材料科學的問題，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

Ceramic Masterpieces: Art, Structure and Technology

為了解決材料科學的問題，作者Vandiver, Pamela B./ Kingery, W. David 這樣論述：

Ceramic Masterpieces: Art, Structure andTechnology was first published by the Free Press in 1986. It won a publisher's award for art (American Publishers' Association, Scholarly and Technical, Honorable Mention, 1986). The copyright is held by David Kingery's son, William D. Kingery, Jr., who ab

out 11 years ago signed over to the American Ceramic Society the rights to publish a second edition of the book. This second edition is divided into four parts. In the introductory section, it states: "The appearance of a ceramic is determined by its internal structure, which is in turn determined b

y the technology of its manufacture. Revolutionary new methods of study and analysis have advanced out understanding of ceramics. This book applies these new methods, connecting visual impact, internal structure, and technology for a deeper appreciation of ceramic masterpieces." Each chapter outline

s the transformative art and structure of a ceramic material by providing a general outline of history, artistic value, antecedent technologies, manufacture of the particular dated example, analysis of macrostructure, then microstructure, then composition, then firing, variability and its relation t

o appearance, and finally significance of technology and its contribution to art and culture. In the ceramic technology section, the sequences and variability of processing, exemplified in the case studies, is inventoried with emphasis on structure and transformation.

材料科學進入發燒排行的影片

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

為了解決材料科學的問題，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。

Research Magnet Technology: Forty Years of Creating High Magnetic Fields

為了解決材料科學的問題，作者Jones, Harry (EDT) 這樣論述：

Research Magnet Technology presents an overview of the technologies necessary to provide high magnetic fields as a research tool mainly, but by no means exclusively, for condensed matter physics. Taken from the perspective of the author's career spanning four decades, it contains a historical com

ponent while at the same time deals with state-of-the-art and future developments. Several technologies are described: classical electrical engineering (copper/water-cooled multi-megawatt), superconducting magnets (both low and high temperature), hybrid magnets, non-destructive pulsed magnets, and d

estructive non-continuous techniques for ultra-high fields. The world's dedicated magnet laboratories are described parallel to the involvement of the industry. Examples of major scientific advances that have used high fields will be explored and future applications indicated. Moreover, the many dis

tinguished and colorful scientists and engineers who have made an impression on the author over the last 40 years are featured anecdotally where appropriate.Unlike most books on magnet technology and related topics that are either rigorous textbooks with a heavy mathematical content or popular works

which treat the magnet as an interesting curiosity, this book adopts a unique approach by balancing the two extremes.

基於深度學習進行電池性質預測

為了解決材料科學的問題，作者許家維 這樣論述：

鋰離子電池作為常見的儲能設備，廣泛應用於終端設備上且藉由電池管理系統進行監控確保電池老化程度仍可應付工作所需。然而電池在使用初期並無明顯老化特性的反應，因此對於使用過的電池無法很好評估預期壽命以至於材料的浪費或設備的異常(Early failure)。本研究利用時序資料連續性進行資料擴增更同時對神經網路潛空間進行正則化，並透過包含篩選器與預測器的神經網路架構在僅有少量循環的量測數據下，預測電池產品壽命、剩餘使用壽命、充電所需時間、放電時的電壓電量變化曲線等。其中，僅測量一個充放電完整循環的數據，就能提供僅有57週期方均根誤差的產品壽命預測。本研究亦同時引入注意力機制於此框架中達成僅使用若干個

循環的測量資料便可預測整個電池的產品週期放電電量、放電功耗等特性。