4.1.1 New Synthesis Method for Graphene Using
Agricultural Waste
5.2.1 A Quick and Simple Blood Test to Detect
Early-Stage Cancer
2033 –
3.2.1 Getting Closer to 3D Nanoprinting
2034 –
2.1 Ultra-Stretchable Silicon
3.1.1 Assembling Nanoparticles into 3D Structures
with Microdroplets
5.1.1 Magnetic Nanovoyagers in Human Blood
2035 –
4.2.1 MAX Phases Get Two-Dimensional as Well
2036 –
1.1.1 Self-Powered Smartwear
5.2.2 Nanoparticles Allow Simple Monitoring of
Circulating Cancer Cells
5.3.1 Untethered Active Microgripper for
Single-Cell Analysis
2037 –
3.2.2 The Emergence of 3D-Printed
Nanostructures
4.2.2 Transistor Made from All-2D Materials
5.3.2 New Technique Precisely Determines
Nanoparticle Uptake into Individual Cells
5.4.2 Surface-Modified Nanocellulose Hydrogels
for Wound Dressing
2038 –
2.2 Rewritable, Transferable and Flexible Sticker-Type
Organic Memory
4.1.1 New Synthesis Method for Graphene Using
Agricultural Waste
2039 –
1.1.2 Cotton T-Shirts As Batteries
5.4.3 Curcumin Nanoparticles as Innovative
Antimicrobial and Wound Healing Agents
2040 –
3.2.3 Printing in Three Dimensions with Graphene
4.2.3 Novel Mono-Elemental Semiconductors:
Arsenene and Antimonene Join 2D Family
2041 –
5.1.2 Microrobots to Deliver Drugs on Demand
5.2.3 Multiplexing Biosensors on a Chip for
Human Metabolite Detection
5.3.3 Optical Sensor Detects Single Cancer
Cells
2042 –
1.1.3 Graphene Yarns Turn Textiles into
Supercapacitors
3.1.2 A Design Guide to Self-Assemble
Nanoparticles into Exotic Superstructures
2043 –
4.1.3 Graphene from Fingerprints
4.2.4 Vanadium Disulfide—A Monolayer Material
for Li-Ion Batteries
5.3.4 Catch and Release of Individual
Cancer Cells
2044 –
2.3 Roll-to-Roll Production of Carbon Nanotube-Based
Supercapacitors
3.2.4 Fully 3D-Printed Quantum Dot LEDs to Fit
a Contact Lens
5.1.3 First Demonstration of Micromotor
Operation in a Living Organism
5.2.4 Multimodal Biosensor Integrates Optical,
Electrical, and Mechanical Signals
2045 –
1.2.1 Solar Cell Textiles
2046 –
5.4.4 Multifunctional RNA Nanoparticles to
Combat Cancer and Viral Infections
2047 –
3.1.3 3D Nanopatterning with Memory-Based,
Sequential Wrinkling
5.2.5 Detecting Damaged DNA with Solid-State
Nanopores
5.3.5 Sensing of Single Malaria-Infected Red
Blood Cells
1.1.4 Silky Substrate Makes Flexible Solar Cells
Biocompatible
2048-
2.4 Foldable Capacitive Touch Pad Printed with
Nanowire Ink
3.2.5 3D-Printed Programmable Release Capsules
4.1.4 Graphene Laminate Drastically Changes
Heat Conduction of Plastic Materials
2049 –
1.2.2 Complete Solar Cells Printed by Inkjet##
5.4.5 Replacing Antibiotics with Graphene-Based
Photothermal Agents
5.4.6 Nanotechnology Against Acne*
2050 –
1.1.5 Folding Origami Batteries
2.5 Computer Memory Printed on Paper
3.1.4 Spraying Light—the Fabrication of
Light-Emitting 3D Objects
4.2.5 Chemically Enhanced 2D Material Makes
Excellent Tunable Nanoscale Light Source
5.1.4 Multiplexed Planar Array Analysis from
Within a Living Cell
2051 –
2.6 Nanopaper Transistors
3.2.6 Embedded 3D-Printing for Soft Robotics
Fabrication
2052 –
5.4.7 Biofunctionalized Silk Nanofibers Repair
the Optic Nerve
2053 –
3.1.5 Microfabrication Inspired by LEGO™
5.3.6 Novel Mechanobiological Tool for
Probing the Inner Workings of a Cell
2054 –
2.7 Approaching the Limits of Transparency and
Conductivity with Nanomaterials
4.1.5 Graphene Quantum Dot Band-Aids Disinfect
