Quantum, Magnetic, and Ionic Physics

Departemen Fisika, Fakultas Matematika dan Ilmu Pengetahuan Alam Universitas Indonesia

Chairman of the specialization: Dr. Adam Badra Cahaya

The year 2025 has been officially declared by UNESCO as the International Year of Quantum Science and Technology, recognizing the transformative impact of quantum science on modern society and its foundational role in future technologies. In alignment with this global initiative, the Quantum, Magnetic, and Ionic Physics Research Group (QuMI-Phys Group) was established based on Universitas Indonesia Rector’s Regulation No. 6 of 2025 concerning Research Groups/Laboratories at Universitas Indonesia. This initiative aims to optimize research, which serves as a foundational pillar in the development of science and technology.

This research group represents a collaboration of faculty members actively engaged in the field of Condensed Matter and Materials Physics, combining experimental, theoretical, and computational approaches. The group focuses on exploring the rich interplay between quantum phenomena, magnetic interactions, and ionic transport mechanisms in solid-state materials.

Quantum, magnetic, and ionic physics all play crucial roles in solid-state devices, impacting their functionality and design. Quantum mechanics is fundamental for understanding the behavior of electrons and their interactions within materials, while magnetism influences materials’ magnetic properties and their interaction with magnetic fields. Ionic physics, lastly, governs the motion and behavior of ions within materials, particularly in devices like batteries and sensors.

Prospective Students

Are recommended to have good grade in the following compulsory course:

  • Introduction to Solid State Physics (Pendahuluan Fisika Zat Padat)

See optional courses in Kurikulum 2024 for Condensed Matter and Material Physics

  • Introduction to Materials Science (Pendahuluan Ilmu Material)
  • Characterization Methods of Material (Metode Karakterisasi Material)
  • Thermodynamics of Materials (Termodinamika Material)
  • Capita Selecta on Advanced Material (Kapita Selekta Material Maju)
  • Magnetism (Kemagnetan)
  • Spectroscopy A & B (Spektroskopi A & B)
  • Solid State Ionics (Fisika Zat Padat Ionik)
  • Computation of Materials (Komputasi Material)
  • Nonrelativistic Quantum Field Theory (Teori Medan Kuantum Nonrelativistik)

*This recommendation is a general guide. Please contact your academic or research advisor for specific recommendation.

May pursue appropriate programs, based on their background and career options (each program also has “by research path” option focusing on research)

Compulsory courses in by course path of Master Program in Materials Science includes:

  • Structure Material
  • Material Properties and Performance
  • Thermodynamics and Material Kinetics
  • Characterization and Material Analysis

Compulsory courses in by course path of Master Program in Physics, includes:

  • Computational Methods and Mathematics
  • Physics Methodology
  • Integrated Science and Mathematics

Compulsory courses in by course path of Doctoral Program in Material Science includes:

  • Scientific Literacy
  • Advanced Material Structure
  • Philosophy of Science
  • Advanced Material Properties and Performance
  • Integrated Science and Mathematics
  • Advance Material Characterization and Analysis
  • Advanced Thermodynamics and Kinetics of Materials

Compulsory courses in by course path of Doctoral Program in Physics includes:

  • Integrated Science and Mathematics
  • Research Methodology
  • Capita Selecta Physics A & B
  • Philosophy of Science and Literature Review
  • Scientific Writing

 

Sub-Groups

Quantum mechanics explains how electrons move and interact within solid materials, including phenomena like electron transport, band structure, and the formation of quantum wells and dots. Quantum mechanics is essential for designing and understanding quantum devices like quantum dots, which can be used for quantum computing, sensing, and optical applications. Our research interest focuses on developing theoretical explanations of transport, magnetic, and optical properties of strongly correlated electron systems. (Former Fisika Materi Padat Teoritis/Komputasional lab)

Member Of This Specialization

adam

Assoc. Prof. Dr. Adam Badra Cahaya
aziz

Assoc. Prof. M. Aziz Majidi, Ph.D.
Dr.-Seno-Aji-S.Si_.-M.Sc_

Dr. Seno Aji, S.Si., M.Sc.

