John Labram

Oregon State University

H-index: 32

North America-United States

About John Labram

John Labram, With an exceptional h-index of 32 and a recent h-index of 23 (since 2020), a distinguished researcher at Oregon State University, specializes in the field of Device Physics, Thin Film Transistors, Time Resolved Microwave Conductivity, Retinomorphic Sensors.

His recent articles reflect a diverse array of research interests and contributions to the field:

Retinomorphic sensor

Operating principles of zero-bias retinomorphic sensors

Predicting solar cell performance from terahertz and microwave spectroscopy

An organic retinomorphic sensor

Role of blend ratio in bulk heterojunction organic retinomorphic sensors

The effect of substrate curvature on capacitance and transfer characteristics for thin film transistors on the surface of spheres

Role of A‐Site Composition in Charge Transport in Lead Iodide Perovskites

Establishing Self‐Dopant Design Principles from Structure–Function Relationships in Self‐n‐Doped Perylene Diimide Organic Semiconductors

John Labram Information

University	Oregon State University
Position	Assistant Professor
Citations(all)	3150
Citations(since 2020)	1980
Cited By	1811
hIndex(all)	32
hIndex(since 2020)	23
i10Index(all)	48
i10Index(since 2020)	39
Email	Access Email
University Profile Page	Oregon State University
Google Scholar	View Google Scholar Profile

John Labram Skills & Research Interests

Device Physics

Thin Film Transistors

Time Resolved Microwave Conductivity

Retinomorphic Sensors

John Labram

Oregon State University

About John Labram

John Labram Information

John Labram Skills & Research Interests

Top articles of John Labram

Retinomorphic sensor

Operating principles of zero-bias retinomorphic sensors

Predicting solar cell performance from terahertz and microwave spectroscopy

Jens Neu

Michele Failla

Vladimir Dyakonov

Ryuzi Katoh

Min Ji Hong

Maurizio Monti

Shane Ardo

An organic retinomorphic sensor

Role of blend ratio in bulk heterojunction organic retinomorphic sensors

Xueqiao Zhang

The effect of substrate curvature on capacitance and transfer characteristics for thin film transistors on the surface of spheres

Role of A‐Site Composition in Charge Transport in Lead Iodide Perovskites

Min Ji Hong

Establishing Self‐Dopant Design Principles from Structure–Function Relationships in Self‐n‐Doped Perylene Diimide Organic Semiconductors

Daniel Powell

Xueqiao Zhang

Layered Hybrid Lead Iodide Perovskites with Short Interlayer Distances

Alice Li

Min Ji Hong

Yang Liu

Clayton J Dahlman

Ram Seshadri

Long-range charge carrier mobility in metal halide perovskite thin-films and single crystals via transient photo-conductivity

Yen-Hung Lin

Min Ji Hong

Bernard Wenger

Henry J Snaith

Quantifying the performance of perovskite retinomorphic sensors

Inter‐Sample and Intra‐Sample Variability in Electronic Properties of Methylammonium Lead Iodide

Min Ji Hong

A perovskite retinomorphic sensor

Time-resolved changes in dielectric constant of metal halide perovskites under illumination

Min Ji Hong

Liangdong Zhu

Cheng Chen

Longteng Tang

Yen-Hung Lin

Wen Li

Rose Johnson

Henry J Snaith

Chong Fang

Long-range exciton diffusion in molecular non-fullerene acceptors

Yuliar Firdaus

Safakath Karuthedath

Wentao Huang

Masrur Morshed Nahid

Yuanbao Lin

Akmaral Seitkhan

Aniruddha Basu

Weimin Zhang

Iain Mcculloch

Harald Ade

John Labram

Role of the Blend Ratio in Polymer: Fullerene Phototransistors

Min Ji Hong

A piperidinium salt stabilizes efficient metal-halide perovskite solar cells

Yen-Hung Lin

Jiaying Wu

Alexandra J Ramadan

Junliang Liu

Sai Bai

Feng Gao

Bernard Wenger

Henry J Snaith

Impact of moisture on mobility in methylammonium lead iodide and formamidinium lead iodide

Min Ji Hong

Light soaking in metal halide perovskites studied via steady-state microwave conductivity

Yen-Hung Lin

Wen Li

Rafik Addou

Min Ji Hong