800 件ヒット (0.031秒):
Google Classroomのクラスコードは工学部Webページにて確認すること。
学部シラバス・時間割(https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html)
Chemical and Biomolecular Engineering II refers to any technological applications of chemical and biological systems, such as biomolecules and environmental materials to make or modify products or green processes for specific purposes. This class focuses on biomaterials, biomedical engineering, membrane transport, protein engineering, environmentally benign materials and reactions, biomass conversion, fluid dynamics, green process and industrial processes. Students will learn some basic aspects of engineering for biotechnology, biological and environmental materials.
The class code for Google Classroom can be found on the Web site of
the School of Engineering:
https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html (JP Only)
Chemical and Biomolecular Engineering II refers to any technological applications of chemical and biological systems, such as biomolecules and environmental materials to make or modify products or green processes for specific purposes. This class focuses on biomaterials, biomedical engineering, membrane transport, protein engineering, environmentally benign materials and reactions, biomass conversion, fluid dynamics, green process and industrial processes. Students will learn some basic aspects of engineering for biotechnology, biological and environmental materials.
Google Classroomのクラスコードは工学研究科Webページ
https://www.eng.tohoku.ac.jp/edu/syllabus-g.html
(大学院シラバス・時間割・履修登録)にて確認すること。
生物工学および関連分野の中でも,生命現象の基礎的解明とその応用について,広範で,かつ深い専門知識を講義すると共に,現時点における問題点の発掘とそれに対応する新しい問題解決法を考究し,博士課程学生の問題発見・設定能力の涵養に主眼を置く.物質生産系としてのタンパク質合成システムの応用なども具体的な考究の対象とする.
The class code for Google Classroom can be found on the Web site of the School of Engineering:
https://www.eng.tohoku.ac.jp/english/academics/doctoral.html (under "Timetable & Course Description")
(Advanced Biomolecular Engineering)This lecture will deal with a wide range of research topics concerning basic and advanced aspects of life sciences and their applications. This lecture will also discuss bimolecular engineering issues that remain to be solved and consider how to address these issues scientifically. Such issues, for example, include application of protein synthesis systems for the production of useful compounds.
酵素系,微生物系,植物系,および動物細胞系システムにより有用物質の合成を達成するバイオテクノロジーの基盤技術として,遺伝子工学技術やタンパク質工学技術などについて学ぶ。
This class subject deals with a variety of genetic and protein engineering approaches, which serve as a basis of biotechnology for the production of useful compounds using enzymatic, microbial, plant and animal cell systems.
生物工学および関連分野の中でも生体機能化学に関与する基礎から応用について、広範で、かつ深い専門知識を講義すると共に、現時点における問題点の発掘とそれに対応する新しい問題解決法を考究し、博士課程学生の問題発見・設定能力の涵養に主眼をおく。生体のもつ酵素や遺伝子の機能の応用なども具体的な考究の対象とする。
Lectures on extensive and deep applied biochemistry and biotechnology in bioengineering and related fields are given. Discovering current problems and exploring new problem-solving methods are discussed to train student’s problem-finding and setting abilities. Application of the functions of enzymes and genes in living organisms is also discussed.
生物工学及び関連分野の中でも、生命現象の有機化学的解明とその応用について、広範でかつ深い専門知識を講義するとともに、現時点における問題点の発掘とそれに対応する新しい問題解決法を考究し、博士課程の学生の問題発見・設定能力の涵養に主眼をおく。新しい生物活性物質の創製のための設計・合成法なども具体的考究の対象とする。
In bioengineering and related fields, lectures will be given on a wide range of specialized knowledge about the organic chemical elucidation of life phenomena and their applications. In addition, the main focus is on cultivating the ability of doctoral course students to find and set up problems by discovering current problems and investigating new problem-solving methods to deal with them. Design and synthesis methods for the creation of new biologically active substances will also be the subject of specific research.
Google Classroomのクラスコードは工学研究科Webページ
https://www.eng.tohoku.ac.jp/edu/syllabus-g.html
(大学院シラバス・時間割・履修登録)にて確認すること。
環境に調和した有機合成化学を実現するためには,有害な物質の生成や使用を削減もしくは除去するような化学物質や製造プロセスの創出,設計,応用が求められる。本講義の前半では,光学異性体の合成を例として,分子認識化学と不斉触媒の設計の基礎,環境負荷の低減を目指した代替試剤や反応場の利用などについて概説する。また,後半では,機能性ホスト分子の設計を軸として,環境負荷低減を目指した有機分子捕集材料や金属イオン分離材料の開発について概説する。
The class code for Google Classroom can be found on the Web site of the School of Engineering:
https://www.eng.tohoku.ac.jp/english/academics/master.html (under "Timetable & Course Description")
In order to realize environmentally-benign synthetic organic chemistry, it is necessary to create, design, and/or apply chemical substances, as well as production processes, which can reduce the formation or utilization of harmful materials or remove them. In the first half of this course, you will learn the basics of molecular recognition chemistry and the design of catalysts, and utilization of alternative reagents or reaction fields intended to reduce environmental loading, taking syntheses of enantiopure compounds as examples. In the second half, you will learn examples for the development of capturing and separation materials for organic molecules and metal ions based on the design of functional host molecules.
