Kim, Wan-In Lee, Chin Myung Whang

Bulletin of the Korean Chemical Society 2011 32, 2671-2676

Difeng Qian, Yaogang Li, Qinghong Zhang, Guoying Shi, Hongzhi Wang

Journal of Alloys and Compounds 2011 ,

Junghwan Yoon, Minhea Jin, Myeongkyu Lee

Advanced Materials 2011 , n/a-n/a

Lijian Meng, Can Li, M. P. dos Santos

Journal of Inorganic and Organometallic Polymers and Materials 2011 ,

Alexander C Santulli, Christopher Koenigsmann, Amanda L Tiano, Donald DeRosa, Stanislaus S Wong

Nanotechnology 2011 22, 245402

Yu-Ching Hsu, Tony Chang Chi Wu, I-Chun Cheng, Jian-Zhang Chen, Mu-Rong Yang

Japanese Journal of Applied Physics 2011 50, 06GF09

A.A. Aref, Liangbin Xiong, Nannan Yan, A.M. Abdulkarem, Ying Yu

Materials Chemistry and Physics 2011 127, 433-439

Chun-Hou Liao, Wu-Tsung Shih, Chi-Chang Chen, Yuh-Lang Lee, Ping-Lin Kuo

Thin Solid Films 2011 519, 5552-5557

Vivek Dhas, Subas Muduli, Shruti Agarkar, Abhimanyu Rana, Beatrice Hannoyer, Rahul Banerjee, Satishchandra Ogale

Solar Energy 2011 85, 1213-1219

Marija Drev, Urša Opara Krašovec, Mateja Hočevar, Marko Berginc, Marjeta Kržmanc Maček, Marko Topič

Journal of Sol-Gel Science and Technology 2011 ,

Ambily Mathew, G. Mohan Rao, N. Munichandraiah

Materials Chemistry and Physics 2011 127, 95-101

Chun-Xia Zhao, Lizhong He, Shi Zhang Qiao, Anton P.J. Middelberg

Chemical Engineering Science 2011 66, 1463-1479

Yunqian Dai, Wenying Liu, Eric Formo, Yueming Sun, Younan Xia

Polymers for Advanced Technologies 2011 22, 326-338

Jang-Yul Kim, Tohru Sekino, Shun-Ichiro Tanaka

Journal of Materials Science 2011 46, 1749-1757

J Caro

2011,423-447

Luísa Andrade, Helena Aguilar Ribeiro, Adélio Mendes

2011,

Sara Cavaliere, Surya Subianto, Iuliia Savych, Deborah J. Jones, Jacques Rozière

Energy & Environmental Science 2011 4, 4761

Patcharee Charoensirithavorn, Takashi Sagawa, Shuzi Hayase, Susumu Yoshikawa

Journal of Solar Energy Engineering 2011 133, 011101

Yu-Kai Han, Mei-Ying Chang, Wen-Yao Huang, Hsin-Yu Pan, Ko-Shan Ho, Tar-Hwa Hsieh, Sin-Yu Pan

Journal of The Electrochemical Society 2011 158, K88

Zusing Yang, Chia-Ying Chen, Prathik Roy, Huan-Tsung Chang

Chemical Communications 2011 47, 9561

Luisa De Marco, Michele Manca, Raffaella Buonsanti, Roberto Giannuzzi, Francesco Malara, Paola Pareo, Luigi Martiradonna, Nunzia M. Giancaspro, P. Davide Cozzoli, Giuseppe Gigli

Journal of Materials Chemistry 2011 21, 13371

Xiangfeng Wei, Jiehua Liu, Yun Zhi Chua, Junling Song, Xue-Wei Liu

Energy & Environmental Science 2011 4, 2054

Qiuliu Huang, Gang Zhou, Liang Fang, Lipeng Hu, Zhong-Sheng Wang

Energy & Environmental Science 2011 4, 2145

Joo Hwan Koh, Jong Kwan Koh, Jin Ah Seo, Jong-Shik Shin, Jong Hak Kim

Nanotechnology 2011,365401

Jijun Qiu, Fuwei Zhuge, Kun Lou, Xiaomin Li, Xiangdong Gao, Xiaoyan Gan, Weidong Yu, Hyung-Kook Kim, Yoon-Hwae Hwang

