ADMISSIONS
Undergraduate Admissions
ADMISSIONS
Undergraduate Admissions
入學資訊Star RecommendationAdmission ApplicationAdmission Application-Tun Meng-Electrical Information Departmentexam distributionOtherTransfer
Our university has launched a new milestone in cultivating semiconductor talent, laying a foundation by extending its reach to the undergraduate level. We are closely collaborating with the industry to set teaching goals and directions, providing opportunities for internships and student exchange programs abroad. We aim to nurture young, outstanding technological talents for higher education and the industrial chain. Our department is divided into two specialized tracks: “Program of Solid-State Electronics” and “Program of Nano-Sciences.” The core research focus of the “Program of Solid-State Electronics” includes IC processes, component innovation, chip design, and quantum physics. The “Program of Nano-Sciences” emphasizes interdisciplinary learning, offering a choice between two out of four major fields: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences.
114學年招生名額表
| Academic Year 2025-2026 | Star Recommendation | Admission Application | Admission Application-Tun Meng-Electrical Information Department | exam distribution | Total |
|---|---|---|---|---|---|
| Program of Solid-State Electronics | 6 | 26 | 2 | 6 | 40 |
| Program of Nano-Sciences | 3 | 14 | 0 | 3 | 20 |
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 6 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 校系分則下載 |
本校招生資訊 大學甄選資訊 認識本系 |
| Program of Nano-Sciences | 3 | The teaching goal is to cultivate outstanding students with interdisciplinary learning intelligence, without focusing on a single field. Interdisciplinary learning provides an advantage in acquiring information, integrating knowledge from related fields. This track is the transformation of our university’s Nano Bachelor’s Program, which has been running for sixteen years and has successfully nurtured over 300 excellent interdisciplinary talents. Building on the strengths of the Nano Bachelor’s Program, the first and second years involve fundamental mandatory courses in subjects such as mathematics, physics, chemistry, electronics, materials, and programming (including laboratory courses). Starting from the third year, students can choose from dual-core courses based on their personal interests, selecting two major specialized fields from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. This not only provides a broad knowledge base across these four fields but also allows for depth in two specialized fields. What to study is entirely up to the students, with a flexible course selection environment that allows them to explore what they like and are good at. | 校系分則下載 |
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 26 | The core research focuses include IC processing, component innovation, chip design, and quantum physics. | 5/16(五)二階出席調查表單: 出席調查表單填寫5/16二階報到名單: 上午場名單 下午場名單附檔連結 |
本校招生資訊 大學甄選資訊 認識本系 新生入學獎學金 校園平面圖 |
| Program of Nano-Sciences | 14 | Students can select dual-core courses based on their personal interests, choosing two major specialized courses from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. | 5/16(五)二階出席調查表單:出席調查表單填寫
附檔連結 |
| Academic Year 2025-2026 | Admission Quota | Character | Download & Links |
|---|---|---|---|
| Program of Solid-State Electronics | 2 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 附檔連結
本校招生資訊 大學甄選資訊 認識本系 |
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 6 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 附檔連結 |
本校招生資訊 大學分科測驗資訊 認識本系 新生入學獎學金 校園平面圖 |
| Program of Nano-Sciences | 3 | The teaching goal is to cultivate outstanding students with interdisciplinary learning intelligence, without focusing on a single field. Interdisciplinary learning provides an advantage in acquiring information, integrating knowledge from related fields. This track is the transformation of our university’s Nano Bachelor’s Program, which has been running for sixteen years and has successfully nurtured over 300 excellent interdisciplinary talents. Building on the strengths of the Nano Bachelor’s Program, the first and second years involve fundamental mandatory courses in subjects such as mathematics, physics, chemistry, electronics, materials, and programming (including laboratory courses). Starting from the third year, students can choose from dual-core courses based on their personal interests, selecting two major specialized fields from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. This not only provides a broad knowledge base across these four fields but also allows for depth in two specialized fields. What to study is entirely up to the students, with a flexible course selection environment that allows them to explore what they like and are good at. | 附檔連結 |
| Admission Channel | Admission Quota | Links |
|---|---|---|
| Special Selection | 0 | 本校綜合組招生網頁 |
| Sports Performance | 0 | |
| Disabilities | 0 | |
| Four Technical and Two Professional | 0 |
Cross-University Department Transfer under the University System of Taiwan
Our department participates in the Taiwan University System (including National Central University, National Tsing Hua University, National Yang Ming Chiao Tung University, and National Chengchi University) and accepts cross-university department transfer applications.
The groups and quotas available for transfer each year are based on the announcement of the Taiwan University System for that particular year.
