Madhavi Krishnan

Q: What Schools Are Affiliated With Madhavi Krishnan

Madhavi Krishnan is affiliated with the following schools: Imperial College London, University of Oxford, University of Michigan, University of Zurich, TU Dresden

Madhavi Krishnan's AcademicInfluence.com Rankings

Madhavi Krishnan

Chemistry

#1996

World Rank

#2834

Historical Rank

Nanotechnology

#220

World Rank

#220

Historical Rank

Physical Chemistry

#522

World Rank

#573

Historical Rank

chemistry Degrees

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Chemistry

Madhavi Krishnan's Degrees

Masters Chemistry University of Oxford

Why Is Madhavi Krishnan Influential?

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According to Wikipedia, Madhavi Krishnan is a British chemist who is an Associate Professor of Physical Chemistry at the University of Oxford. Krishnan invented an electrostatic fluidic trap which permits the spatial control and manipulation of nanoscale materials. These traps can permit the sensitive detection of biomarkers of disease, allowing for early diagnosis.

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Madhavi Krishnan'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

An integrated nanoliter DNA analysis device. (1998) (1201)
PCR in a Rayleigh-Bénard convection cell. (2002) (245)
An integrated microfluidic device for influenza and other genetic analyses. (2005) (221)
Geometry-induced electrostatic trapping of nanometric objects in a fluid (2010) (210)
Reactions and fluidics in miniaturized natural convection systems. (2004) (89)
Microfabricated reaction and separation systems. (2001) (72)
Single-molecule electrometry. (2017) (58)
Spontaneous stretching of DNA in a two-dimensional nanoslit. (2007) (57)
Measuring the size and charge of single nanoscale objects in solution using an electrostatic fluidic trap. (2012) (53)
Polymerase chain reaction in high surface-to-volume ratio SiO2 microstructures. (2004) (44)
Electrostatic free energy for a confined nanoscale object in a fluid. (2013) (30)
A simple model for electrical charge in globular macromolecules and linear polyelectrolytes in solution (2017) (24)
Information storage and retrieval in a single levitating colloidal particle. (2015) (23)
Measuring three-dimensional interaction potentials using optical interference. (2013) (22)
Entropic Trapping of a Singly Charged Molecule in Solution. (2018) (20)
Novel Convective Flow Based Approaches for High-Throughput PCR Thermocycling (2004) (20)
Electrostatic self-assembly of charged colloids and macromolecules in a fluidic nanoslit. (2008) (19)
Angular trapping of anisometric nano-objects in a fluid. (2012) (19)
Single-molecule trapping and measurement in solution. (2019) (16)
Simultaneous two‐photon fluorescence correlation spectroscopy and lifetime imaging of dye molecules in submicrometer fluidic structures (2007) (14)
Measured electrical charge of SiO2 in polar and nonpolar media. (2016) (13)
Interfacial solvation can explain attraction between like-charged objects in aqueous solution. (2019) (12)
Lattice diffusion of a single molecule in solution. (2017) (7)
A novel strategy for the design of multiple reaction systems for genetic analysis (2002) (6)
Comment on `Nanoconfinement-enhanced conformational response of single DNA molecules to changes in ionic environment' (2008) (5)
Spectrally resolved single-molecule electrometry. (2018) (5)
Electroviscous effect for a confined nanosphere in solution. (2020) (3)
Nonmonotonic Pair Potentials in the Interaction of Like-Charged Objects in Solution. (2022) (2)
Far-Field Electrostatic Signatures of Macromolecular 3D Conformation (2022) (2)
Opto-Electrostatic Determination of Nucleic Acid Double-Helix Dimensions and the Structure of the Molecule–Solvent Interface (2022) (2)
Erratum: “Electrostatic free energy for a confined nanoscale object in a fluid” [J. Chem. Phys. 138, 114906 (2013)] (2013) (1)
Electrostatic free energies carry structural information on nucleic acid molecules in solution. (2022) (1)
Theoretical considerations for counting nucleic acid molecules in microdevices (2005) (0)
Innovations in DNA analysis device technology: Exploiting the effects of scale. (2004) (0)
A charge dependent long-ranged force drives tailored assembly of matter in solution (2022) (0)
The electroviscous eﬀect for a conﬁned nanosphere in solution (2020) (0)
The Role of Surface Chemistry in the Orientational Behavior of Water at an Interface (2022) (0)
Single-Molecule Trapping and Measurement in a Nanostructured Lipid Bilayer System (2022) (0)
Wide-field optical imaging of electrical charge and chemical reactions at the solid–liquid interface (2022) (0)
Erratum: "A simple model for electrical charge in globular macromolecules and linear polyelectrolytes in solution" [J. Chem. Phys. 146, 205101 (2017)]. (2017) (0)
The electrostatic fluidic trap: a new approach to the spatial control and manipulation of matter at the nanometer scale (presentation video) (2014) (0)
Design of multiple reaction systems for genetic analysis (2001) (0)
Single-Molecule Electrometry: A New Tool for Structure, Conformation and Interaction Studies on Single Biomolecules in Solution (2018) (0)

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Other Resources About Madhavi Krishnan

en.wikipedia.org

What Schools Are Affiliated With Madhavi Krishnan?

Madhavi Krishnan is affiliated with the following schools:

Madhavi Krishnan's Academic­Influence.com Rankings

Madhavi Krishnan's Degrees

Why Is Madhavi Krishnan Influential?

Madhavi Krishnan's Published Works

Published Works

Other Resources About Madhavi Krishnan

What Schools Are Affiliated With Madhavi Krishnan?

Madhavi Krishnan's AcademicInfluence.com Rankings