生物工学および関連分野の中でも、酵素機能の解明とその人工的再現と応用について、広範で、かつ深い専門知識を講義すると共に、現時点における問題点の発掘とそれに対応する新しい問題解決方法を考究し、博士課程学生の問題発見・設定能力の涵養に主眼をおく。生体分子を工学的に応用する際に必要な酵素機能の開拓とそれによる超精密分子認識、生体機能材料やバイオセンサーの開発なども具体的な考究の対象とする。
In biomolecular engineering and related fields, extensive and deep expertise will be given for understanding of the enzyme function and their artificial reproduction and application. Students are required to find out problems at the present stage and consider new methods to solve them, by which problem-finding and task-setting abilities of doctoral students will be developed. Improvement of enzyme functions for biomolecular engineering, development of biofunctional materials, and biosensors for molecular recognition of biomolecules are also the subject of this class.
Google Classroomのクラスコードは工学部Webページにて確認すること。
学部シラバス・時間割(https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html)
The class code for Google Classroom can be found on the Web site of
the School of Engineering:
https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html (JP Only)
Purpose/Abstract
We are surrounded by a large number of chemical products manufactured with various types of materials including organic, inorganic and their composite materials. Even in our body, biological materials are constantly being produced with the help of specialized enzymes and biochemical reactions. The objective of the present course is to provide
chemistry-oriented topics concerned with the development of functional materials in various areas of engineering.
Goal
Students will learn some basic aspects of chemical production, with special emphasis on environmentally friendly methodologies for the synthesis of fine chemicals and advanced materials.
Contents
This course is offered in the Spring semester with the goal of understanding chemical and biomolecular engineering. Various topics will be presented by different instructors, as listed in the course schedule below, with each instructor giving two lectures for each topic.
化学プロセスを構成する反応操作と分離精製操作について、プロセス工学的な立場から広範でかつ深い専門知識を講義すると共に、資源および環境保全を考慮した化学プロセスの設計方法を考察し、問題発見と設定の能力を錬磨する。合理的な反応プロセスの開発のための反応操作と分離操作のシステム化、最適化を含めたプロセス設計学を具体的な講義の対象とする。
The course provides broad and deep expertise from a process engineering standpoint on the reaction and separation/purification operations that constitute chemical processes, and examines methods of designing chemical processes in consideration of resource and environmental conservation. Process design including systemization and optimization of reaction and separation operations for the development of rational reaction processes will be the subject of specific lectures. The course will focus on process design, including systemization and optimization of reaction and separation operations for the development of rational reaction processes.
Google Classroomのクラスコードは工学部Webページにて確認すること。
学部シラバス・時間割(https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html)
1.目的
化学工学に関連する講義で得られた知識をもとに、化学装置とプロセスの設計・運転に必要な事項を習得する。
2.概要
流動・伝熱・移動現象・相平衡・反応工学・プロセス制御・プロセス設計と、蒸留・熱交換・抽出・吸着・吸収・反応・乾燥・分離・撹拌について具体的な例を用いて基礎的な演習を行う。
3.達成目標等
この演習では、主に以下のような能力を習得することを目標とする。
・化学工学の基礎的なモデル化手法を理解し、モデル化と定量的な解析ができる。
・各種の化学装置とプロセスについて理解し、それぞれの基礎的な設計ができる。
The class code for Google Classroom can be found on the Web site of
the School of Engineering:
https://www.eng.tohoku.ac.jp/edu/syllabus-ug.html (JP Only)
1. Objective
Students learn topics required for design and operation of chemical equipment and processes based on the knowledge obtained from the lectures related to chemical engineering.
2. Outline
Students do fundamental practices for fluid flow, heat transfer, transport phenomena, phase change, reaction engineering, and process control and design as well as distillation, heat exchanger, extraction, absorption, reaction, drying, separation and stirring by using the specific examples.
3. Goal
The goal of this practice is to mainly acquire the following skills:
- To understand the fundamental modeling methodology of chemical engineering and to perform modeling and quantitative analysis.
- To understand the various chemical equipment and processes and to do their basic design.