Related references
Note: Only part of the references are listed.Molecular Structure and Modeling of Water-Air and Ice-Air Interfaces Monitored by Sum-Frequency Generation
Fujie Tang et al.
CHEMICAL REVIEWS (2020)
Electrostatic Interactions Control the Functionality of Bacterial Ice Nucleators
M. Lukas et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2020)
Nonadditive Ion Effects Drive Both Collapse and Swelling of Thermoresponsive Polymers in Water
Ellen E. Bruce et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2019)
Ice is born in low-mobility regions of supercooled liquid water
Martin Fitzner et al.
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2019)
Probing the critical nucleus size for ice formation with graphene oxide nanosheets
Guoying Bai et al.
NATURE (2019)
Ice-Nucleating and Antifreeze Proteins Recognize Ice through a Diversity of Anchored Clathrate and Ice-like Motifs
Arpa Hudait et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2018)
The enhancement and suppression of immersion mode heterogeneous ice-nucleation by solutes
Thomas F. Whale et al.
CHEMICAL SCIENCE (2018)
Twin-plate Ice Nucleation Assay (TINA) with infrared detection for high-throughput droplet freezing experiments with biological ice nuclei in laboratory and field samples
Anna T. Kunert et al.
ATMOSPHERIC MEASUREMENT TECHNIQUES (2018)
Beyond the Hofmeister Series: Ion-Specific Effects on Proteins and Their Biological Functions
Halil I. Okur et al.
JOURNAL OF PHYSICAL CHEMISTRY B (2017)
Janus effect of antifreeze proteins on ice nucleation
Kai Liu et al.
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2016)
Ice-nucleating bacteria control the order and dynamics of interfacial water
Ravindra Pandey et al.
SCIENCE ADVANCES (2016)
Intercomparing different devices for the investigation of ice nucleating particles using Snomax (R) as test substance
H. Wex et al.
ATMOSPHERIC CHEMISTRY AND PHYSICS (2015)
BINARY: an optical freezing array for assessing temperature and time dependence of heterogeneous ice nucleation
C. Budke et al.
ATMOSPHERIC MEASUREMENT TECHNIQUES (2015)
The Role of Sulfates on Antifreeze Protein Activity
Konrad Meister et al.
JOURNAL OF PHYSICAL CHEMISTRY B (2014)
Counterion Effect on Interfacial Water at Charged Interfaces and Its Relevance to the Hofmeister Series
Satoshi Nihonyanagi et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2014)
Beyond Hofmeister
Pavel Jungwirth et al.
NATURE CHEMISTRY (2014)
Observation of ice-like water layers at an aqueous protein surface
Konrad Meister et al.
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2014)
Effects of atmospheric conditions on ice nucleation activity of Pseudomonas
E. Attard et al.
ATMOSPHERIC CHEMISTRY AND PHYSICS (2012)
Novel dimeric β-helical model of an ice nucleation protein with bridged active sites
Christopher P. Garnham et al.
BMC STRUCTURAL BIOLOGY (2011)
Specific Anion Effects on Water Structure Adjacent to Protein Monolayers
Xin Chen et al.
LANGMUIR (2010)
Parameterizations for ice nucleation in biological and atmospheric systems
Thomas Koop et al.
PHYSICAL CHEMISTRY CHEMICAL PHYSICS (2009)
Chemistry - Getting specific about specific ion effects
Douglas J. Tobias et al.
SCIENCE (2008)
Specific ion effects on interfacial water structure near macromolecules
Xin Chen et al.
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY (2007)
Ice nucleation in nature: supercooling point (SCP) measurements and the role of heterogeneous nucleation
PW Wilson et al.
CRYOBIOLOGY (2003)
Properties of water solutions of electrolytes and nonelectrolytes
AA Zavitsas
JOURNAL OF PHYSICAL CHEMISTRY B (2001)
Water activity as the determinant for homogeneous ice nucleation in aqueous solutions
T Koop et al.
NATURE (2000)