Journal of Materials Chemistry 2011 21, 5062

Huei-Siou Chen, Chaochin Su, Ji-Lian Chen, Tsai-Yin Yang, Nai-Mu Hsu, Wen-Ren Li

Journal of Nanomaterials 2011 2011, 1-8

Daiki Nagamatsu, Takashi Nemoto, Hiroki Kurata, Jinting Jiu, Motonari Adachi, Seiji Isoda

MATERIALS TRANSACTIONS 2011 52
(3),
280-284

Aixiang Wei, Wang Zhao, Jun Liu, Zengxian Ge, Chuanbiao Liu

Integrated Ferroelectrics 2011 127
(1),
157-163

Yu Yen Kuo, Jui Guo Lin, Chao Hsin Chien

Journal of The Electrochemical Society 2011 159
(2),
K46-K49

T. S. Senthil, N. Muthukumarasamy, M. Thambidurai, R. Balasundaraprabhu, S. Agilan

Journal of Sol-Gel Science and Technology 2010 ,

Jan Kehres, Jens Wenzel Andreasen, Frederik Christian Krebs, Alfons M. Molenbroek, Ib Chorkendorff, Tejs Vegge

Journal of Applied Crystallography 2010 43, 1400-1408

D. P. Dubal, D. S. Dhawale, A. M. More, C. D. Lokhande

Journal of Materials Science 2010 ,

X.D. Li, D.W. Zhang, S. Chen, Z.A. Wang, Z. Sun, X.J. Yin, S.M. Huang

Materials Chemistry and Physics 2010 124, 179-183

Chao-Chin Su, Wei-Cheng Hung, Chin-Jung Lin, Shu-Hua Chien

Journal of the Chinese Chemical Society 2010 57
(10.1002/jccs.v57.5B),
1131-1135

Viswanathan S. Saji, Myoungho Pyo

Thin Solid Films 2010 518, 6542-6546

X. D. LI, D. W. ZHANG, Z. A. WANG, Z. SUN, S. M. HUANG, X. J. YIN, C. F. LIN

International Journal of Nanoscience 2010 09
(04),
301-305

Lidong Sun, Sam Zhang, Xiao Wei Sun, Xiaodong He

2010,57-108

W. Q. Peng, Y.-J. Liu, M. Aizawa, Z.-M. Wang, H. Hatori, T. Hirotsu

Journal of Porous Materials 2010 ,

Ru-Hua Tao, Jin-Ming Wu, Hong-Xing Xue, Xiao-Mei Song, Xu Pan, Xia-Qin Fang, Xiao-Dong Fang, Song-Yuan Dai

Journal of Power Sources 2010 195, 2989-2995

Viswanathan S. Saji, KyuKwan Zong, Myoungho Pyo

Journal of Photochemistry and Photobiology A: Chemistry 2010 212, 81-87

U. Terranova, D. R. Bowler

The Journal of Physical Chemistry C 2010 114
(14),
6491-6495

Hui Xu, Xia Tao, Dong-Ting Wang, Yan-Zhen Zheng, Jian-Feng Chen

Electrochimica Acta 2010 55, 2280-2285

J Ida, T Honma, S Hayashi, K Nakajima, E Wada, A Shimizu

Journal of Physics Conference Series 2010,012132

Yuanhao Wang, Hongxing Yang, Hongmei Xu

Materials Letters 2010 64, 164-166

Jiaguo Yu, Jiajie Fan, Kangle Lv

Nanoscale 2010 2, 2144

Ian Ivar Suni

2010,

Jiaguo Yu, Jiajie Fan, Li Zhao

Electrochimica Acta 2010 55, 597-602

Yu-Kai Han, Jenq-Nan Yih, Mei-Ying Chang, Wen-Yao Huang, Ko-Shan Ho, Tar-Hwa Hsieh, Jhih-Gong Lou

