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研究生: 吳美瑩
論文名稱: 粒子發展史融入自然與生活科技教學對國中學生學習成就及科學本質觀影響之研究
指導教授: 方泰山
Fang, Tai-Shan
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2004
畢業學年度: 93
語文別: 中文
論文頁數: 119
中文關鍵詞: 粒子發展史科學史教學模式學習成就科學本質迷思概念
英文關鍵詞: the history of particles, science history, teaching model, learning achievement, the nature of science, misconceptions
論文種類: 學術論文
相關次數: 點閱:139下載:64
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  • 本研究採準實驗研究法,旨在運用粒子發展史融入自然與生活科技教學,探討科學史融入教學模式對學生學習成就及科學本質觀的影響。研究者採用歷史個案研究方式設計教材,並採行分組討論式的合作學習方法設計教學模式,以台北市某國中二年級145名學生為實驗對象,分為實驗組(71人)及控制組(74人),進行十堂課的教學實驗。本研究除藉學習成就測驗、了解科學本質量表(UNOS)前後測成績,探討粒子發展史融入教學模式對學生學習成就及對科學本質了解的影響外,並分析不同性別、不同程度學生在學習成就及對科學本質了解上的差異,以及從學生的活動學習單內容及學習感受問卷回饋意見進行質與量的分析。研究結果發現如下:
    一、粒子發展史融入教學模式能促進學生之學習成就。
    就性別而言,實驗組女生學習成就的後測表現沒有顯著優於男生;就程度而言,實驗組高分組及中分組的學習成就後測表現顯著高於低分組,也就是科學史融入教學模式對高分組及中分組的影響顯著高於低分組。
    二、粒子發展史融入教學模式未能促進學生對科學本質的了解。
    就性別而言,實驗組女生了解科學本質的後測表現沒有顯著優於男生;就程度而言,實驗組高分組、中分組和低分組的了解科學本質後測表現沒有顯著差異,也就是科學史融入教學均未能促進各組學生對科學本質了解的提升。
    三、大部分學生認為粒子發展史融入教學模式對他們有幫助。
    1. 學生對實驗教學之感受:一是分組討論改變學習型態;二是上課方式變的新鮮、特別;三是科學史教學模式讓教材更易了解。學生對實驗教材之感受:一是科學史教材內容深入、觀念較易理解;二是科學史教材有重點整理;三是科學史教材內容活潑;四是科學史教材重視科學概念發展過程。
    2. 有63﹪的學生宣稱實驗教學引起他們的學習興趣。實驗教學引起學習興趣的理由:一是喜歡分組討論;二是科學史教材內容生動;三是教學有助思考。
    3. 有 94﹪的學生宣稱實驗教學幫助他們了解科學本質。科學史融入教學模式促進學生在科學知識本質的了解最多,科學方法與科學事業本質的了解很少。
    4. 有82﹪的學生宣稱實驗教學改善他們的迷思概念。
    5. 實驗教學對於學生的最大幫助:一是提高學習成就;二是增進反省思考;三是了解科學史。
    四、學生的迷思概念與科學史上的科學概念相比較,發現學生在粒子相關的某些概念和古代科學家的想法相似。

    This research adopts quasi-experimental research method. It aims to integrate the history of particles to the teaching of Science and Technology to investigate the impact of the integrated teaching model of the science history on the students’ learning achievement and their view of the nature of science. The researcher used historical case-study approach to design the teaching materials and adopted group discussion of cooperative learning method as the teaching model. The subjects were 145 8th graders in a junior high school in Taipei, 71 in the experiment group and 74 in the control group. The students in the experiment group received ten classes of teaching experiment. This research not only used pre- and post-test scores of learning achievement test and Understanding of the Nature of Science Scale (UNOS) investigate the impact of the integrated teaching model on the students’ learning achievement and their view of the nature of science but also analyzed the difference between different sexes and levels of students. It also underwent quality and quantity analysis on students’ worksheets and feedback questionnaire. The findings are as followed.
    I.The integrated teaching model of the history of particles can facilitate students’ learning achievement.
    As far as sexes are concerned, the girls’ learning achievement on posttest is not significantly higher than that of the boys’ in experiment group. As to different student levels, the learning achievements on posttest of the high-score and medium-score groups are significantly higher than that of the low-score group; that is, the impact of the integrated teaching model of science history on the high-score and medium-score groups are significantly higher that of the low-score group.
    II.The integrated teaching model of the history of particles cannot increase students’ understanding of the nature of science.
    As far as sexes are concerned, the girls’ understanding of the nature of science on posttest is not significantly higher than that of the boys’ in experiment group. As to different student levels, the understanding of the nature of science on posttest for the high-score and medium-score groups are not significantly different from that of the low-score group; that is, the impact of the integrated teaching model of science history cannot significantly facilitate the understanding of the nature of science of all groups of students.
    III.Most students thought that the integrated teaching model of the history of particles was helpful for them.
    1.The feelings students have toward experiment teaching: a) group discussion changed students’ learning style; b) classes became interesting and special; c) the new teaching model made the materials easier to understand.
    The feelings students have toward experiment materials: a) the materials on science history are in-depth and easier to understand; b) there were a list of main points on science history; c) the materials on science history are snappy; d) the science history materials emphasized the development of scientific concepts.
    2.63% of students declared that experiment teaching arouse their learning interests. The reasons are: a) students like group discussion; b) the materials on science history are lively; c) the teaching helped students to think.
    3.94% of students declared that experiment teaching helped them understand the nature of science. The integrated teaching model of science history facilitated students’ understanding of the nature of scientific knowledge much better than that of scientific method and scientific enterprise.
    4.82% of students declared that experiment teaching helped them improve their misconceptions.
    5.The greatest help the experiment teaching has toward students are: a) enhance learning achievement; b) increase reflection; c) understand science history.
    IV.Comparing students’ misconceptions and the scientific concepts in the science history, students’ concepts concerning particles are similar to some thoughts of ancient scientists.