Wounds
5.2.6 Wearable Graphene Strain Sensors Monitor
Human Vital Signs
2055 –
1.1.6 Towards Self-Powered Electronic Papers
1.2.3 Solar Paint Paves the Way for Low-Cost
Photovol## taics
2056 –
5.1.5 Self-Powered Micropumps Respond to
Glucose Levels
5.4.8 Move Over Chips—Here Come
Multifunctional Labs on a Single Fiber
2058 –
1.1.7 Light-Driven Bioelectronic Implants
Don’t Need Batteries
2.7 Approaching the Limits of Transparency and
Conductivity with Nanomaterials
3.1.6 Atomic Calligraphy
5.2.9 Ultrafast Sensor Monitors You While You
Speak
5.3.7 Snail-Inspired Nanosensor Detects and
Maps mRNA in Living Cells
5.4.10 A Nanoparticle-Based Alternative to Viagra*##
2059 –
4.1.6 A Nanomotor that Mimics an Internal
Combustion Engine
5.4.9 Nanoparticles Accelerate and Improve
Healing of Burn Wounds
2060 –
1.1.8 A Stretchable Far-Field Communication
Antenna for Wearable Electr## onics
5.2.10 Detecting Flu Viruses in Exhaled Breath
2061 –
3.1.7 Complex Assemblies Based on Micelle-Like
Nanostruc tures
4.1.7 The Most Effective Material for EMI Shielding
5.1.6 Sneaking Drugs into Cancer Cells
2062 –
5.3.8 Silicon Chips Inserted into Living Cells Can
Feel the Pressure
2063 –
1.1.9 Reversibly Bistable Materials Could
Revolutionize Flexible Electronics
1.2.4 Paper Solar Cells
3.1.8 Precise Manipulation of Single Nanoparticles
with E-Beam Tweezers
5.2.11 Nanosensor for Advanced Cancer
Biomarker Detection
2064 –
5.1.7 Nanoparticle-Corked Nanotubes as Drug
Delivery Vehicles
5.2.12 Optical Detection of Epigenetic Marks
2065 –
1.2.5 Recharging Wearable Textile Battery by
Sunlight
4.1.8 Eavesdropping on Cells with Graphene
Transistors
2.10 Nanoelectronics on Textiles, Paper, Wood and
Stone
5.4.11 Light-Triggered Local Anesthesia
2066 –
5.2.13 Nanosensor Tattoo on Teeth Monitors
Bacteria in Your Mouth
5.4.12 Toward Next-Generation Nanomedicines
for Cancer Therapy
2067 –
1.1.10 Nanogenerators for Large-Scale Energy
Harvesting
5.1.8 Plasmonic Nanocrystals for Combined
Photothermal and Photodynamic Cancer
Therapies
2068 –
2.9 Integrating Nanoelectronic Devices onto Living
Plants and Insects
3.1.9 Trapping Individual Metal Nanoparticles
in Air
4.1.9 Graphene Beats Polymer Coatings in
Preventing Microbially-Induced Corrosion
2070 –
3.1.10 Plant Viruses Assist with Building Nanoscale
Devices
5.2.14 Tracking Nanomedicines Inside the Body
2071 –
4.1.10 Janus Separator: A New Opportunity to
Improve Lithium–Sulfur Batteries
5.3.9 Direct Observation of How Nanoparticles
Interact with the Nucleus of a Cancer Cell
2072 –
3.1.11 Sculpting 3D Silicon Structures at the Single
Nanometer Scale
2073 –
5.1.9 Remotely Activating Biological Materials
with Nanocomposites
5.2.15 Measuring Femtoscale Displacement for
Photoacoustic Spectroscopy
2074 –
5.1.10 Pre-Coating Nanoparticles to Better Deal
with Protein Coronas
5.3.10 A Precise Nanothermometer for Intracellular
Temperature Mapping
2075 –
3.1.12 Probing the Resolution Limits of
Electron-Beam Lithography
3.1.16 Self-Assembly Machines—A Vision for the
Future of Manufacturing
2086 –
5.3.12 Functionalizing Living Cells
# Nanotech
## 2031 –
5.4.1 High-Tech Band-Aids
## 2032 –
4.1.1 New Synthesis Method for Graphene Using
Agricultural Waste
5.2.1 A Quick and Simple Blood Test to Detect
Early-Stage Cancer
## 2033 –
3.2.1 Getting Closer to 3D Nanoprinting
## 2034 –
2.1 Ultra-Stretchable Silicon
3.1.1 Assembling Nanoparticles into 3D Structures