Macromolecular Chemistry and Physics 2010 , n/a-n/a

Pavel A. Sedach, Terry J. Gordon, Sayed Y. Sayed, Tobias Fürstenhaupt, Ruohong Sui, Thomas Baumgartner, Curtis P. Berlinguette

Journal of Materials Chemistry 2010 20, 5063

Xiangqing Li, Ying Cheng, Lifang Liu, Jin Mu

Colloids and Surfaces A: Physicochemical and Engineering Aspects 2010 353, 226-231

P. Sudhagar, June Hyuk Jung, Suil Park, R. Sathyamoorthy, Heejoon Ahn, Yong Soo Kang

Electrochimica Acta 2009 55, 113-117

Liguo Jin, Jin Zhai, Liping Heng, Tianxin Wei, Liping Wen, Lei Jiang, Xiaoxu Zhao, Xianyou Zhang

Journal of Photochemistry and Photobiology C: Photochemistry Reviews 2009 10, 149-158

A. Vomiero, I. Concina, M. M. Natile, E. Comini, G. Faglia, M. Ferroni, I. Kholmanov, G. Sberveglieri

Applied Physics Letters 2009 95
(19),
193104

J. Caro

Microporous and Mesoporous Materials 2009 125, 79-84

D. Çakır, O. Gülseren

Physical Review B 2009 80,

Rong-Ho Lee, Yu-Wei Huang

Thin Solid Films 2009 517, 5903-5908

Chih-Chieh Wang, Chung-Yi Yu, Chi-Chung Kei, Chao-Te Lee, Tsong-Pyng Perng

Nanotechnology 2009 20, 285601

A. Vomiero, G. Jimenez, C. Baratto, E. Comini, I. Concina, G. Faglia, M. Falasconi, M. Ferroni, I. Kholmanov, N. Poli, A. Ponzoni, S. Todros, G. Sberveglieri

2009,001325-001326

Chien-Hsin Yang, Han-Lung Chen, Yao-Yuan Chuang, Chun-Guey Wu, Chiao-Pei Chen, Shao-Hong Liao, Tzong-Liu Wang

Journal of Power Sources 2009 188, 627-634

Daoai Wang, Bo Yu, Feng Zhou, Chengwei Wang, Weimin Liu

Materials Chemistry and Physics 2009 113, 602-606

V THAVASI, V RENUGOPALAKRISHNAN, R JOSE, S RAMAKRISHNA

Materials Science and Engineering: R: Reports 2009 63, 81-99

Huei-Siou Chen, Chaochin Su, Chin-Kai Lin, Yi-Fang Hsieh, Chong-Kuang Yang, Wen-Ren Li

JOURNAL OF CHEMICAL ENGINEERING OF JAPAN 2009 42, s36-s42

Patcharee Charoensirithavorn, Yuhei Ogomi, Takashi Sagawa, Shuzi Hayase, Susumu Yoshikawa

Journal of The Electrochemical Society 2009 156, H803

Shuang Li, Yaogang Li, Hongzhi Wang, Wugang Fan, Qinghong Zhang

European Journal of Inorganic Chemistry 2009,4078

Soon Hyung Kang, Hyun Sik Kim, Jae-Yup Kim, Yung-Eun Sung

Nanotechnology 2009,355307

Shuang LI, Qing-Hong ZHANG, Yao-Gang LI, Hong-Zhi WANG

Journal of Inorganic Materials 2009,675

Eun Sik Kwak, Wonmok Lee, Nam-Gyu Park, Junkyung Kim, Hyunjung Lee

Advanced Functional Materials 2009,1093

Haiyan Li, Jun Jiao

MRS Proceedings 2009 1167,

Xiao-Hong WU, Song WANG, Yun GUO, Zhao-Yang XIE, Lu HAN, Zhao-Hua JIANG

Chinese Journal of Chemistry 2008 26
(10.1002/cjoc.v26:10),
1939-1943

Kaname Yoshida, Jinting Jiu, Daiki Nagamatsu, Takashi Nemoto, Hiroki Kurata, Motonari Adachi, Seiji Isoda

