演題:自然とつながるデライトフルな建築へ
Delightful Architecture that connects with Nature
日時:2022年6月29日(水)10:40~12:10
会場:オンライン(Zoom)による開催
講師:川島 範久(明治大学 講師)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:下記URLより事前登録を行ってください。
https://zoom.us/webinar/register/WN_2y9xXuhKR5avkrIU73MVOA
ご登録後、ウェビナー参加に関する確認メールが届きます。
主催:早稲田大学 創造理工学部 建築学科
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
演題:ダイズおよびイネの生育を促進する土壌微生物の単離解析と利用
日時:2022年6月10日(金)16:00~17:30
会場:オンライン(Zoom)による開催
講師:大津 直子(東京農工大学農学研究院 生物生産科学部門 教授)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法: 事前申込先:[email protected]
「お名前」「所属」「メールアドレス」「講演会参加の目的」を明記下さい。
早稲田大学の学生の場合は、学籍番号もご記入ください。
申し込みいただいた方に、zoomアドレスをお送りします。
主催:早稲田大学 先進理工学部 生命医科学科
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
演題:Research and Design -Focusing on “Baby Rooms”-
日時:2022年5月11日(水)10:40~12:10
会場:オンライン(Zoom)による開催
講師:仲 綾子(東洋大学ライフデザイン学部人間環境デザイン学科 教授)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:時間になりましたら下記URLよりご入室下さい。
https://zoom.us/j/99452664180?pwd=SXNGeURVa09TSHJTT0lzRUxBWXlEQT09
主催:早稲田大学 創造理工学部 建築学科
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
社会文化領域コース進入説明会を、2022年6月2日 (木) にオンラインで開催します。
関心のある学生は、以下のポスターおよび社会文化領域のホームページ上の情報をよく確認し、必要な手続きをとってください。
Figure 1 Three-color image of HD1, the most distant galaxy candidate to date, created using data from the VISTA telescope. The red object in the center of the zoom-in image is HD1. (Credit: Harikane et al.)
An international astronomer team has discovered the most distant galaxy candidate to date, named HD1, which is about 13.5 billion light-years away. This discovery implies that bright systems like HD1 existed as early as 300 million years after the Big Bang. This galaxy candidate is one of the targets of the James Webb Space Telescope launched late last year. If observations with the James Webb Space Telescope confirm its exact distance, HD1 will be the most distant galaxy ever recorded.
To understand how and when galaxies formed in the early Universe, astronomers look for distant galaxies. Because of the finite speed of light, it takes time for the light from distant objects to reach Earth. If an object is 1 billion light-years away, it means that the light left that object 1 billion years ago and had to travel for 1 billion years to reach us. Thus studying distant galaxies lets us look back in time.
The current record holder for the most distant galaxy is GN-z11, a galaxy 13.4 billion light-years away discovered by the Hubble Space Telescope. However, this distance is about the limit of Hubble’s detection capabilities.
HD1, a candidate object for the earliest/most-distant galaxy at 13.5 billion light-years away, was discovered from more than 1,200 hours of observation data taken by the Subaru Telescope, VISTA Telescope, UK Infrared Telescope, and Spitzer Space Telescope. “It was very hard work to find HD1 out of more than 700,000 objects,” says Yuichi Harikane, an assistant professor of ICRR, the University of Tokyo, who discovered HD1. “HD1’s red color matched the expected characteristics of a galaxy 13.5 billion light-years away surprisingly well, giving me a little bit of goosebumps when I found it.”
The team conducted follow-up observations using the Atacama Large Millimeter/submillimeter Array (ALMA) to confirm HD1’s distance. Akio Inoue, a professor at Waseda University, who led the ALMA observations, says, “We found a weak signal at the frequency where an oxygen emission line was expected. The significance of the signal is 99.99%. If this signal is real, this is evidence that HD1 exists 13.5 billion light-years away, but we cannot be sure without a significance of 99.9999% or more.”
HD1 is very bright, suggesting that bright objects already existed in the Universe only 300 million years after the Big Bang. HD1 is difficult to explain with current theoretical models of galaxy formation. Observational information on HD1 is limited and its physical properties remain a mystery. It is thought to be a very active star-forming galaxy, but it might be an active black hole. Either possibility makes it a very interesting object. In recognition of its astronomical importance, HD1 was selected as a target for the cycle 1 observations by the James Webb Space Telescope, launched last year. Yuichi Harikane, who is leading these observations, says, “If the spectroscopic observation confirms its exact distance, HD1 will be the most distant galaxy ever recorded, 100 million light-years further away than GN-z11. We are looking forward to seeing the Universe with the James Webb Space Telescope.”
