Paul W. K. Rothemund

Paul W. K. Rothemund's AcademicInfluence.com Rankings

Chemistry

#848

World Rank

#1392

Historical Rank

#360

USA Rank

Nanotechnology

#26

World Rank

#26

Historical Rank

#12

USA Rank

chemistry Degrees

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Chemistry

Why Is Paul W. K. Rothemund Influential?

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According to Wikipedia, Paul Wilhelm Karl Rothemund is a research professor at the Computation and Neural Systems department at Caltech. He has become known in the fields of DNA nanotechnology and synthetic biology for his pioneering work with DNA origami. He shared both categories of the 2006 Feynman Prize in Nanotechnology with Erik Winfree for their work in creating DNA nanotubes, algorithmic molecular self-assembly of DNA tile structures, and their theoretical work on DNA computing. Rothemund is also a 2007 recipient of the MacArthur Fellowship.

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Paul W. K. Rothemund's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Folding DNA to create nanoscale shapes and patterns (2006) (5602)
Algorithmic Self-Assembly of DNA Sierpinski Triangles (2004) (811)
Self-assembly of carbon nanotubes into two-dimensional geometries using DNA origami templates. (2010) (564)
Solution of a 20-Variable 3-SAT Problem on a DNA Computer (2002) (523)
The program-size complexity of self-assembled squares (extended abstract) (2000) (460)
Design and characterization of programmable DNA nanotubes. (2004) (400)
Placement and orientation of individual DNA shapes on lithographically patterned surfaces. (2009) (355)
Programmable molecular recognition based on the geometry of DNA nanostructures. (2011) (320)
An autonomous polymerization motor powered by DNA hybridization (2007) (300)
A single-stranded architecture for cotranscriptional folding of RNA nanostructures (2014) (266)
Two computational primitives for algorithmic self-assembly: copying and counting. (2005) (235)
An information-bearing seed for nucleating algorithmic self-assembly (2009) (230)
A New Porphyrin Synthesis. The Synthesis of Porphin1 (1936) (208)
A Sticker-Based Model for DNA Computation (1998) (201)
FORMATION OF PORPHYRINS FROM PYRROLE AND ALDEHYDES (1935) (195)
Porphyrin Studies. V.1 The Metal Complex Salts of α,β,γ,δ-Tetraphenylporphine (1948) (193)
Engineering and mapping nanocavity emission via precision placement of DNA origami (2016) (185)
A DNA and restriction enzyme implementation of Turing machines (1995) (175)
On applying molecular computation to the data encryption standard (1999) (167)
Combinatorial optimization problems in self-assembly (2002) (150)
Rothemund, P.W.K.: Folding DNA to create nanoscale shapes and patterns. Nature 440, 297-302 (2006) (132)
Erratum: Self-assembly of two-dimensional DNA origami lattices using cation-controlled surface diffusion (2014) (128)
Using lateral capillary forces to compute by self-assembly (2000) (126)
Porphyrin Studies. III.1 The Structure of the Porphine2 Ring System (1939) (119)
Solution of a Satisfiability Problem on a Gel-Based DNA Computer (2000) (115)
Sturdier DNA nanotubes via ligation. (2005) (112)
Theory and experiments in algorithmic self-assembly (2001) (112)
Porphyrin Studies. IV.1 The Synthesis of α,β,γ,δ-Tetraphenylporphine (1941) (110)
Self-Assembled Circuit Patterns (2003) (103)
Optimized assembly and covalent coupling of single-molecule DNA origami nanoarrays. (2014) (99)
A population‐based temporal logic gate for timing and recording chemical events (2016) (83)
DNA Nanotechnology: A foundation for Programmable Nanoscale Materials (2017) (62)
Concerning the Structure of “Acetonepyrrole” (1955) (62)