Molecular Crystals and Liquid Crystals 2008 491, 14-20

A. Sadeghzadeh Attar, M. Sasani Ghamsari, F. Hajiesmaeilbaigi, Sh. Mirdamadi, K. Katagiri, K. Koumoto

Journal of Materials Science 2008 43, 5924-5929

A. Sadeghzadeh Attar, M. Sasani Ghamsari, F. Hajiesmaeilbaigi, Sh. Mirdamadi, K. Katagiri, K. Koumoto

Journal of Materials Science 2008 ,

Lei Yang, Yuan Lin, Jianguang Jia, Xurui Xiao, Xueping Li, Xiaowen Zhou

Journal of Power Sources 2008 182, 370-376

T Stergiopoulos, A Ghicov, V Likodimos, D S Tsoukleris, J Kunze, P Schmuki, P Falaras

Nanotechnology 2008 19, 235602

G. Sberveglieri, E. Comini, G. Faglia, M. Ferroni, G. Jimenez, A. Vomiero

2008,1-3

Jih-Jen Wu, Guan-Ren Chen, Chia-Chun Lu, Wei-Ting Wu, Jen-Sue Chen

Nanotechnology 2008 19, 105702

Cheng-Yu Kuo, Shih-Yuan Lu

Nanotechnology 2008 19, 095705

Markéta Zukalová, Jan Procházka, Arnošt Zukal, Jun Ho Yum, Ladislav Kavan

Inorganica Chimica Acta 2008 361, 656-662

S. H. Kang, S.-H. Choi, M.-S. Kang, J.-Y. Kim, H.-S. Kim, T. Hyeon, Y.-E. Sung

Advanced Materials 2008 20
(10.1002/adma.v20:1),
54-58

Luís Moreira Gonçalves, Verónica de Zea Bermudez, Helena Aguilar Ribeiro, Adélio Magalhães Mendes

Energy & Environmental Science 2008,655

Abbas Sadeghzadeh Attar, Morteza Sasani Ghamsari, Fereshteh Hajiesmaeilbaigi, Shamsoddin Mirdamadi

Journal of Materials Science 2008,1723

Ismael C. Flores, Jilian Nei de Freitas, Claudia Longo, Marco-Aurelio De Paoli, Herbert Winnischofer, Ana Flávia Nogueira

Journal of Photochemistry and Photobiology A: Chemistry 2007 189, 153-160

Ben F. Cottam, Siva Krishnadasan, Andrew J. deMello, John C. deMello, Milo S. P. Shaffer

Lab Chip 2007 7, 167-169

Yong Zhao, Jin Zhai, Tianxin Wei, Lei Jiang, Daoben Zhu

Journal of Materials Chemistry 2007 17, 5084

Ben F. Cottam, Siva Krishnadasan, Andrew J. deMello, John C. deMello, Milo S. P. Shaffer

Lab on a Chip 2007 7, 167

Jih-Jen Wu, Guan-Ren Chen, Hung-Hsien Yang, Chen-Hao Ku, Jr-Yuan Lai

Applied Physics Letters 2007 90, 213109

Avi Shalav

Progress in Photovoltaics: Research and Applications 2006 14
(10.1002/pip.v14:8),
753-758

Tsung-Wei Zeng, Yun-Yue Lin, Hsi-Hsing Lo, Chun-Wei Chen, Cheng-Hsuan Chen, Sz-Chian Liou, Hong-Yun Huang, Wei-Fang Su

Nanotechnology 2006 17, 5387-5392

Avi shalav, Bryce S. Richards

Progress in Photovoltaics: Research and Applications 2006 14
(10.1002/pip.v14:4),
373-379

Qiaohong Yao, Junfeng Liu, Qing Peng, Xun Wang, Yadong Li

Chemistry – An Asian Journal 2006,737

S. A. Akhoon, S. Rubab, M. A. Shah

,197-225

S. A. Akhoon, S. Rubab, M. A. Shah

,277-312

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Natural gas and renewables will be most of US power and US will export oil, coal and gas – NextBigFuture.com

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Natural gas is continuing to dominate energy usage in the United States. Coal provided 60{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of US electrical power 30 years ago and was still providing 50{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} in 2005.