with Microdroplets
5.1.1 Magnetic Nanovoyagers in Human Blood
## 2035 –
4.2.1 MAX Phases Get Two-Dimensional as Well
## 2036 –
1.1.1 Self-Powered Smartwear
5.2.2 Nanoparticles Allow Simple Monitoring of
Circulating Cancer Cells
5.3.1 Untethered Active Microgripper for
Single-Cell Analysis
## 2037 –
3.2.2 The Emergence of 3D-Printed
Nanostructures
4.2.2 Transistor Made from All-2D Materials
5.3.2 New Technique Precisely Determines
Nanoparticle Uptake into Individual Cells
5.4.2 Surface-Modified Nanocellulose Hydrogels
for Wound Dressing
## 2038 –
2.2 Rewritable, Transferable and Flexible Sticker-Type
Organic Memory
4.1.1 New Synthesis Method for Graphene Using
Agricultural Waste
## 2039 –
1.1.2 Cotton T-Shirts As Batteries
5.4.3 Curcumin Nanoparticles as Innovative
Antimicrobial and Wound Healing Agents
## 2040 –
3.2.3 Printing in Three Dimensions with Graphene
4.2.3 Novel Mono-Elemental Semiconductors:
Arsenene and Antimonene Join 2D Family
## 2041 –
5.1.2 Microrobots to Deliver Drugs on Demand
5.2.3 Multiplexing Biosensors on a Chip for
Human Metabolite Detection
5.3.3 Optical Sensor Detects Single Cancer
Cells
## 2042 –
1.1.3 Graphene Yarns Turn Textiles into
Supercapacitors
3.1.2 A Design Guide to Self-Assemble
Nanoparticles into Exotic Superstructures
## 2043 –
4.1.3 Graphene from Fingerprints
4.2.4 Vanadium Disulfide—A Monolayer Material
for Li-Ion Batteries
5.3.4 Catch and Release of Individual
Cancer Cells
## 2044 –
2.3 Roll-to-Roll Production of Carbon Nanotube-Based
Supercapacitors
3.2.4 Fully 3D-Printed Quantum Dot LEDs to Fit
a Contact Lens
5.1.3 First Demonstration of Micromotor
Operation in a Living Organism
## 5.2.4 Multimodal Biosensor Integrates Optical,
Electrical, and Mechanical Signals
## 2045 –
1.2.1 Solar Cell Textiles
## 2046 –
5.4.4 Multifunctional RNA Nanoparticles to
Combat Cancer and Viral Infections
## 2047 –
3.1.3 3D Nanopatterning with Memory-Based,
Sequential Wrinkling
5.2.5 Detecting Damaged DNA with Solid-State
Nanopores
5.3.5 Sensing of Single Malaria-Infected Red
Blood Cells
1.1.4 Silky Substrate Makes Flexible Solar Cells
Biocompatible
## 2048-
2.4 Foldable Capacitive Touch Pad Printed with
Nanowire Ink
3.2.5 3D-Printed Programmable Release Capsules
4.1.4 Graphene Laminate Drastically Changes
Heat Conduction of Plastic Materials
## 2049 –
1.2.2 Complete Solar Cells Printed by Inkjet##
5.4.5 Replacing Antibiotics with Graphene-Based
Photothermal Agents
5.4.6 Nanotechnology Against Acne*
## 2050 –
1.1.5 Folding Origami Batteries
2.5 Computer Memory Printed on Paper
3.1.4 Spraying Light—the Fabrication of
Light-Emitting 3D Objects
4.2.5 Chemically Enhanced 2D Material Makes
Excellent Tunable Nanoscale Light Source
5.1.4 Multiplexed Planar Array Analysis from
Within a Living Cell
## 2051 –
2.6 Nanopaper Transistors
3.2.6 Embedded 3D-Printing for Soft Robotics
Fabrication
## 2052 –
5.4.7 Biofunctionalized Silk Nanofibers Repair
the Optic Nerve
## 2053 –
3.1.5 Microfabrication Inspired by LEGO™
5.3.6 Novel Mechanobiological Tool for
Probing the Inner Workings of a Cell
## 2054 –
2.7 Approaching the Limits of Transparency and
Conductivity with Nanomaterials
4.1.5 Graphene Quantum Dot Band-Aids Disinfect
Wounds
5.2.6 Wearable Graphene Strain Sensors Monitor
Human Vital Signs
## 2055 –
1.1.6 Towards Self-Powered Electronic Papers
1.2.3 Solar Paint Paves the Way for Low-Cost
