2019 Swanson School Summary of Faculty Research

Page 47

CHEMICAL & PETROLEUM ENGINEERING

J. Karl Johnson, PhD

904 Benedum Hall | 3700 O’Hara Street | Pittsburgh, PA 15261

William Kepler Whiteford Professor Associate Director, Center for Research Computing

P: 412-624-5644  C: 412-680-1783 karlj@pitt.edu http://www.engineering.pitt.edu/KarlJohnson/

Molecular Modeling: A Tool for Development of New Materials The Johnson research group uses computer simulation tools to discover, characterize, and optimize new materials from the bottom-up, starting at the levels of electrons, atoms, and molecules. Application areas studied by the Johnson group include designing new membrane materials for desalination of seawater,

as shown in Figure 1, design of nanoporous materials for gas separation, CO2 capture, and conversion of CO2 to useful products, as illustrated in Figure 2, and elucidation of reaction mechanisms on surfaces and in condensed phases.

Figure 1. Molecular simulation (left) and experimental realization of a functionalized carbon nanotube membrane for desalination of seawater. Simulations first predicted that zwitterion functionalized nanotubes could be effective for desalination by imparting gatekeeper functionality to the nanotubes. The experiments verified the predictions, showing that a polyamide/carbon nanotube mixed matrix membrane has both higher flux and higher selectivity compared with plain polyamide membranes.

Molecular modeling can be used to screen a range of materials for a given application, thereby saving time and money by identifying a relatively small collection of promising candidate materials that can be investigated experimentally. For example, we have employed this strategy for screening of complex metal hydrides for hydrogen storage using a set of criteria including gravimetric, volumetric, and thermodynamic metrics. We were able to screen millions of compositions and conditions in order to identify a small subset of a few promising candidate materials that had not previously been identified. Several of these materials were investigated experimentally and some were found to outperform existing complex hydrides in many respects. This basic approach can also be applied to designing tailored sorbent and membrane materials based on metal organic framework or similar materials. We also use the techniques of molecular modeling to study complex systems involving chemical reactions on surfaces and in condensed phases. For large-scale systems this demands a hybrid approach employing both quantum mechanical modeling, to account for bond breaking and bond forming events, and classical modeling to capture long-range interactions and physical collective phenomena that are difficult to describe from a purely quantum mechanical approach.

DEPARTMENT OF CHEMICAL AND PETROLEUM ENGINEERING

Figure 2. Porous metal organic framework, UiO-66, functionalized with a Lewis pair catalytic site for chemical reduction of CO2 to formic acid. This functional group was designed from first-principles simulations.