Coal is very competitive in certain parts of the United States, including in the coal hotbeds of Appalachia and the Powder River Basin in Montana and Wyoming.

Natural gas power generation is up 17{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} this year. Natural gas production continues to rise. By itself natural gas is heading to 35{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of US electrical power in 2019. All of the hydro, solar, wind and biomass (ethanol) will be another 15{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974}. Combined they will be over 50{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of US electrical power generation.

Depending on oil and energy prices the US will become a major net exporter of fossil fuels. The US is already exporting coal and some oil and gas. This will become a major amount. As recently as 2005, the US was importing 30{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of its energy. The US is still a net importer of 10{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of its energy. By 2020-2022, the US should pass to become a net exporter. If oil prices are high then natural gas prices would tend to follow as well. High prices would mean supply and production shortages elsewhere and the US could scale up to exporting 20{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of its energy before 2030.

BTU anticipates 56 new or converted natural gas plants to come online by the end of next year.

CO2 emissions better but not as good as hoped

In theory, natural gas can have 50-60{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of the emissions of coal. Fracking releases large amounts of natural gas – which consists of both CO2 and methane – directly into the atmosphere. Fracking wells can leak 40 to 60{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} more methane than conventional natural gas wells.

The Natural gas revolution did reduce overall US emissions from 2000. However, it is not tracking the optimal 50-60{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} of coal CO2 emissions. After declining by 0.9{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} in 2017, EIA forecasts that energy-related carbon dioxide (CO2) emissions will rise by 2.0{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} in 2018. The increase largely reflects higher natural gas consumption because of a colder winter and warmer summer than in 2017. Emissions are forecast to decline by 0.8{0b7da518931e2dc7f5435818fa9adcc81ac764ac1dff918ce2cdfc05099e9974} in 2019. Energy-related CO2 emissions are sensitive to changes in weather, economic growth, energy prices, and fuel mix.

Increased natural gas use is also because natural gas plants back up the intermittent solar and wind power. Solar generating from 10am to 5pm with variation based on clouds. Wind also generating at different times.

Here is the energy breakdown for the USA.

Energy 2017 (TWH) 2018 YTD Last 12 months Natural gas 1273 655 1362 Coal 1208 542 1176 Nuclear 805 403 821 Wind, ethanol and biomass 334 192 350 Hydro 300 162 287 Solar 53 33 60 Other including oil, coke 42 23 45 Overall electricity 4015 2012 4102

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Huge Martian dust storm may be killing NASA’s Opportunity rover

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A global dust storm on Mars is threatening the future of NASA’s Opportunity rover, the longest-lived robot on that planet.

The golf-cart-size vehicle launched toward Mars in June 2003, landed in January 2004, and was supposed to last three months. Today, the rover is 15 years old and has rolled more than a marathon’s worth of miles across the surface of the red planet using solar power.

But Opportunity now seems to be in trouble.

Thanks to the long-lasting global dust storm, which has now raged for nearly two months, Opportunity fell asleep on June 10 and hasn’t phoned home.

Global dust storms appear once every couple of years and shroud the planet in a dull-red haze, but NASA said this is “one of the most intense” ever recorded.

“This is the worst storm Opportunity has ever seen, and we’re doing what we can, crossing our fingers, and hoping for the best,” Steve Squyres, a planetary scientist at Cornell University and leader of the rover mission, told A.J.S. Rayl for a recent Planetary Society blog post.