This research will be published in the April 8, 2022 issue of The Astrophysical Journal as Yuichi Harikane, et al. “A Search for H-Dropout Lyman Break Galaxies at z~12-16”. This work was supported by the Japanese Ministry of Education, Culture, Sports, Science and Technology (MEXT), the Japan Society for the Promotion of Science (17H06130, 19J01222, 20K22358, 21K13953), and the NAOJ ALMA Scientific Research Grant (2020-16B).
Figure 2 Earliest galaxy candidates and the history of the Universe.
(Credit: Harikane et al., NASA, ESA, and P. Oesch (Yale University))
Journal: The Astrophysical Journal
Title: “A Search for H-Dropout Lyman Break Galaxies at z~12-16”
Authors: Yuichi Harikane, Akio K. Inoue, Ken Mawatari, Takuya Hashimoto, Satoshi, Yamanaka, Yoshinobu Fudamoto, Hiroshi Matsuo, Yoichi Tamura, Pratika Dayal, L. Y. Aaron Yung, Anne Hutter, Fabio Pacucci, Yuma Sugahara, and Anton M. Koekemoer
DOI:10.3847/1538-4357/ac53a9
URL:https://iopscience.iop.org/article/10.3847/1538-4357/ac53a9
https://ui.adsabs.harvard.edu/abs/2021arXiv211209141H/abstract
演題:細菌とファージの攻防
日時:2022年4月16日(土) 9:30 – 11:00
会場:オンライン(Zoom)による開催
講師:大塚 裕一(埼玉大学 理学部 分子生物学科・准教授)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:参加希望者は[email protected] (常田)まで連絡してください。
参加のためのZOOM情報をご連絡します。
主催:早稲田大学 先進理工学研究科 生命医科学専攻
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
演題:高分子から原子の世界へ ー原子を混ぜてみようー
日時:2022年3月28日(月) 10:00 – 11:30
会場:西早稲田キャンパス 55N号館 1階 第二会議室
講師:山元 公寿(東京工業大学 教授)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:入場無料、直接会場へお越しください。
主催:早稲田大学 先進理工学研究科 応用化学専攻
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
演題:100年企業におけるデジタルトランスフォーメーションの挑戦
日時:2022年3月19日(土)13:15-14:45
会場:ZOOMによるオンライン講演会
講師:黒川 博史(ライオン株式会社DX推進部長)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:参加ご希望の方はメールにて前々日までに [email protected] まで連絡してください。
参加のためのZoom 情報をご連絡します。なお、メールのタイトルは「3/19イベント申し込み」としてください。
主催:先進理工部 化学・生命化学科
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
4/1に学生証を配布します(感染拡大防止のため、配付時間を分割しております。)。学生証の受け取りは本人に限り、郵送はいたしかねます。学部生は「受験票」、大学院生は「公的身分証明書(運転免許証、パスポート、在留カード)」を必ず持参のうえ、指定の場所・時間帯にお受け取りください。また、開始直後は混みあいますので、滞留が生じないよう分散しての来場にご協力ください。
※定期券は、学生証受け取り後、購入可能です。届出住所の変更を要する場合は、MyWasedaを経由しての届出が承認された後、裏面シールの再発行が必要です(Support Anywhere「各種申請・変更手続き」)。
※急な体調不良などによる欠席の連絡は不要です。やむを得ない事情により受け取れなかった場合に限り、4/4以降、西早稲田キャンパス51号館1階理工学統合事務所教学支援課カウンターにてお渡しします(4/2-3は、受け取れません)。学部生は「受験票」、大学院生は「公的身分証明書(運転免許証、パスポート、在留カード)」を持参のうえ、事務取扱時間内にお受け取りください。
※共同大学院の他大学(東京女子医科大学・東京農工大学・東京都市大学)本属学生の方は、早稲田大学学生証およびWaseda IDを専攻の指示にしたがってお受け取りください。
演題:原子力エネルギー利用と安全研究の最前線
日時:2022年3月14日(月)13:00~17:30
会場:西早稲田キャンパス 63 号館 2 階 02 教室
オンライン(Zoom)のハイブリッド同時開催
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:参加無料、事前申込制
事前申込先:【申込期限:2022 年 3 月 7 日】
以下の Google フォームより参加申し込みください。
https://forms.gle/Fajbq7SapsBY2nfX6
現在、新規参加お申込みはオンライン参加に限定させて頂いております。
主催:先進理工学研究科 共同原子力専攻
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
*English version follows Japanese
3/18に配布します。感染拡大防止のため時間を分割しますので、指定の時間帯および教室でお受け取りください。開始直後は混みあいますので、滞留が生じないよう分散して来場するようご配慮ください。
※共同大学院他大学(東京女子医科大学・東京農工大学・東京都市大学)本属学生の方は、専攻の指示に従ってお受け取りください。
※急な体調不良などによる欠席の連絡は不要です。3/18に来られない場合は、4/2の同時間帯・会場で実施する2回目にお受け取りください(3/19~4/1の期間はお渡しできません)。2回とも参加できない場合は、4/4以降、51号館1階教学支援課カウンターにてお受け取りください(郵送はいたしかねます)。
※学生証をまだ受け取っていない方は、教学支援課カウンターで学生証を受け取ってから、裏面シールをお受け取りください(学生証の郵送はいたしかねます)。
※住所変更が生じている方は、以下の手順でご対応ください。
(1)MyWasedaから住所変更を申請(Support Anywhere「各種申請・変更手続き」)
(2)学生証裏面シールを受け取り
(3)51号館1階教学支援課カウンターにて裏面シールを交換
New backside sticker for your student ID will be distributed on March 18, within the period designated for each group/major. Below schedule is arranged for the infection prevention, thus your cooperation to be at your designated period would be highly appreciated.
