Carbon dioxide的問題，透過圖書和論文來找解法和答案更準確安心。 我們找到下列包括價格和評價等資訊懶人包

Negative Emissions Technologies for Climate Change Mitigation

為了解決Carbon dioxide的問題，作者Rackley, Stephen A. 這樣論述：

Negative Emissions Technologies for Climate Change Mitigation provides a comprehensive introduction to the full range of technologies that are being researched, developed and deployed in order to transition from our current energy system, dominated by fossil fuels, to a negative-carbon emissions

system. After an introduction to the challenge of climate change, the technical fundamentals of natural and engineered carbon dioxide removal and storage processes and technologies are described. Each NET is then discussed in detail, including the key elements of the technology, enablers and constra

ints, governance issues, and global potential and cost estimates. This book offers a complete overview of the field, thus enabling the community to gain a full appreciation of NETs without the need to seek out and refer to a multitude of sources.

Carbon dioxide進入發燒排行的影片

利用焙燒暨酸浸法從廢棄LED晶粒中回收鎵金屬資源

為了解決Carbon dioxide的問題，作者吳德懷 這樣論述：

LED是發光二極體(Light Emitting Diode)的簡稱。由於LED燈具有節能、無汞等特性，在照明市場之需求日益增加，LED在許多領域已經取代了傳統光源(白熾燈、螢光燈等)。LED燈之高效率白光照明主要是由LED晶粒中氮化鎵(GaN)半導體所產生。隨著LED市場的擴大，未來將產生大量的LED廢棄物。因此，回收廢棄LED中所含的鎵金屬資源對於資源的可持續利用和環境保護都具有重要意義。本研究以廢棄LED燈珠為對象，利用焙燒與酸浸法從其LED晶粒中回收鎵金屬資源，主要包括三個部分：化學組成分析、氟化鈉焙燒處理與酸溶浸漬等。探討各項實驗因子包括焙燒溫度、焙燒時間、礦鹼比、酸浸漬種類及濃度

、浸漬時間、及浸漬固液比等，對於鎵金屬浸漬率之影響，並與各文獻方法所得到的鎵金屬浸漬效果進行比較。研究結果顯示，LED晶粒中含有鎵5.21 wt.%，氟化鈉焙燒暨酸溶浸漬之最佳條件為焙燒溫度900 ℃、焙燒時間3hr、礦鹼比1:6.95、鹽酸浸漬濃度0.5 M、浸漬溫度25 ℃、浸漬時間10mins、固液比2.86 g/L，鎵金屬浸漬率為98.4%。與各文獻方法相比較，本方法可於相對低溫且常壓下獲得較高之鎵金屬浸漬效果。

Printable Mesoscopic Perovskite Solar Cells

為了解決Carbon dioxide的問題，作者 這樣論述：

Hongwei Han, professor and doctoral supervisor of Wuhan National Laboratory for Optoelectronics, Huazhong University of Science and Technology. He has published more than 150 papers in journals such as Science, Adv Mater, Nature Comms, JACS, etc. One of his papers has been cited more than 2,200 time

s. Hosted many international and domestic academic conferences. He presided over the National Natural Science Foundation of China integrated projects, key projects, 863 projects and other projects. In 2016, he was awarded the Changjiang Scholar Distinguished Professor, and in 2017, he was awarded th

e leading talent in science and technology innovation of the National Ten Thousand Talents Program. Michael Grätzel, professor of Ecole Polytechnique Federale de Lausanne, created the field of molecular photovoltaics, being the first to conceive and realize mesoscopic photo-systems based on molecul

ar light harvesters that by now can rival and even exceed the performance of conventional solar cells. Furthermore, he played a pivotal role in the recent development of perovskite solar cells (PSCs) that directly emerged from the DSC. Their meteoric rise to reach a solar to electric power conversio

n efficiency of over 25 % in 2019 has attracted wide research interest with over 10,000 papers being published on the subject over the last 7 years. Graetzel is also a leader in the field of fuel generation by sunlight, which is a key technology to provide future renewable energy sources that can be

stored. His group uses tandems of two photosystems to split water into hydrogen and oxygen and reduce carbon dioxide by visible light. His 1645 publications have received some 284,000 citations and his h-index is 243. Anyi Mei got his PHD in Huazhong University of Science and Technology in 2018. A

fter that, he continues his research in the university and becomes an associate professor in Wuhan National Laboratory for Optoelectronics in Huazhong University of Science and Technology. His research focuses on printed mesoscopic solar cell materials and devices. He has published more than 60 peer

-reviewed articles with H-index 27. Dr. Yue Hu is currently associate professor of Huazhong University of Science and Technology. Dr. Hu has carried out a series of pioneering work in the fields of dye-sensitized solar cells and perovskite solar cells. From the perspectives of molecular design, mat

erial synthesis, interface modification, device optimization and mechanism analysis, Dr. Hu Yue has developed a series of new low-cost light absorbing materials focusing on the photoelectric conversion efficiency, stability and cost of mesoscopic solar cells. She has participated in many scientific

research projects of the Royal Society of chemistry and the National Natural Science Foundation of China. She has published more than 80 research articles in international journals including Science, Advanced Materials, and Advanced Energy Materials etc. with H-index 25.

鉍改質二氧化鈦奈米管陣列電極應用於脫鹽及能量儲存之雙功能電池

為了解決Carbon dioxide的問題，作者胡進煇 這樣論述：

隨著人口增加、劇烈的氣候變化和環境的污染，水資源匱乏以及能源危機問題將會在未來幾十年內持續下去。由於海洋的水資源無限，海水淡化自然成為了解決淡水短缺的解答。海水淡化可以使高濃度的海水轉化成淡水，藉以增加淡水的量，且不受氣候的影響。主要研究是發展低耗能、低成本以及多樣化的淡化技術。鉍除了可以做為氯氣的儲存電極，也發現可以應用於可充電之脫鹽電池，另外鉍和氯氧化鉍皆不可溶於寬廣的pH值以及電位範圍的鹽水溶液，因此在海水中能夠重複使用。本研究以陽極處理得之的二氧化鈦奈米管作為模板，透過無電鍍法將鉍沉積於二氧化鈦奈米管作為氯化物儲存電極。氯離子以氯氧化鉍形式儲存在鉍奈米管陣列中。為探討氯化及脫氯行為，

以實驗半電池反應對鉍奈米管陣列電極進行線性掃描伏安法 (LSV) 和循環伏安法 (CV)。以及探討由不同電壓20V、30V以及40V二氧化鈦奈米管模板製備下，鉍奈米管陣列的差別。