![Research Image](/sites/default/files/inline-images/MIP_91_0.png)
Simplified (and superior!) Synthesis of Nickelate Superconductors (MIP #91)
![Research Image](/sites/default/files/inline-images/MIP_87a_0.png)
Hump in Hall Measurements Insufficient as Evidence for Skyrmions (MIP #87)
![Research Image](/sites/default/files/inline-images/Screenshot%202023-08-06%20at%209.44.12%20PM.png)
Expanding the Capabilities of Lab-Based ARPES on Quantum Materials (MIP #79)
![Research Image](/sites/default/files/inline-images/MIP_74_0.png)
Gate-tunable heavy fermions in a moiré Kondo lattice (MIP #74)
![Research Image](/sites/default/files/inline-images/Screen%20Shot%202023-02-24%20at%2010.55.52%20AM.png)
The Electronic Phase Diagram of Moiré Superlattices (MIP #68)
![Research Image](/sites/default/files/inline-images/MIP_66_0.jpg)
From Machine Learning to Discovery of New Family Member (MIP #66)
![Research Image](/sites/default/files/inline-images/MIP_65_0.png)
Lorentz Ptychography for high-resolution, high sensitivity magnetic imaging (MIP #65)
![Research Image](/sites/default/files/inline-images/MIP_62_thumb.jpg)
Engineering Quantum Fabrics with Arbitrary Periodicities (MIP #62)
![Research Image](/sites/default/files/inline-images/60_img.jpg)
Metallicity of Ultrathin SrIrO3/SrRuO3 Heterostructures (MIP #60)
![Research Image](/sites/default/files/inline-images/58_thumb.jpg)
Robotic Assembly of Quantum Fabrics from Atomically Thin Layers (MIP #58)
![Research Image](/sites/default/files/inline-images/Screen%20Shot%202021-11-22%20at%201.23.06%20PM.png)
Cleaning up a Quantum Material: from Quantum Enigma to Quantum Oscillations (MIP #48)
![Research Image](/sites/default/files/inline-images/Screen%20Shot%202021-11-22%20at%2012.52.23%20PM_0.png)
Quantification of Interfacial Electron-Phonon Coupling from Photoemission Replica Bands in a High-Tc Superconductor (MIP #46)
![Research Image](/sites/default/files/inline-images/MIP_45_thumb.jpg)
Cryo-STEM Unveils Electronic Order at the Atomic Scale (MIP #45)
![Research Image](/sites/default/files/inline-images/thumbnail_43_0.png)
Discovery of “Pseudogap” Behavior in a Monolayer Thick High-Temperature Superconductor (MIP #43)
![Research Image](/sites/default/files/inline-images/MIP_42_THUMBNAIL.png)
The Highest Resolution Microscope, enabled by a new detector technology, reaches an ultimate resolution limit – the vibrations of atoms themselves (MIP #42)
![Research Image](/sites/default/files/inline-images/%2337_thumb.jpg)
When Seemingly Passive Substrates are Active (MIP #37)
![Materials By Design](/sites/default/files/inline-images/thumb%2336.jpg)
“Band-Structure Engineering” of Quantum Materials to Create a new Superconductor (MIP #36)
![Crystal Structure and Bulk Crystal](/sites/default/files/inline-images/Picture_MIP%2334_thumb.jpg)
Discovery and Single Crystal Growth of High Entropy Pyrochlores (MIP #34)
![Research Image comparing theory to experimental data](/sites/default/files/inline-images/thumb%2333.jpg)
Atomic-Scale Visualizations of Low-Temperature Phase Transitions (MIP #33)
![EMPAD Sample schematic](/sites/default/files/inline-images/Highlight%2027_1.png)
When it Comes to Seeing Atoms, Blurrier is Better (MIP #27)
![Micrograph at 158K](/sites/default/files/inline-images/Screen%20Shot%202020-07-15%20at%204.25.04%20PM.png)
New Sample Holder for High-Resolution Electron Microscopy at Previously Inaccessible Temperatures (MIP #24)
![Pyrochlore Ice Spin Diagram](/sites/default/files/inline-images/pyrochlore_icespin_0.png)
A Strategy to Make and Manipulate Magnetic Monopoles by Exploiting Interfaces (MIP #23)
![RuCl3 Heterolayer diagram](/sites/default/files/inline-images/Picture1-2_0.png)
New theoretical approach to tackle interface quantum materials (MIP #22)
![Machine Learning](/sites/default/files/inline-images/segmentation_0_0_1.png)
PARADIM machine learning model for assisted optical floating zone synthesis(MIP#21)
![Electron micrographs and illustrations of remote epitaxy](/sites/default/files/inline-images/MIP_20_0.png)
Freeing wafer-scale stacking of single crystals from the shackles of epitaxial constraints (MIP# 20)
![Research Work flow](/sites/default/files/inline-images/Screen%20Shot%202020-02-24%20at%2010.05.02%20AM_0.png)
Theory+MBE+ARPES to navigate correlated materials A new Modality of Materials Discovery (MIP #16)
![Electron Microscopy Images with illustration of RuO3 layer](/sites/default/files/inline-images/MIP_Highlight_12_0.jpg)
An atomically thin ferromagnet—just one atom thick (MIP #12)
![Fluid Pressure Stabilization](/sites/default/files/inline-images/MIP_Highlight_11_b_0.jpg)
Pushing boundaries: High pressure, supercritical optical floating zone materials discovery (MIP #11)
![MIP Highlight 10](/sites/default/files/inline-images/MIP_Highlight_10_1.jpg)
Superconducting Sr2RuO4 Films— key step toward ground-state quantum computing (MIP #10)
![MIP Highlight 8](/sites/default/files/inline-images/MIP_Highlight_8_1.jpg)
High-Resolution Electron Microscopy gets Cooler Sub-Angstrom Imaging at Cryogenic Temperatures (MIP #8)
![MIP Highlight 6](/sites/default/files/inline-images/MIP_Highlight_6_1.jpg)
New Detector for Electron Microscopy enables analysis of 2D Materials at record resolution (MIP #6)
![MIP Highlight 5](/sites/default/files/inline-images/MIP_Highlight_5_1.jpg)
Stretching Valleytronic Materials far beyond Conventional Limits to Tune their Properties (MIP #5)
![MIP Highlight 4](/sites/default/files/inline-images/Screen%20Shot%202020-02-28%20at%202.29.18%20PM_3.png)
Valleytronics Made to Order: Layer-by-Layer Stacking of TMD Sheets with ~cm Dimensions(MIP #4)
![MIP Highlight 3](/sites/default/files/inline-images/MIP_Highlight_3_0.jpg)
Perturbing Valleytronic Materials to make them Relevant to Ground-State Quantum Computing (MIP #3)