Photovol## taics
## 2056 –
5.1.5 Self-Powered Micropumps Respond to
Glucose Levels
5.4.8 Move Over Chips—Here Come
Multifunctional Labs on a Single Fiber
## 2058 –
1.1.7 Light-Driven Bioelectronic Implants
Don’t Need Batteries
2.7 Approaching the Limits of Transparency and
Conductivity with Nanomaterials
3.1.6 Atomic Calligraphy
5.2.9 Ultrafast Sensor Monitors You While You
Speak
5.3.7 Snail-Inspired Nanosensor Detects and
Maps mRNA in Living Cells
5.4.10 A Nanoparticle-Based Alternative to Viagra*##
## 2059 –
4.1.6 A Nanomotor that Mimics an Internal
Combustion Engine
5.4.9 Nanoparticles Accelerate and Improve
Healing of Burn Wounds
## 2060 –
1.1.8 A Stretchable Far-Field Communication
Antenna for Wearable Electr## onics
5.2.10 Detecting Flu Viruses in Exhaled Breath
## 2061 –
3.1.7 Complex Assemblies Based on Micelle-Like
Nanostruc tures
4.1.7 The Most Effective Material for EMI Shielding
5.1.6 Sneaking Drugs into Cancer Cells
## 2062 –
5.3.8 Silicon Chips Inserted into Living Cells Can
Feel the Pressure
## 2063 –
1.1.9 Reversibly Bistable Materials Could
Revolutionize Flexible Electronics
1.2.4 Paper Solar Cells
3.1.8 Precise Manipulation of Single Nanoparticles
with E-Beam Tweezers
5.2.11 Nanosensor for Advanced Cancer
Biomarker Detection
## 2064 –
5.1.7 Nanoparticle-Corked Nanotubes as Drug
Delivery Vehicles
5.2.12 Optical Detection of Epigenetic Marks
## 2065 –
1.2.5 Recharging Wearable Textile Battery by
Sunlight
4.1.8 Eavesdropping on Cells with Graphene
Transistors
2.10 Nanoelectronics on Textiles, Paper, Wood and
Stone
5.4.11 Light-Triggered Local Anesthesia
## 2066 –
5.2.13 Nanosensor Tattoo on Teeth Monitors
Bacteria in Your Mouth
5.4.12 Toward Next-Generation Nanomedicines
for Cancer Therapy
## 2067 –
1.1.10 Nanogenerators for Large-Scale Energy
Harvesting
5.1.8 Plasmonic Nanocrystals for Combined
Photothermal and Photodynamic Cancer
Therapies
## 2068 –
2.9 Integrating Nanoelectronic Devices onto Living
Plants and Insects
3.1.9 Trapping Individual Metal Nanoparticles
in Air
4.1.9 Graphene Beats Polymer Coatings in
Preventing Microbially-Induced Corrosion
## 2070 –
3.1.10 Plant Viruses Assist with Building Nanoscale
Devices
5.2.14 Tracking Nanomedicines Inside the Body
## 2071 –
4.1.10 Janus Separator: A New Opportunity to
Improve Lithium–Sulfur Batteries
5.3.9 Direct Observation of How Nanoparticles
Interact with the Nucleus of a Cancer Cell
## 2072 –
3.1.11 Sculpting 3D Silicon Structures at the Single
Nanometer Scale
## 2073 –
5.1.9 Remotely Activating Biological Materials
with Nanocomposites
5.2.15 Measuring Femtoscale Displacement for
Photoacoustic Spectroscopy
## 2074 –
5.1.10 Pre-Coating Nanoparticles to Better Deal
with Protein Coronas
5.3.10 A Precise Nanothermometer for Intracellular
Temperature Mapping
## 2075 –
3.1.12 Probing the Resolution Limits of
Electron-Beam Lithography
## 2076 –
5.2.16 Reduced Graphene Oxide Platform
Shows Extreme Sensitivity to Circulating
Tumor Cells
## 2077 –
5.3.11 Direct Observation of Drug Release from
Carbon Nanotubes in Living Cells
## 2078 –
3.1.13 Foldable Glass
## 2080 –
3.1.14 Plasmonic Biofoam Beats Conventional
Plasmonic Surfaces
## 2081 –
3.1.15 Nanotechnology in a Bubble
## 2083 –
3.1.16 Self-Assembly Machines—A Vision for the
Future of Manufacturing
## 2086 –
5.3.12 Functionalizing Living Cells
Nanotech
2031 –
5.4.1 High-Tech Band-Aids
2032 –