Why the dust storm is endangering Opportunity

Mars in 2001 as it typically appeared (left) and how the red planet looked after a global dust storm appeared (right).
NASA/JPL-Caltech/MSSS

The Martian weather event has not only blocked light to Opportunity’s solar panels, but also coated them in fine dust. This one-two punch has dramatically lowered the rover’s ability to store and use electrical energy.

Cold is a big issue on Mars, where winter temperatures can drop to -100 degrees Fahrenheit near the equator. Such cold can shrink bits of metal in electronic circuits and snap them.

Little buttons of nuclear material called plutonium-238 help keep Opportunity’s circuitry warm, but the stuff doesn’t last forever and is well-decayed — so it’s not hot enough to fully protect the rover’s systems. This means Opportunity still needs electricity to keep its battery charged, run circuit-warming heaters, and talk to NASA mission control back on Earth.

Draining the batteries too low is also problematic. The longer they’re inactive, the more electrical storage capacity they lose. If the storm doesn’t break soon, and Martian dust devils don’t blow the dust off Opportunity’s solar panels, NASA says there’s a possibility the batteries could “brown out,” or suddenly dip in voltage.

If that happens, or the rover can’t recover a variety of “fault modes,” Opportunity will join the ranks of Spirit — its nearly identical sister rover.

Spirit stopped talking to NASA in March 2010, during a Martian winter. Engineers tried to regain contact with Spirit for more than a year before calling it quits. (Spirit is now presumably another dead robot on the red planet.)

Now for the good news

Simulated images show what NASA’s Opportunity rover saw as a global Martian dust storm blotted out the sun in June 2018.
NASA/JPL-Caltech/TAMU

NASA said in an August 16th press release that “there’s reason to be optimistic,” since the storm appears to be weakening. This could mean enough sunlight may soon hit Opportunity’s solar panels to charge up its batteries and phone home.

The agency also said that the batteries were in “relatively good” working condition before the storm, so “there’s not likely to be too much degradation.” Dust storms also tend to warm up the environment, so that will help buffer against circuit-busting cold.

Opportunity is “not out of the woods” yet, though. A representative at NASA told Business Insider there is “no update” on the rover’s status, which means the agency has yet to hear back.

This is one of the longest periods a solar-powered robot has ever hibernated on Mars to conserve energy. Opportunity has already pushed its engineered lifetime by a decade and a half — and it’s not getting any younger.

“Even if engineers hear back from Opportunity, there’s a real possibility the rover won’t be the same,” NASA said. “No one will know how the rover is doing until it speaks.”

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Solar rebates Archives | Yes Solar Solutions

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Yes Solar Solutions Mission

Yes Solar Solutions is proud to make solar simple, bringing the power of independence to North Carolina homeowners and businesses. Serving Raleigh, Cary, Durham, Greensboro, Morrisville, Chapel Hill, Apex, Holly Springs, Garner, Winston-Salem, High Point, Burlington, Fayetteville and all of North Carolina.

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Blake Cummings, Runoff election – Corporation commission – Democrat – News – The Daily Ardmoreite

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Editor’s note: Candidates for state and national offices on the ballot for the August 28 runoff election were invited to respond to questions for profiles in The Ardmoreite. Those who chose to respond will be featured alongside their ballot opponent. For those that did not participate, basic information will be provided.

Introduction:
I live in Seminole County, near Maud, but was raised at Kinta, in Haskell County. I have a BBA in Petroleum Land Management from OU. I have worked primarily in the oil and gas industry, but also in telecom and government relations. My wife Donna is an RN and my daughter Abby is a nursing student at East Central University.

Why are you running for this office?
I am running because our state government, especially the OCC, no longer answers to the people of Oklahoma, but to a small number of rich and powerful elite, CEOs and billionaires. I want to bring the focus of government on the people who make this state great: The 3.9 million Oklahomans, not the select few.

What do you think are the top three biggest challenges facing our state?
Our three biggest challenges are 1. funding for our future, 2. Education, and 3. Getting back to serving the millions, not the millionaires.