校內轉系
本系固態電子組及奈米科學組互轉比照校內轉系辦理申請。
| 114學年 | 名額 | 特色 | 相關網站 |
|---|---|---|---|
| 固態電子組 | 待訂 | 以培養具有全方位半導體知識的優秀學子為教學目標,核心研究主軸包括IC製程、元件創新、晶片設計、量子物理。「IC製程」為一片矽晶圓到封裝在市場可販售商品中,首先需瞭解半導體元件之基礎知識,並學習相關製程,從光罩製作、微影製程、離子佈植、熱擴散或熱處理、化學氣相沉積或物理性鍍膜、乾式與濕式蝕刻,甚至化學機械研磨及元件封裝等製程,讓學生瞭解半導體在現今科技中擔任舉足輕重之角色。「元件創新」從現在當紅的金屬氧化物場效電晶體,一路到最近的量子計算單元,利用最前瞻的物理理論開創史無前例的新元件總能為半導體產業掀起巨大革命。「晶片設計」則依照不同的使用需求設計不同架構的晶片,利用各種邏輯閘為元件建立連結,除了模擬電路元件之間的效率外,系統之間的能量干擾也是考慮的重要議題。「量子物理」則是隨著半導體元件的微縮,巨觀的物理已不再適合用來分析,量子物理成為新興半導體固態理論的重要基石。 | 主辦單位 |
| 奈米科學組 | 待訂 | 以培養具有跨領域學習智能的優秀學子為教學目標,不聚焦於單一領域,跨領域學習提供了訊息優勢,融合學習相關領域知識。本組其前身即為本校運行十六年培育出三百多位優秀跨領域人才之奈米學士班轉型而來。延續奈米學士班優勢,在大一及大二進行基礎專業必修學科,包括數學、物理、化學、電子、材料及程式語言之修習(含實驗課),大三起,依個人興趣進行雙核心課程選讀,就奈米電子、奈米光電、奈米材料及奈米生科四大領域選修兩主專長領域課程,不只有四領域知識廣度,還有雙領域的深度,學什麼完全由學生自己決定,自由修課環境,能好好探索自己喜歡什麼、擅長什麼。 |
入學資訊
Our university has launched a new milestone in cultivating semiconductor talent, laying a foundation by extending its reach to the undergraduate level. We are closely collaborating with the industry to set teaching goals and directions, providing opportunities for internships and student exchange programs abroad. We aim to nurture young, outstanding technological talents for higher education and the industrial chain. Our department is divided into two specialized tracks: “Program of Solid-State Electronics” and “Program of Nano-Sciences.” The core research focus of the “Program of Solid-State Electronics” includes IC processes, component innovation, chip design, and quantum physics. The “Program of Nano-Sciences” emphasizes interdisciplinary learning, offering a choice between two out of four major fields: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences.
114學年招生名額表
| Academic Year 2025-2026 | Star Recommendation | Admission Application | Admission Application-Tun Meng-Electrical Information Department | exam distribution | Total |
|---|---|---|---|---|---|
| Program of Solid-State Electronics | 6 | 26 | 2 | 6 | 40 |
| Program of Nano-Sciences | 3 | 14 | 0 | 3 | 20 |
Star Recommendation
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 6 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 校系分則下載 |
本校招生資訊 大學甄選資訊 認識本系 |
| Program of Nano-Sciences | 3 | The teaching goal is to cultivate outstanding students with interdisciplinary learning intelligence, without focusing on a single field. Interdisciplinary learning provides an advantage in acquiring information, integrating knowledge from related fields. This track is the transformation of our university’s Nano Bachelor’s Program, which has been running for sixteen years and has successfully nurtured over 300 excellent interdisciplinary talents. Building on the strengths of the Nano Bachelor’s Program, the first and second years involve fundamental mandatory courses in subjects such as mathematics, physics, chemistry, electronics, materials, and programming (including laboratory courses). Starting from the third year, students can choose from dual-core courses based on their personal interests, selecting two major specialized fields from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. This not only provides a broad knowledge base across these four fields but also allows for depth in two specialized fields. What to study is entirely up to the students, with a flexible course selection environment that allows them to explore what they like and are good at. | 校系分則下載 |
Admission Application
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 26 | The core research focuses include IC processing, component innovation, chip design, and quantum physics. | 附檔連結
|
本校招生資訊 大學甄選資訊 認識本系 新生入學獎學金 第一志願正取錄取,獲2萬獎學金及iPad Air 乙台 |
| Program of Nano-Sciences | 14 | Students can select dual-core courses based on their personal interests, choosing two major specialized courses from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. | 附檔連結
|
Admission Application-Tun Meng-Electrical Information Department
| Academic Year 2025-2026 | Admission Quota | Character | Download & Links |
|---|---|---|---|
| Program of Solid-State Electronics | 2 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 附檔連結
本校招生資訊 大學甄選資訊 認識本系 |
exam distribution
| Academic Year 2025-2026 | Admission Quota | Character | Download | Links |
|---|---|---|---|---|