4.1.1 New Synthesis Method for Graphene Using Agricultural Waste 5.2.1 A Quick and Simple Blood Test to Detect Early-Stage Cancer
2033 –
3.2.1 Getting Closer to 3D Nanoprinting
2034 –
2.1 Ultra-Stretchable Silicon 3.1.1 Assembling Nanoparticles into 3D Structures with Microdroplets 5.1.1 Magnetic Nanovoyagers in Human Blood
2035 –
4.2.1 MAX Phases Get Two-Dimensional as Well
2036 –
1.1.1 Self-Powered Smartwear 5.2.2 Nanoparticles Allow Simple Monitoring of Circulating Cancer Cells 5.3.1 Untethered Active Microgripper for Single-Cell Analysis
2037 –
3.2.2 The Emergence of 3D-Printed Nanostructures 4.2.2 Transistor Made from All-2D Materials 5.3.2 New Technique Precisely Determines Nanoparticle Uptake into Individual Cells 5.4.2 Surface-Modified Nanocellulose Hydrogels for Wound Dressing
2038 –
2.2 Rewritable, Transferable and Flexible Sticker-Type Organic Memory 4.1.1 New Synthesis Method for Graphene Using Agricultural Waste
2039 –
1.1.2 Cotton T-Shirts As Batteries 5.4.3 Curcumin Nanoparticles as Innovative Antimicrobial and Wound Healing Agents
2040 –
3.2.3 Printing in Three Dimensions with Graphene 4.2.3 Novel Mono-Elemental Semiconductors: Arsenene and Antimonene Join 2D Family
2041 –
5.1.2 Microrobots to Deliver Drugs on Demand 5.2.3 Multiplexing Biosensors on a Chip for Human Metabolite Detection 5.3.3 Optical Sensor Detects Single Cancer Cells
2042 –
1.1.3 Graphene Yarns Turn Textiles into Supercapacitors 3.1.2 A Design Guide to Self-Assemble Nanoparticles into Exotic Superstructures
2043 –
4.1.3 Graphene from Fingerprints 4.2.4 Vanadium Disulfide—A Monolayer Material for Li-Ion Batteries 5.3.4 Catch and Release of Individual Cancer Cells
2044 –
2.3 Roll-to-Roll Production of Carbon Nanotube-Based Supercapacitors 3.2.4 Fully 3D-Printed Quantum Dot LEDs to Fit a Contact Lens 5.1.3 First Demonstration of Micromotor Operation in a Living Organism
5.2.4 Multimodal Biosensor Integrates Optical,
Electrical, and Mechanical Signals
2045 –
1.2.1 Solar Cell Textiles
2046 –
5.4.4 Multifunctional RNA Nanoparticles to Combat Cancer and Viral Infections
2047 –
3.1.3 3D Nanopatterning with Memory-Based, Sequential Wrinkling 5.2.5 Detecting Damaged DNA with Solid-State Nanopores 5.3.5 Sensing of Single Malaria-Infected Red Blood Cells 1.1.4 Silky Substrate Makes Flexible Solar Cells Biocompatible
2048-
2.4 Foldable Capacitive Touch Pad Printed with Nanowire Ink 3.2.5 3D-Printed Programmable Release Capsules 4.1.4 Graphene Laminate Drastically Changes Heat Conduction of Plastic Materials
2049 –
1.2.2 Complete Solar Cells Printed by Inkjet## 5.4.5 Replacing Antibiotics with Graphene-Based Photothermal Agents 5.4.6 Nanotechnology Against Acne*
2050 –
1.1.5 Folding Origami Batteries 2.5 Computer Memory Printed on Paper 3.1.4 Spraying Light—the Fabrication of Light-Emitting 3D Objects 4.2.5 Chemically Enhanced 2D Material Makes Excellent Tunable Nanoscale Light Source 5.1.4 Multiplexed Planar Array Analysis from Within a Living Cell
2051 –
2.6 Nanopaper Transistors 3.2.6 Embedded 3D-Printing for Soft Robotics Fabrication
2052 –
5.4.7 Biofunctionalized Silk Nanofibers Repair the Optic Nerve
2053 –
3.1.5 Microfabrication Inspired by LEGO™ 5.3.6 Novel Mechanobiological Tool for Probing the Inner Workings of a Cell
2054 –
2.7 Approaching the Limits of Transparency and Conductivity with Nanomaterials 4.1.5 Graphene Quantum Dot Band-Aids Disinfect Wounds 5.2.6 Wearable Graphene Strain Sensors Monitor Human Vital Signs