What are your top five priorities to address while in office?
My five priorities are 1. Treat wind and solar energy with equal footing as oil and gas. 2. Rural internet access should expand to all households in the state. 3. 7 percent GPT again and for good this time. 4. Restore our tax rates to the level they were the last time our government paid for itself and necessary services, and 5. Don’t make government work against the masses like it has the last decade.

When faced with a specific situation that puts your personal viewpoint at odds with a great many of your constituents, what decision do you make and why?
If I feel strongly about an issue, I will make my case to the people. If the majority still stands against my position, as their public servant I will support the people’s choice. Public service is not personal service.

What is your position on the gross production tax? What do you think the max GPT should be? What is your stance on GPT for resources other than oil?
A 7 percent GPT was the norm for decades. We must get back to that level ASAP. Because this was the norm, it should never go higher than 7 percent without a vote of the people at large. Seven percent GPT should apply to all energy resources in Oklahoma: oil, gas, wind, solar, and anything else related to energy production.

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Portal:Solar energy – Wikipedia

Solar Energy & Power

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The benefit of thermal mass is shown in this comparison of how heavy and light weight constructions affect internal temperature

In building design, thermal mass is a property of the mass of a building which enables it to store heat, providing “inertia” against temperature fluctuations. It is sometimes known as the thermal flywheel effect. For example, when outside temperatures are fluctuating throughout the day, a large thermal mass within the insulated portion of a house can serve to “flatten out” the daily temperature fluctuations, since the thermal mass will absorb thermal energy when the surroundings are higher in temperature than the mass, and give thermal energy back when the surroundings are cooler, without reaching thermal equilibrium. This is distinct from a material’s insulative value, which reduces a building’s thermal conductivity, allowing it to be heated or cooled relatively separate from the outside, or even just retain the occupants’ thermal energy longer.

Scientifically, thermal mass is equivalent to thermal capacitance or heat capacity, the ability of a body to store thermal energy. It is typically referred to by the symbol C_th and measured in units of J/°C or J/K (which are equivalent). Thermal mass may also be used for bodies of water, machines or machine parts, living things, or any other structure or body in engineering or biology. In those contexts, the term “heat capacity” is typically used instead. Read more…

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IKEA starts installing over 5,000 solar panels on its Alberta store locations

Solar Energy & Power

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IKEA is a Swedish-founded multinational group, that designs and sells ready-to-assemble furniture, kitchen appliances and home accessories. It has been the world’s largest furniture retailer since at least 2008.

Ikea has started on a path to become 100 percent circular and climate-positive in its operations with the start of two solar projects at its locations in Alberta.

Ikea locations in Edmonton and Calgary will be receiving a combined 5,100 solar panels.

The Edmonton location will be taking the lion’s share with 2,905 panels that, once installed, will produce 1,180 megawatts of energy per year.

Calgary will be outfitted with the remaining 2,240 panels, creating 1,000 megawatts per year.

These panels will produce enough electricity to supply 25 percent of the voltage needed for the company’s operations in Alberta.

The addition of the panels to the two locations will offset an approximate 1,622 tonnes of CO2 emissions per year once operational.

More Stories From Around the Web:

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Solar Panel Installer in Adrian, MI at Diverse Staffing

Solar Energy & Power

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Diverse Staffing is now accepting Solar Panel Installer applicants for immediate hire for a long term temporary position. In this job, you will work for our client at a facility in Adrian, MI. This position pays up to $15.00/hr. and is a 1st shift position. Overtime maybe required. This position will start in mid August and continue for 4 to 5 months. Full-time maybe offered to top performer.

Our client provides cost effective renewable energy for agriculture, commercial and residential customers throughout the Midwest. Our client provides full design and installation of solar energy and wind energy systems in Michigan, Illinois, Indiana, Iowa, Kentucky, Minnesota, Missouri, Ohio, Tennessee, and Wisconsin and now in Arkansas. They specialize in agricultural, commercial and rural residential installations. Diverse Staffing has partnered with a great company offering to pay for its star performers to acquire their CDL license.