Understanding magnetism is crucial for designing magnetic materials like ferromagnets, which are used in magnetic storage devices, sensors, and actuators. Quantum magnetism plays a role in understanding the interactions between magnetic moments in materials, which can lead to novel magnetic phenomena and functionalities. (former micromagneticmagnetic materials dan characterization labs)

Member Of This Specialization

DedeDRPMUI

Prof. Dede Djuhana, M.Si., Ph.D.
azwar

Prof. Dr. Azwar Manaf, M.Met.
budi1

Assoc. Prof. Dr. Budhy Kurniawan R., M.Si.

Ionic physics governs the movement of ions through solid electrolytes, including materials such as perovskite oxides and halides, which are essential for energy storage and transduction applications. Understanding ionic conductivity is crucial for designing and optimizing devices like batteries, fuel cells, and ionic sensors.

Member Of This Specialization

djoko

Prof. Dr. tech. Djoko Triyono
Dr.-Nur-Ika-Puji-Ayu-S.T-scaled-1-2048x2000

Dr. Nur Ika Puji Ayu

Research and Publications

Research Grant (Hibah Penelitian)

  • Hibah Direktorat Penelitian dan Pengabdian kepada Masyarakat, Kemenristekdikti
    • D. Triyono, PPS-PTM: Inovasi Substrat Perovskite BFO untuk Deteksi Rhodamine B dengan Teknik SERS yang Sensitif dan non-Timbal
    • D. Triyono, PPS-PTM: Teknik SERS Perovskite Berbasis LaFeO3-Emas: Solusi Ramah Lingkungan untuk Pemantauan Residu Pestisida yang Sensitif dan Stabil
    • D. Triyono, PFR: Inovasi Teknologi Sensor Gas Respon Cepat Berbasis Perovskite untuk Monitoring Emisi CO2
  • Hibah Universitas Indonesia:
    • A.B.Cahaya, PUTI Q1: Kajian Stabilitas Struktur Nano dari Quantum Dot 
    • M.A.Majidi, PUTI Q1: Studi Plasmon Terkorelasi dalam Sistem Cuprates melalui Pemodelan Hubbard pada Sistem Kisi 2D yang Dipecahkan dengan
      Metode Dynamical Mean-Field Theory
    • S. Aji, PUTI Q1: Photo-Induced Magnetic Phase Transitions in Nontrivial Spin Textures 
    • B. Kurniawan, PUTI Q1: Eksplorasi Peran Vacancy pada Ion Ca2+ terhadap Struktur, Sifat Magnetik, dan Magnetocaloric Effect, Senyawa La0.7Ca0.2-xSr0.1MnO3 melalui XRD, MPMS, Difraksi Neutron dan XAS
    • N.I.P.Ayu, PUTI Q1; Hydrides-ion Conductor for the Next Generation Hydrides-ionBattery
    • D. Djuhana, PUTI Q2: Investigasi Nanostruktur, Sifat Magnetik, Simulasi Mikromagnetik dan Performa Penyerapan Radar Nanohibrida MOFe2O3-(CH3CH2)2NH/Grafit/ZnO

Journal Publication

  • R.Takagi, R.Hirakida, Y.Settai, R.Oiwa, H.Takagi, A.Kitaori, K.Yamauchi, H.Inoue, J.Yamaura, D.Nishio-Hamane, S.Itoh, S.Aji, H.Saito, T.Nakajima, T.Nomoto, R.Arita, S.Seki, “Spontaneous Hall effect induced by collinear antiferromagnetic order at room temperature”, Nature Materials 24, 63–68 (2025)
  • M.Khalil, A.G.Juandito, D.Djuhana, B.Priyono, G.T.M. Kadja, M.H.Mahyuddin, F.F.Abdi, “Tunable domain wall pinning behavior by notch geometry in CoFeB nanostrip under nano-pulse current injection”, FlatChem 50, 100843 (2025)
  • C.Kurniawan, R.N., D.-H. Kim, D.Djuhana, “Tunable domain wall pinning behavior by notch geometry in CoFeB nanostrip under nano-pulse current injection”, Kuwait J.Sci. 52, 100418 (2025)