| Program of Solid-State Electronics | 7 | The teaching goal is to cultivate outstanding students with comprehensive semiconductor knowledge. The core research focuses include IC processing, component innovation, chip design, and quantum physics. “IC processing” involves transforming a silicon wafer into a marketable packaged product. It starts with understanding the basic knowledge of semiconductor components and learning the related processes, such as photomask creation, photolithography, ion implantation, thermal diffusion or heat treatment, chemical vapor deposition or physical vapor deposition, dry and wet etching, chemical-mechanical polishing, and component packaging. This allows students to understand the crucial role semiconductors play in today’s technology. “Component innovation” ranges from the currently popular metal-oxide-semiconductor field-effect transistors (MOSFETs) to the latest quantum computing units. Utilizing cutting-edge physical theories to create unprecedented new components can bring a huge revolution to the semiconductor industry. “Chip design” involves designing chips with different architectures based on specific usage needs, using various logic gates to establish connections between components. In addition to simulating the efficiency of circuit components, energy interference between systems is also an important issue to consider. “Quantum physics” has become an essential foundation of emerging semiconductor solid-state theory as the miniaturization of semiconductor components makes classical physics unsuitable for analysis. | 附檔連結 |
本校招生資訊 大學甄選資訊 認識本系 新生入學獎學金 第一志願正取錄取,獲2萬獎學金及iPad Air 乙台 |
| Program of Nano-Sciences | 4 | The teaching goal is to cultivate outstanding students with interdisciplinary learning intelligence, without focusing on a single field. Interdisciplinary learning provides an advantage in acquiring information, integrating knowledge from related fields. This track is the transformation of our university’s Nano Bachelor’s Program, which has been running for sixteen years and has successfully nurtured over 300 excellent interdisciplinary talents. Building on the strengths of the Nano Bachelor’s Program, the first and second years involve fundamental mandatory courses in subjects such as mathematics, physics, chemistry, electronics, materials, and programming (including laboratory courses). Starting from the third year, students can choose from dual-core courses based on their personal interests, selecting two major specialized fields from four areas: nanoelectronics, nano-optoelectronics, nanomaterials, and nano-biosciences. This not only provides a broad knowledge base across these four fields but also allows for depth in two specialized fields. What to study is entirely up to the students, with a flexible course selection environment that allows them to explore what they like and are good at. | 附檔連結 |
Other
| Admission Channel | Admission Quota | Links |
|---|---|---|
| Special Selection | 0 | 本校綜合組招生網頁 |
| Sports Performance | 0 | |
| Disabilities | 0 | |
| Four Technical and Two Professional | 0 |
Transfer
Cross-University Department Transfer under the University System of Taiwan
Our department participates in the Taiwan University System (including National Central University, National Tsing Hua University, National Yang Ming Chiao Tung University, and National Chengchi University) and accepts cross-university department transfer applications.
The groups and quotas available for transfer each year are based on the announcement of the Taiwan University System for that particular year.
校內轉系
本系固態電子組及奈米科學組互轉比照校內轉系辦理申請。
| 113學年 | 名額 | 特色 | 相關網站 |
|---|---|---|---|
| 固態電子組 | 待訂 | 以培養具有全方位半導體知識的優秀學子為教學目標,核心研究主軸包括IC製程、元件創新、晶片設計、量子物理。「IC製程」為一片矽晶圓到封裝在市場可販售商品中,首先需瞭解半導體元件之基礎知識,並學習相關製程,從光罩製作、微影製程、離子佈植、熱擴散或熱處理、化學氣相沉積或物理性鍍膜、乾式與濕式蝕刻,甚至化學機械研磨及元件封裝等製程,讓學生瞭解半導體在現今科技中擔任舉足輕重之角色。「元件創新」從現在當紅的金屬氧化物場效電晶體,一路到最近的量子計算單元,利用最前瞻的物理理論開創史無前例的新元件總能為半導體產業掀起巨大革命。「晶片設計」則依照不同的使用需求設計不同架構的晶片,利用各種邏輯閘為元件建立連結,除了模擬電路元件之間的效率外,系統之間的能量干擾也是考慮的重要議題。「量子物理」則是隨著半導體元件的微縮,巨觀的物理已不再適合用來分析,量子物理成為新興半導體固態理論的重要基石。 | 主辦單位 |
| 奈米科學組 | 待訂 | 以培養具有跨領域學習智能的優秀學子為教學目標,不聚焦於單一領域,跨領域學習提供了訊息優勢,融合學習相關領域知識。本組其前身即為本校運行十六年培育出三百多位優秀跨領域人才之奈米學士班轉型而來。延續奈米學士班優勢,在大一及大二進行基礎專業必修學科,包括數學、物理、化學、電子、材料及程式語言之修習(含實驗課),大三起,依個人興趣進行雙核心課程選讀,就奈米電子、奈米光電、奈米材料及奈米生科四大領域選修兩主專長領域課程,不只有四領域知識廣度,還有雙領域的深度,學什麼完全由學生自己決定,自由修課環境,能好好探索自己喜歡什麼、擅長什麼。 |