2055 –
1.1.6 Towards Self-Powered Electronic Papers 1.2.3 Solar Paint Paves the Way for Low-Cost Photovol## taics
2056 –
5.1.5 Self-Powered Micropumps Respond to Glucose Levels 5.4.8 Move Over Chips—Here Come Multifunctional Labs on a Single Fiber
2058 –
1.1.7 Light-Driven Bioelectronic Implants Don’t Need Batteries 2.7 Approaching the Limits of Transparency and Conductivity with Nanomaterials 3.1.6 Atomic Calligraphy 5.2.9 Ultrafast Sensor Monitors You While You Speak 5.3.7 Snail-Inspired Nanosensor Detects and Maps mRNA in Living Cells 5.4.10 A Nanoparticle-Based Alternative to Viagra*##
2059 –
4.1.6 A Nanomotor that Mimics an Internal Combustion Engine 5.4.9 Nanoparticles Accelerate and Improve Healing of Burn Wounds
2060 –
1.1.8 A Stretchable Far-Field Communication Antenna for Wearable Electr## onics 5.2.10 Detecting Flu Viruses in Exhaled Breath
2061 –
3.1.7 Complex Assemblies Based on Micelle-Like Nanostruc tures 4.1.7 The Most Effective Material for EMI Shielding 5.1.6 Sneaking Drugs into Cancer Cells
2062 –
5.3.8 Silicon Chips Inserted into Living Cells Can Feel the Pressure
2063 –
1.1.9 Reversibly Bistable Materials Could Revolutionize Flexible Electronics 1.2.4 Paper Solar Cells 3.1.8 Precise Manipulation of Single Nanoparticles with E-Beam Tweezers 5.2.11 Nanosensor for Advanced Cancer Biomarker Detection
2064 –
5.1.7 Nanoparticle-Corked Nanotubes as Drug Delivery Vehicles 5.2.12 Optical Detection of Epigenetic Marks
2065 –
1.2.5 Recharging Wearable Textile Battery by Sunlight 4.1.8 Eavesdropping on Cells with Graphene Transistors 2.10 Nanoelectronics on Textiles, Paper, Wood and Stone 5.4.11 Light-Triggered Local Anesthesia
2066 –
5.2.13 Nanosensor Tattoo on Teeth Monitors Bacteria in Your Mouth 5.4.12 Toward Next-Generation Nanomedicines for Cancer Therapy
2067 –
1.1.10 Nanogenerators for Large-Scale Energy Harvesting 5.1.8 Plasmonic Nanocrystals for Combined Photothermal and Photodynamic Cancer Therapies
2068 –
2.9 Integrating Nanoelectronic Devices onto Living Plants and Insects 3.1.9 Trapping Individual Metal Nanoparticles in Air 4.1.9 Graphene Beats Polymer Coatings in Preventing Microbially-Induced Corrosion
2070 –
3.1.10 Plant Viruses Assist with Building Nanoscale Devices 5.2.14 Tracking Nanomedicines Inside the Body
2071 –
4.1.10 Janus Separator: A New Opportunity to Improve Lithium–Sulfur Batteries 5.3.9 Direct Observation of How Nanoparticles Interact with the Nucleus of a Cancer Cell
2072 –
3.1.11 Sculpting 3D Silicon Structures at the Single Nanometer Scale
2073 –
5.1.9 Remotely Activating Biological Materials with Nanocomposites 5.2.15 Measuring Femtoscale Displacement for Photoacoustic Spectroscopy
2074 –
5.1.10 Pre-Coating Nanoparticles to Better Deal with Protein Coronas 5.3.10 A Precise Nanothermometer for Intracellular Temperature Mapping
2075 –
3.1.12 Probing the Resolution Limits of Electron-Beam Lithography
2076 –
5.2.16 Reduced Graphene Oxide Platform Shows Extreme Sensitivity to Circulating Tumor Cells
2077 –
5.3.11 Direct Observation of Drug Release from Carbon Nanotubes in Living Cells
2078 –
3.1.13 Foldable Glass
2080 –
3.1.14 Plasmonic Biofoam Beats Conventional Plasmonic Surfaces
2081 –
3.1.15 Nanotechnology in a Bubble
2083 –
3.1.16 Self-Assembly Machines—A Vision for the Future of Manufacturing
2086 –
5.3.12 Functionalizing Living Cells