*It is not necessary to inform us of absences due to sudden illness or other reasons. In case March 18 is not convenient for you, please pick it up on April 2. The venue and the time frame for each group/major remain the same as March 18. (You cannot receive new backside sticker from March 19 to April 1.) If you are unable to attend both sessions, please pick up it after April 4 at “Academic and Student Affairs Section at the Center for Science and Engineering” at the grand floor of the Bldg. 51, Nishi-Waseda Campus (ONLY receive it at counter, no postal service).
*If you have not received your student ID card yet, please pick up it before each session (the list below) at “Academic and Student Affairs Section at the Center for Science and Engineering” at the grand floor of the Bldg. 51, Nishi-Waseda Campus (ONLY receive it at counter, no postal service).
*If you have changed your address, please follow the steps below:
(1) Request a change of address via MyWaseda.
(2) Receive your new backside sticker.
(3) Exchange the sticker at “Academic and Student Affairs Section at the Center for Science and Engineering” at the grand floor of the Bldg. 51, Nishi-Waseda Campus.
12:00-14:00 Math/CSCE Major
14:00-16:00 ME Major
10:00-12:00 CE Major
14:00-16:00 Phys/Chem/Bio Major
10:00-12:00 School of Fundamental Science and Engineering
12:00-14:00 School of Creative Science and Engineering
14:00-16:00 School of Advanced Science and Engineering
10:00-12:00 School of Fundamental Science and Engineering
12:00-14:00 School of Creative Science and Engineering
14:00-16:00 School of Advanced Science and Engineering
10:00-12:00 Graduate School of Fundamental Science and Engineering
12:00-14:00 Graduate School of Creative Science and Engineering
14:00-16:00 Graduate School of Advanced Science and Engineering (*Please follow the instruction from the department if there is any.)
演題:ウイルス性肝炎とその基礎開発研究
日時:2022年3月14日(木)月16:30-18:00
会場:Zoomによるオンライン講演会
講師:村松 正道(国立感染症研究所 ウイルス第二部 部長)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:参加無料、事前申込制
事前申込先:[email protected]
「お名前」「所属」「メールアドレス」「講演会参加の目的」を明記下さい。
早稲田大学の学生の場合は、学籍番号もご記入ください。
申し込みいただいた方に、zoomアドレスをお送りします。
主催:先進理工学部 生命医科学科
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
演題:Part of speech knowledge of Japanese EFL learners
日時:2022年2月28日(月)13:30-14:30
会場:Zoomによるオンライン講演会
講師:石井 友子(明治学院大学 准教授)
対象:学部生、大学院生、教職員、学外者、一般の方
参加方法:参加無料、事前申込制
事前申込先:Https://forms.office.com/r/HVyFfNzHjD
申込締切:2022年2月27日(日) 17:00
主催:英語教育センター
問合せ:早稲田大学 英語教育センター
ラルフ・ローズ
演題:何が見えるか?何をするか?~ある有機化学者の自由な発想
日時:2022年3月3日(木)16:30-17:30
会場:早稲田大学 西早稲田キャンパス 55号館1階大会議室
講師:佐竹 彰治(東京理科大学 教授)
対象:学部生・大学院生、教職員、学外者、一般の方
参加方法:入場無料、直接会場へお越しください。
主催:先進理工学研究科 応用化学専攻
問合せ:早稲田大学 理工センター 総務課
TEL:03-5286-3000
Electrolysis of water into hydrogen and oxygen is a potential source of clean hydrogen fuel. However, the process requires efficient electrocatalysts. Unfortunately, conventional techniques often overestimate their efficiency. Now, researchers from Japan demonstrate an alternative technique for gauging the electrocatalytic performance accurately, opening doors to a smooth transition from lab-scale studies to large-scale hydrogen fuel generation and commercialization of new catalysts with no activity loss issues from overestimation of activity with transient voltammetry techniques.