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Wei Xiong, PhD, D.Eng

37min
pages 127-146

Jörg M.K. Wiezorek, PhD

2min
page 126

Guofeng Wang, PhD

2min
page 125

Jeffrey Vipperman, PhD

2min
page 124

Albert C. To, PhD

1min
page 123

Inanc Senocak, PhD

1min
page 121

Patrick Smolinski, PhD

1min
page 122

Jung-Kun Lee, PhD

3min
page 117

Ian Nettleship, PhD

2min
page 119

David Schmidt, PhD

2min
page 120

Scott X. Mao, PhD

2min
page 118

Tevis D. B. Jacobs, PhD

1min
page 116

Katherine Hornbostel, PhD

1min
page 115

Daniel G. Cole, PhD, PE

2min
page 114

William W. Clark, PhD

2min
page 113

Heng Ban, PhD, PE

2min
page 110

Minking K. Chyu, PhD

2min
page 112

Markus Chmielus, PhD

1min
page 111

M. Ravi Shankar, PhD

2min
pages 106-108

Jayant Rajgopal, PhD

2min
page 105

Paul W. Leu, PhD

1min
page 102

Lisa M. Maillart, PhD

2min
page 103

Amin Rahimian, PhD

1min
page 104

Youngjae Chun, PhD

3min
page 98

Renee M. Clark, PhD

2min
page 99

Joel M. Haight, PhD, P.E., CIH, CSP

2min
page 100

Daniel R. Jiang, PhD

1min
page 101

Karen M. Bursic, PhD

1min
page 97

Mary Besterfield-Sacre, PhD

2min
page 96

Mostafa Bedewy, PhD

1min
page 95

Minhee Yun, PhD

2min
pages 92-94

Gregory F. Reed, PhD

3min
page 88

Feng Xiong, PhD

2min
page 90

Jun Yang, PhD

3min
page 91

Guangyong Li, PhD

2min
page 86

Inhee Lee, PhD

2min
page 85

Hong Koo Kim, PhD

2min
page 83

Alexis Kwasinski, PhD

2min
page 84

Alex K. Jones, PhD

3min
page 82

Alan D. George, PhD, FIEEE

2min
page 79

Masoud Barati, PhD

2min
page 78

Brandon M. Grainger, PhD

2min
page 80

Mai Abdelhakim, PhD

1min
page 77

Radisav Vidic, PhD

2min
pages 75-76

Piervincenzo Rizzo, PhD

2min
page 73

Aleksandar Stevanovic, PhD, P.E., FASCE

2min
page 74

Carla Ng, PhD

2min
page 72

Lei Fang, PhD

3min
page 65

Alessandro Fascetti, PhD

2min
page 66

Sarah Haig, PhD

2min
page 68

Xu Liang, PhD

2min
page 70

Jeen-Shang Lin, PhD, P.E

2min
page 71

Andrew P. Bunger, PhD

2min
page 64

Melissa Bilec, PhD

2min
page 63

Judith C. Yang, PhD

2min
pages 60-62

Götz Veser, PhD

2min
page 58

Jason E. Shoemaker, PhD

1min
page 56

Tagbo Niepa, PhD

2min
page 54

Christopher E. Wilmer, PhD

1min
page 59

Sachin S. Velankar, PhD

2min
page 57

Giannis Mpourmpakis, PhD

2min
page 53

Badie Morsi, PhD

3min
page 52

James R. McKone, PhD

1min
page 51

Steve R. Little, PhD

2min
page 50

J. Karl Johnson, PhD

2min
page 47

John A. Keith, PhD

2min
page 48

Susan Fullerton, PhD

2min
page 46

Lei Li, PhD

1min
page 49

Robert M. Enick, PhD

2min
page 45

Eric J. Beckman, PhD

2min
page 44

David A. Vorp, PhD

2min
page 37

Jonathan Vande Geest, PhD

1min
page 36

Justin S. Weinbaum, PhD

1min
page 38

Ipsita Banerjee, PhD

2min
page 43

George Stetten, MD, PhD

2min
page 34

Savio L-Y. Woo, PhD, D.Sc., D.Eng

2min
page 39

Gelsy Torres-Oviedo, PhD

3min
page 35

Ioannis Zervantonakis, PhD

2min
pages 40-42

Mark Redfern, PhD

2min
page 29

Spandan Maiti, PhD

2min
page 28

Partha Roy, PhD

2min
page 30

Sanjeev G. Shroff, PhD

2min
page 33

Warren C. Ruder, PhD

1min
page 31

Joseph Thomas Samosky, PhD

2min
page 32

Patrick J. Loughlin, PhD

2min
page 27

Prashant N. Kumta, PhD

2min
page 26

Mangesh Kulkarni, PhD

1min
page 25

Takashi “TK” Kozai, PhD

2min
page 24

Alan D. Hirschman, PhD

1min
page 21

Tamer S. Ibrahim, PhD

5min
page 22

Mark Gartner, PhD

1min
page 20

Bistra Iordanova, PhD

1min
page 23

Richard E. Debski, PhD

1min
page 17

Neeraj J. Gandhi, PhD

2min
page 19

William Federspiel, PhD

2min
page 18

Lance A. Davidson, PhD

2min
page 16

Aaron Batista, PhD

4min
page 9

Rakié Cham, PhD

2min
page 13

Bryan N. Brown, PhD

1min
page 12

Tracy Cui, PhD

2min
page 14

Kurt E. Beschorner, PhD

2min
page 10

Moni Kanchan Datta, PhD

2min
page 15

Harvey Borovetz, PhD

1min
page 11

Steven Abramowitch, PhD

2min
page 8
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