Here is a daily log for Haihao Liu from 2016.6.5 to 2016.8.7 in Saito Lab in Tohoku Univ.
Daily schedule (tentative)†
- 09:00-10:00 Finishing/continuing any work from previous day
- 10:00-12:00 Discussion with Shoufie-san
- 12:00-13:00 Lunch
- 13:00-14:30 Discussion with Shoufie-san
- 14:30-15:00 Prepare daily report presentation
- 15:00-15:30 Meeting with Saito-sensei
- 15:30-17:30 Continuing work/updating Pukiwiki
Goal of the project†
- To enhance electric field at graphene surface by changing the possible patterns of dielectric thin layers through deep learning algorithms.
- Keywords: graphene, transfer matrix, deep learning
Schedule for discussion†
10:00-12:00
13:00-14:30
- Please note that: All appointment should be done by communicating each other on what kind of subjects will you teach.
- If Haihao-san asks you what he needs, please answer it with CC to Saito.
- If you do not have any materials to be taught, please give him an easy question to solve.
- If Haihao-san could not answer this question, it means that your question is bad (needs some knowledge).
- If Haihao-san can answer within 2 mins, it means that you gave improper question (the answer is too trivial).
Questions and Answers†
This section is for posting questions from Haihao-san and answers from other group members.
- Please list here with some simple reasons or details.
- For every problem, give a tag double asterisks (**) in the code so that it will appear in the table of contents.
- For the answer, give a tag triple asterisks (***) in the code below the problem in order to make a proper alignment.
- List from new to old.
Q: (Placeholder)†
A: (Placeholder)†
Report†
This part is basically written by Haihao-san. Any other people can add this. Here the information should be from new to old so that we do not need to scroll.
June 6†
- Nugraha-sensei helped me set up lab server access, mail client, etc.
- Bento lunch from Espace Ouvert restaurant (next to 7-11 on bottom floor of new building), ate with Saito-sensei who played his ukulele.
- Learned how to derive boundary conditions for EM wave passing from one dielectric media to another, using Maxwell's equations (Faraday's and Ampere's).
- Solved for reflection and transmission probabilities at boundary for normal incident wave.
To do:
- Test SHH from dorm room
- Read pages on reflection and transmission of EM waves at boundary, and derive probabilities for both TE and TM both of oblique incident waves.