    第一章 緒論 1 第一節 研究背景與動機 1 第二節 研究目的與問題 3 第三節 研究假設 4 第四節 名詞解釋 5 第五節 研究範圍與限制 8 第二章 文獻探討 10 第一節 科學史在科學教學所扮演的角色 10 第二節 科學史與迷思概念改變 15 第三節 科學史與了解科學本質 19 第四節 科學史教材 23 第五節 學生粒子迷思概念探討 28 第三章 研究方法與設計 33 第一節 研究架構與實驗設計 33 第二節 研究樣本 34 第三節 研究工具 35 第四節 教材與教學設計 39 第五節 研究程序 45 第六節 資料處理 47 第四章 研究結果及討論 48 第一節 科學史融入教學對學生學習成就之影響 48 第二節 科學史融入教學對學生了解科學本質之影響 53 第三節 學生學習感受回饋意見之分析 59 第四節 學生迷思概念之分析 77 第五節 討論 82 第五章 結論與建議 89 第一節 結論 89 第二節 建議 93 參考文獻 94 壹、中文部分 94 貳、英文部分 97 附錄 100 附錄一 學習成就測驗 100 附錄二 了解科學本質量表 104 附錄三 單元活動學習單(一) 106 附錄三 單元活動學習單(二) 108 附錄四 學習感受問卷 109 附錄五 進入原子的世界(一) 110 附錄六 進入原子的世界(二) 115 圖目次 圖3-1-1 研究架構與實驗設計圖 33 圖3-4-1 教學活動實施流程 44 圖3-5-1 實施程序 46 表目次 表2-4-1 建構與行為主義的比較 15 表3-2-1 實驗組與控制組學生人數統計表 34 表3-3-1 學習成就測驗內容的雙向細目表 35 表3-3-2 「了解科學本質量表(UNOS)」分量表概述 36 表3-4-1 粒子相關概念的教學目標 39 表3-5-1 實驗組與控制組教學活動實施流程比較 45 表4-1-1 實驗組和控制組前後測分數的平均數和標準差 48 表4-1-2 實驗組和控制組前測分數差異顯著性考驗 48 表4-1-3 實驗組和控制組後測分數差異顯著性考驗 49 表4-1-4 實驗組和控制組進步分數(後測減前測)差異顯著性考驗 49 表4-1-5 段考成績變項分組標準與人數分析表 50 表4-1-6 實驗組性別分組前後測分數的平均數和標準差 50 表4-1-7 實驗組性別分組前測分數差異顯著性考驗 50 表4-1-8 實驗組性別分組後測分數差異顯著性考驗 50 表4-1-9 實驗組性別分組進步分數差異顯著性考驗 51 表4-1-10 實驗組學生程度分組前後測分數的平均數和標準差 51 表4-1-11 實驗組學生程度分組前測分數差異顯著性考驗 51 表4-1-12 實驗組學生程度分組後測分數共變數分析 52 表4-1-13 實驗組學生程度分組調整後之後測分數 52 表4-1-14 實驗組學生程度分組後測分數共變數分析事後比較 52 表4-2-1 實驗組和控制組前測及各分量表分數差異顯著性考驗 53 表4-2-2 實驗組和控制組後測及各分量表分數差異顯著性考驗 54 表4-2-3 實驗組和控制組進步分數差異顯著性考驗 54 表4-2-4 實驗組性別分組前後測量表總分的平均數和標準差 55 表4-2-5 實驗組性別分組前測及各分量表分數差異顯著性考驗 55 表4-2-6 實驗組性別分組後測及各分量表分數差異顯著性考驗 55 表4-2-7 實驗組學生程度分組前後測量表總分的平均數和標準差 56 表4-2-8 實驗組學生程度分組前測及各分量表分數的平均數和標準差 56 表4-2-9 實驗組學生程度分組前測及各分量表分數差異顯著性考驗 56 表4-2-10 實驗組學生程度分組後測及各分量表分數共變數分析 57 表4-2-11 實驗組學生程度分組後測科學事業分量表分數差異顯著性考驗 57 表4-2-12 實驗組學生程度分組調整後之後測量表總分及各分量表分數 58 表4-3-1 實驗教學是否引起學習興趣統計表 63 表4-3-2 實驗教學是否幫助了解科學本質統計表 67 表4-3-3 實驗教學是否改善迷思概念統計表 70 表4-4-1 學生在物質組成的迷思概念(以出現次數統計) 77 表4-4-2 學生在分子及原子的迷思概念(以出現次數統計) 78 表4-4-3 學生在分子定義的迷思概念(以出現次數統計) 79 表4-4-4 學生在原子結構模型的迷思概念(以出現次數統計) 79 表4-4-5 學生在原子體積與質量的迷思概念(以出現次數統計) 80 表4-4-6 學生在質子、中子及電子的迷思概念(以出現次數統計) 81

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    趙匡華(民87)。化學通史。新竹:凡異出版社。
    鄭秀如(民86)。科學史對學生科學知識本質觀及學習成就之影響。國立高雄師範大學科學教育研究所碩士論文。
    劉宗寅(民92)。影響世界的化學大發現。台北:專業文化出版社。
    劉俊庚(民91)。迷失概念與概念改變教學策略之文獻分析-以概念構圖和後設分析模式探討其意涵與影響。國立台灣師範大學科學教育研究所碩士論文。
    蘭宜申譯(民87)。Leonard De Vries原著。原子科學史。台北:藝文印書館。
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