The following in an example of some of the tasks you may be asked to perform daily working at this position:

•    Install Solar Panels at client’s location the first position will be in Adrian Michigan at three different worksites.
•    Layout Job-sites, operate equipment to bore holes or drive posts, pour concrete, fasten and level racking, mount solar panels using hand tools, run wiring, test output as trained by manager.
•    This is a temporary, full time hourly position, overtime will be paid after 40 working hours per week. This position frequently requires long hours.
•    At Diverse Staffing, our focus is on helping people achieve their career goals through the right career opportunities.

At Diverse Staffing, our focus is on helping people achieve their career goals through the right career opportunities. We truly value our staff. Diverse employees enjoy safe work environments, fair supervision, reliable pay, and even benefits like medical coverage if you need it!

It’s time to join a winning team. Apply today!

For immediate consideration, apply online and contact us for an interview at:

Jackson Recruiting Center

1035 Laurence Ave.

Jackson, MI 49202

Phone (517) 945-0007

OnlineAppJackson@diversestaffing.com

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Navajo Nation solar facility breaks ground on second stage of expansion

Solar Energy & Power

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(Photo from Salt River Project).

PHOENIX — A solar facility in Navajo Nation is expected to double the number of homes it can provide renewable energy to over the next year.

Navajo Nation broke ground on the second phase of an expansion project that will provide a 28-megawatt addition to the Kayenta Solar generation facility in northeastern Arizona.

Under the guidance of the Native American nation, Navajo Tribal Utility Authority and the Salt River Project, the facility is expected to serve 36,000 homes once upgrades are complete in June 2019.

“Extending electricity to homes without has always been our goal as well as our challenge,” said NTUA general manager Walter Haase. “Kayenta II is catalyst in that direction and will help us to improve the
standard of living for many Navajo families.”

In addition, improvements will pave the way to further advancements.

The groups will work toward projects that would provide 500 megawatts of renewable energy over the next five to 10 years, according to the release.

Additionally, the jobs and taxes from the project are expected to bring an economic boost to the nation.

The initial Kayenta project was estimated to have brought $15.6 million in economic activity to the surrounding communities.

It’s also attracting some star power.

Property Brothers co-host Jonathan Scott made an appearance at the ceremony, saying he is interested in seeing the impact of the solar energy on the Navajo people.

Follow @KTAR923

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U.S. Senate Sees Blockchain Changing Energy Sector

Solar Energy & Power

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The United States Senate sees blockchain as a future part of the energy sector. This came as information released by the U.S. Senate Committee on Energy and Natural Resources this month.

Blockchain Technology Has Potential in the Energy Sector

The hearing discussed possible applications of distributed ledger technology (DLT) in the energy sector. The committee considered an increase in electricity prices due to growing demand for blockchain apps. More importantly, was a discussion on how blockchain can improve computing systems.

Arvind Narayanan, an associate professor of computer science at Princeton University, explained:

“A blockchain-based market might be more attractive than a centralized trading platform if market participants are averse to a single company controlling the platform. Other initiatives enable customers to directly trade electricity with each other in a ‘peer to peer’ fashion, for example, by buying and selling excess rooftop solar power.”

According to Narayanan, blockchain technology brings potential benefits to risks currently in energy systems.

Previously, we reported that Wien Energie, an important electric company in Austria, is testing different use cases of DLT. The company was trying different products in a developing project in Vienna. But this is not the only project related to blockchain technology in the energy industry.

A similar announcement was made by the National Energy Commission of Chile (CNE) the institution that regulates the energy sector, as it decided to launch a pilot on the Ethereum blockchain. The intention of this project is to increase security levels of the energy grid. Additionally, it aimed to improve integrity, traceability, and confidence.

There are other governments that are working with blockchain technology. DLT is able to improve services, processes and reduce bureaucracy. Financial institutions are also adopting DLT to make their services and products more efficient.

The future looks brighter every time blockchain is considered as a solution to existing problems in large-scale industries like national energy grids.

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