研究生: |
郭品纖 Kuo, Pin-Hsien |
---|---|
論文名稱: |
中學生閱讀科學圖文與不同語意透明度之學術詞彙的認知處理策略──眼動追蹤研究 The Processing Strategies for Illustrated Science Reading and Chinese Academic Words with Different Semantic Transparency among Seventh-Grade Students: An Eye-Tracking Study |
指導教授: |
簡郁芩
Jian, Yu-Cin |
口試委員: |
曾玉村
Tzeng, Yuh-Tsuen 邱國力 Chiou, Guo-Li |
口試日期: | 2021/06/23 |
學位類別: |
碩士 Master |
系所名稱: |
教育心理與輔導學系 Department of Educational Psychology and Counseling |
論文出版年: | 2021 |
畢業學年度: | 109 |
語文別: | 中文 |
論文頁數: | 88 |
中文關鍵詞: | 閱讀能力 、學術詞彙 、科學圖文 、眼動追蹤 、閱讀策略 |
英文關鍵詞: | reading ability, academic words, illustrated science text, eye tracking, reading strategy |
研究方法: | 實驗設計法 |
DOI URL: | http://doi.org/10.6345/NTNU202100695 |
論文種類: | 學術論文 |
相關次數: | 點閱:153 下載:23 |
分享至: |
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科學文章是典型的多元表徵文本(有文字與圖表),且具有概念密度高的學
術詞彙,因此學生在閱讀文章時常有理解困難。本研究藉由眼動追蹤的方式探討
不同閱讀能力的中學生閱讀科學圖文的認知歷程與處理策略,以及遇到語意透明
度高(意譯)與低(音譯)之學術詞彙時,讀者如何處理。本研究有效樣本為 65
名七年級生,藉由前測進行閱讀能力分組,閱讀四篇科學圖文(含有意譯與音譯
的科學學術詞彙各兩篇)後回答自由回憶和閱讀理解題,最後進行提示回溯性放
聲思考(Cued Retrospective Think Aloud, CRTA)。研究結果發現,讀者閱讀含有
意譯與音譯的文本整體的閱讀理解測驗差異並不大,不過閱讀能力與整體閱讀理
解和自由回憶表現呈現顯著正相關。但從眼動指標來看,在學術詞彙的處理層
次,各能力的中學生於閱讀音譯的科學詞彙時,第一次連續凝視時間(gaze
duration)都較意譯學術詞彙長,反映中學生難以從詞素意義理解科學詞彙含意,
因此需要比較長的時間解碼語意透明度低的科學詞彙,而後轉移眼動位置到科學
詞彙附近的句子,藉由上下文推測詞義;而在文章處理的層次,不論閱讀能力高
中低,中學生皆以文字為訊息理解之主要來源,讀文字的總凝視時間比例較讀圖
片的比例高,但學生們清楚表格類插圖的資訊量高且為統整後的資訊,因此相較
於於其他類型的圖片,學生會花較多時間讀統整比較表。提示回溯性放聲思考的
資料則顯示高能力學生多運用推論與整合層次的閱讀策略(如運用插圖訊息、整
合圖文訊息),得以正確辨識圖類型與其資訊量以隨時調整適當的閱讀策略;中
能力學生常使用提取訊息的策略(如找重點、重讀);低能力學生則常會用負向
閱讀處理方式(如重點認知錯誤、不清楚閱讀目的),而難以在閱讀科普文章時
進行有效的學習理解。建議於實務現場中,應考量學生之能力差異,並輔以教學
協助學生找到最適合的閱讀策略。
Science texts are typical texts with multiple representations (with texts and diagrams), containing academic words with high conceptual density. Therefore, students often face difficulty understanding science texts. This study uses eye tracking to explore the cognitive process and strategies of seventh-grade students with different reading abilities in reading illustrated scientific texts, and how readers deal with academic words with high (paraphrase) and low (transliteration) semantic transparency. Seventh-grade students (N=65) were divided into groups of reading ability through a pre-test. After reading four science texts (two with academic words of paraphrase and two with academic words of transliteration), they answered free recall and reading comprehension questions, and finally participated in cued retrospective think aloud (CRTA).
The results show that the reading-comprehension for texts containing academic words (paraphrase and transliteration) is not different. However, reading ability is significantly positively correlated with reading comprehension and free-recall performance. When reading transliterated words, students of all abilities have a longer gaze duration than when reading paraphrasing words, indicating the difficulty in understanding the meaning of academic words from morphemes. Therefore, it takes a relatively long time to decode academic words with low semantic transparency and subsequently use the reading strategy of inferring the meaning of the word from the context to understand the academic words. Furthermore, regardless of the reading ability, students use the text part as the main source of reading comprehension; the proportion of total fixation duration for reading text is higher than reading diagrams. However, the students realize that the form illustration has a high amount of integrated information. Therefore, compared with other types of diagrams, students spent more time reading the form illustration.
The eye movement retrospective think aloud data shows that high-ability students often use inference and integrated reading strategies (such as use of illustrated information, integrated texts, and diagrams) to correctly identify the type of picture and the amount of information to adjust the appropriate reading strategy at any time. Middle-ability students often use information extraction strategies (such as finding key points, rereading); low-ability students often use negative reading processing methods (such as misunderstanding key points, unclear reading purpose), and it is difficult to learn and understand effectively when reading popular science texts.
It is recommended that the differences in students’ reading ability should be considered, and teaching should be supplemented to help students find the most suitable reading strategy.
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