Electrolysis of water or “water electrosplitting” has received a great deal of attention recently owing to its potential as a clean source of hydrogen, the oft-touted fuel of the future. However, two issues have long stood in the way: the large amount of energy lost, and the cost of electrocatalysts (catalysts used for electrolysis). Fortunately, several new kinds of electrocatalysts have made their appearance, which could potentially solve these issues.
The screening of new electrocatalysts is conventionally performed with techniques such as “linear sweep voltammetry” (LSV) and “cyclic voltammetry” (CV), which involve applying a constantly changing voltage to an electrode and monitoring the resulting current. As this current depends on the rate of oxidation or reduction occurring at the electrode, the measured current readings can be used to determine the effect of an electrocatalyst on the speed of the electrolysis reaction.
However, an obvious drawback of these techniques is that they cannot accurately record the “steady-state” response of the electrocatalyst as it does not experience a particular applied voltage long enough to do so. As a result, substantially high current readings are often recorded, which do not reflect the true catalytic activity, hindering the development of efficient electrocatalysts and promotion of the same to large-scale processes.
In a new study published in the Journal of The Electrochemical Society, Assistant Professor Sengeni Anantharaj from Waseda University, Japan, along with his collaborators Dr. Subrata Kundu from CSIR-Central Electrochemical Research Institute, India, and Prof. Suguru Noda from Waseda University have now found a way around this problem, demonstrating an alternate technique called “sampled current voltammetry” (SCV) as a more reliable indicator of electrocatalytic performance at a constant steady-state applied voltage.
“Screening catalysts accurately is just as important as developing new catalysts for all energy conversion reactions,” says Anantharaj, speaking of his motivation. “Our work has highlighted a way to make accurate measurements of electrocatalytic activity previously not possible with conventional transient techniques.”
Before applying the SCV technique, the researchers analyzed the errors resulting from LSV. To show the deviation in current values, they used a steady-state technique called “chronoamperometry” (CA), which is the most accurate method of all yet time consuming to measure current at constant voltages and compared it to the values obtained from LSV.
To determine the activity of electrocatalysts used in electrolysis, they measured the current readings of both the oxygen-producing and hydrogen-producing half-cell reactions. Using a stainless-steel (SS) electrode, precipitated Co(OH)2 (cobalt hydroxide), and platinum foil as catalysts in a KOH (potassium hydroxide) solution, the researchers found that the current density readings from LSV and CA differed significantly, with the difference growing wider at higher applied voltages.
Using the same setup, they then applied the SCV technique and recorded the current densities at various fixed voltages obtained from the steady-state CA responses. “To validate the suitability of SCV, we recorded the CA responses of the SS electrode at various regularly increasing voltages for 130 seconds, within which the SS interface was able to reach a steady state,” elaborates Anantharaj.
From the sampled current readings, the researchers found negligible difference compared to the steady-state CA technique, demonstrating the reliability of the SCV in correctly determining electrocatalyst’s behavior at different voltages. Additionally, while the SCV is particularly useful in the search for a suitable electrocatalyst for water electrosplitting, it can be used to screen electrocatalysts accurately for any electrochemical reaction.
“By addressing the long-standing problem of catalyst performance loss when promoted from the lab to the practical processes, our work could speed up the worldwide adoption of large-scale hydrogen generation from electrolysis,” comments Anantharaj.
It certainly appears we’re now one step closer to the wide adaptation of hydrogen-powered future!
Authors: Sengeni Anantharaj1,2, Subrata Kundu3 and Suguru Noda1,2
Title of original paper: Worrisome Exaggeration of Activity of Electrocatalysts Destined for Steady-State Water Electrolysis by Polarization Curves from Transient Techniques
Journal: Journal of The Electrochemical Society
DOI: 10.1149/1945-7111/ac47ec
Latest Article Publication Date: 5 January 2022
Affiliations:
1Department of Applied Chemistry, School of Advanced Science and Engineering, Waseda University
2Waseda Research Institute for Science and Engineering, Waseda University
3Electrochemical Process Engineering (ECE) Division, CSIR-Central Electrochemical Research Institute (CECRI), India
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