A sticker based model for DNA computation (1996) (57)
Design of DNA origami (2005) (57)
Nanotechnology: The importance of being modular (2012) (44)
Absolute and arbitrary orientation of single-molecule shapes (2018) (43)
RNA origami design tools enable cotranscriptional folding of kilobase-sized nanoscaffolds (2021) (32)
Branched kissing loops for the construction of diverse RNA homooligomeric nanostructures (2019) (30)
Scaffolded DNA Origami: from Generalized Multicrossovers to Polygonal Networks (2006) (29)
Occurrence of Decomposition Products of Chlorophyll. II. Decomposition Products of Chlorophyll in the Stomach Walls of Herbivorous Animals1 (1934) (18)
Hydroxyl-Directed, Stereoselective Olefination of Ketones by Transition Metal Alkylidenes (1995) (15)
Bench-Top Fabrication of Single-Molecule Nanoarrays by DNA Origami Placement. (2021) (15)
THE CHEMILUMINESCENCE OF THE CHLOROPHYLLS, AND OF SOME OTHER PORPHYRIN METAL COMPLEX SALTS (1938) (13)
Properties of DNA- and Protein-Scaffolded Lipid Nanodiscs. (2020) (12)
OCCURRENCE OF DECOMPOSITION PRODUCTS OF CHLOROPHYLL. I. DECOMPOSITION OF CHLOROPHYLL IN THE DIGESTIVE SYSTEM OF THE COW (1932) (10)
Occurrence of Decomposition Products of Chlorophyll. III.1 Isolation of Pyrroporphyrin from Beef Bile1a (1935) (7)
Beyond Watson and Crick: Programming DNA self-assembly for nanofabrication (2012) (7)
Low-cost, bottom-up fabrication of large-scale single-molecule nanoarrays by DNA origami placement (2020) (5)
Self-assembly of two-dimensional DNA origami lattices using cation-controlled surface diffusion (2014) (5)
A population-based temporal logic gate for timing and recording chemical events (2015) (3)
Hemin and Chlorophyll : the Two Most Important Pigments for Life on Earth (1956) (3)
Progressive Alignment of Shapes (2016) (2)
Hydroxyl‐Directed, Stereoselective Olefination of Ketones by Transition Metal Alkylidenes. (1995) (1)
Ray Optics for Gliders. (2021) (1)
Porphyrin studies; the metal complex salts of alpha, beta, gamma, delta-tetraphenylporphine. (1948) (1)
Correction to "Design and Characterization of Programmable DNA Nanotubes" (2013) (1)
THE OCCURRENCE OF PHYLLOERYTHRIN IN THE DIGESTIVE SYSTEM OF HERBIVOROUS ANIMALS. (1931) (1)
Snell’s Law for Gliders (2022) (0)
Design and Characterization of Programmable DNA Nanotubes Supporting Information (2004) (0)
The Application of Absorption Spectroscopy to the Study of Chicrophyl and Photosynthesis (1946) (0)
Chloroplast pigments and chromotographic analysis (1959) (0)
Design and Characterization of Programmable DNA Nanotubes Correction to Supporting Information (2013) (0)
Snell’s Law for Swimmers (2021) (0)
Biology: Following in the wake (2009) (0)
Interfacing Molecules with the Macroscopic World (2017) (0)
Development of Long, Stiff DNA Tubes as Nanopatterned Substrates for Protein Binding (2005) (0)
Digital nanoreactors for control over absolute stoichiometry and spatiotemporal behavior of receptors within lipid bilayers (2022) (0)
Composite of 64 AFM Images Taken Sequentially at Scales - Sierpinski Triangles (2011) (0)
Digital nanoreactors to control absolute stoichiometry and spatiotemporal behavior of DNA receptors within lipid bilayers (2023) (0)
Quantum dots coupled to chip-based dielectric resonators via DNA origami mediated assembly (Conference Presentation) (2016) (0)
Nanotechnology: Science and Computation - ReadingSample (2017) (0)

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Other Resources About Paul W. K. Rothemund

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What Schools Are Affiliated With Paul W. K. Rothemund?

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