| 1. |
磯 暁, 鈴木 博, トンネル効果と摩擦, 数理科学, Vol.352, No.10, 1992.10. |
| 2. |
H MURAYAMA, H SUZUKI, T YANAGIDA, J YOKOYAMA, CHAOTIC INFLATION AND BARYOGENESIS IN SUPERGRAVITY, PHYSICAL REVIEW D, Vol.50, No.4, pp.R2356-R2360, 1994.08, We propose a Kahler potential in supergravity which successfully accommodates chaotic inflation. This model can have a large gravitino mass without giving a large mass to squarks and sleptons, and thus is free from both the gravitino problem and entropy crisis. In this model baryogenesis takes places naturally, identifying the inflaton with a right-handed sneutrino with its mass M congruent-to 10(13) GeV, which is consistent with the COBE data and the Mikheyev-Smirnov-Wolfenstein solution to the solar neutrino problem. The model can also accommodate the matter content appropriate for the mixed dark matter scenario.. |
| 3. |
鈴木 博, 福井, 隆, 物性物理学におけるボゾン化法ー量子異常の視点から, 数理科学, Vol.43, No.7, pp.41-47, 2005.07. |
| 4. |
Hiroshi Suzuki, Perturbative spectrum of a Yukawa-Higgs model with Ginsparg-Wilson fermions, 2007.06, A Yukawa-Higgs model with Ginsparg-Wilson (GW) fermions, proposed recently by
Bhattacharya, Martin and Poppitz as a possible lattice formulation of chiral
gauge theories, is studied. A simple argument shows that the gauge boson always
acquires mass by the St"uckelberg (or, in a broad sense, Higgs) mechanism,
regardless of strength of interactions. The gauge symmetry is spontaneously
broken. When the gauge coupling constant is small, the physical spectrum of the
model consists of massless fermions, massive fermions and emph{massive} vector
bosons.. |
| 5. |
鈴木 博, 場の量子論の考え方, 数理科学, Vol.46, No.7, pp.6-11, 2008.07. |
| 6. |
鈴木博, 格子ゲージ理論におけるグラディエントフローの応用, パリティ, Vol.30, No.1, pp.31-33, 2015.01. |
| 7. |
鈴木 博, 新著紹介「今度こそわかるくりこみ理論」, 日本物理会誌, 10.11316/butsuri.71.6_399, Vol.71, No.6, p.399, 2016.06. |
| 8. |
Aya Kasai, Ken-ichi Okumura, Hiroshi Suzuki, A dilaton-pion mass relation, 2016.09, Recently, Golterman and Shamir presented an effective field theory which is
supposed to describe the low-energy physics of the pion and the dilaton in an
$SU(N_c)$ gauge theory with $N_f$ Dirac fermions in the fundamental
representation. By employing this formulation with a slight but important
modification, we derive a relation between the dilaton mass squared~$m_ au^2$,
with and without the fermion mass~$m$, and the pion mass squared~$m_pi^2$ to
the leading order of the chiral logarithm. This is analogous to a similar
relation obtained by Matsuzaki and~Yamawaki on the basis of a somewhat
different low-energy effective field theory. Our relation reads
$m_ au^2=m_ au^2|_{m=0}+KN_fhat{f}_pi^2m_pi^2/(2hat{f}_ au^2)+O(m_pi^4ln
m_pi^2)$ with~$K=9$, where $hat{f}_pi$ and~$hat{f}_ au$ are decay
constants of the pion and the dilaton, respectively. This mass relation differs
from the one derived by Matsuzaki and~Yamawaki on the points that
$K=(3-gamma_m)(1+gamma_m)$, where $gamma_m$ is the mass anomalous dimension,
and the leading chiral logarithm correction is~$O(m_pi^2ln m_pi^2)$.
For~$gamma_msim1$, the value of the decay constant~$hat{f}_ au$ estimated
from our mass relation becomes $sim50%$ larger than $hat{f}_ au$ estimated
from the relation of Matsuzaki and~Yamawaki.. |
| 9. |
鈴木 博, 格子場の理論, 数理科学, Vol.55, No.11, pp.24-25, 2017.11. |
| 10. |
白銀瑞樹, 江尻信司, 石見涼, 金谷和至, 北沢正清, 谷口裕介, 鈴木博, 梅田貴士, 若林直輝, Gradient flowを用いてみる一次相転移点近傍の熱力学量の性質, 日本物理学会講演概要集(CD-ROM), Vol.72, No.2, p.ROMBUNNO.12aS31‐5, 2017.09. |
| 11. |
鈴木博, 格子ゲージ理論におけるエネルギー・運動量テンソルの構成:Gradient flowの方法, 日本物理学会誌, 10.11316/butsuri.73.3_148, Vol.73, No.3, pp.148-153, 2018.03. |
| 12. |
金谷和至, 石見涼, 梅田貴士, 江尻信司, 北沢正清, 鈴木博, 谷口裕介, Gradient flowによる(2+1)‐flavor QCD状態方程式―物理点での試験研究―, 日本物理学会講演概要集(CD-ROM), Vol.73, No.1, p.ROMBUNNO.24pK201‐7, 2018.03. |
| 13. |
鈴木 博, 量子アノマリーと経路積分, 数理科学, Vol.668, No.2, pp.27-35, 2019.02. |
| 14. |
鈴木博, グラディエントフロー―エネルギー運動量テンソルへの応用を中心として―, 原子核研究, Vol.64, No.1, pp.52-64, 2019.09. |
| 15. |
鈴木 博, グラディエントフロー—エネルギー運動量テンソルへの応用を中心として—, 原子核研究, 2019.09. |
| 16. |
鈴木 博, 特集・経路積分を考える-量子力学の姿を探る-「量子アノマリーと経路積分」, 数理科学, 2019.02. |
| 17. |
鈴木 博, 最近の研究から「格子ゲージ理論におけるエネルギー・運動量テンソルの構成:Gradient flow の方法」, 日本物理学会誌 73 巻第 3 号, 2018.03. |
| 18. |
鈴木 博, 特集・発展する場の理論「格子場の理論」, 数理科学, 2017.11. |
| 19. |
鈴木 博, グラディエントフローによる格子ゲージ理論のエネルギー運動量テンソル, 科研費NEWS, 2016.01. |
| 20. |
鈴木 博, 新著紹介「園田英徳:今度こそわかるくりこみ理論」, 日本物理学会誌 71 巻 6 号, 2016.06. |
| 21. |
鈴木 博, 特集:物理科学、この一年 素粒子物理「格子ゲージ理論におけるグラディエントフローの応用」, 月刊パリティ(丸善), 2015.01. |
