Skip to main content

Silver Nanoparticles: Properties and Applications

Silver Nanoparticles: Properties and Applications

Steven J. Oldenburg, Ph.D.
President - nanoComposix, Inc.
Silver nanoparticles have unique optical, electrical, and thermal properties and are being incorporated into products that range from photovoltaics to biological and chemical sensors. Examples include conductive inks, pastes and fillers which utilize silver nanoparticles for their high electrical conductivity, stability, and low sintering temperatures. Additional applications include molecular diagnostics and photonic devices, which take advantage of the novel optical properties of these nanomaterials. An increasingly common application is the use of silver nanoparticles for antimicrobial coatings, and many textiles, keyboards, wound dressings, and biomedical devices now contain silver nanoparticles that continuously release a low level of silver ions to provide protection against bacteria.
Figure 1: Transmission electron microscopy (TEM) images of silver nanoparticles with diameters of 20 nm (Aldrich Prod. No. 730793), 60 nm (Aldrich Prod. No.730815), and 100 nm (Aldrich Prod. No. 730777) respectively. Scale bars are 50 nm.
Understanding how the size, shape, surface, and aggregation state of the silver nanoparticles change after integration into a target application is critical for optimizing performance. Aldrich Materials Science offers precisely manufactured monodisperse silver nanoparticles that are free from agglomeration, making them ideal for research, development, and use in a variety of innovative applications (Figure 1). Each batch of nanoparticles is extensively characterized using transmission electron microscopy (TEM) images, dynamic light scattering (for particle size analysis), Zeta potential measurements, and UV/Visible spectral analysis to ensure consistent materials in every order.
Silver Nanoparticle Optical Properties
There is growing interest in utilizing the optical properties of silver nanoparticles as the functional component in various products and sensors. Silver nanoparticles are extraordinarily efficient at absorbing and scattering light and, unlike many dyes and pigments, have a color that depends upon the size and the shape of the particle. The strong interaction of the silver nanoparticles with light occurs because the conduction electrons on the metal surface undergo a collective oscillation when excited by light at specific wavelengths (Figure 2, left). Known as a surface plasmon resonance (SPR), this oscillation results in unusually strong scattering and absorption properties. In fact, silver nanoparticles can have effective extinction (scattering + absorption) cross sections up to ten times larger than their physical cross section. The strong scattering cross section allows for sub 100 nm nanoparticles to be easily visualized with a conventional microscope. When 60 nm silver nanoparticles are illuminated with white light they appear as bright blue point source scatterers under a dark field microscope (Figure 2, right). The bright blue color is due to an SPR that is peaked at a 450 nm wavelength. A unique property of spherical silver nanoparticles is that this SPR peak wavelength can be tuned from 400 nm (violet light) to 530 nm (green light) by changing the particle size and the local refractive index near the particle surface. Even larger shifts of the SPR peak wavelength out into the infrared region of the electromagnetic spectrum can be achieved by producing silver nanoparticles with rod or plate shapes.
Figure 2: (Left) Surface plasmon resonance where the free electrons in the metal nanoparticle are driven into oscillation due to a strong coupling with a specific wavelength of incident light. (Right) Dark field microscopy image of 60 nm silver nanoparticles (Aldrich Prod. No. 730815).
Silver Nanoparticle Characterization
The size and shape of metal nanoparticles are typically measured by analytical techniques such as TEM, scanning electron microscopy (SEM) or atomic force microscopy (AFM). Measuring the aggregation state of the particles requires a technique to measure the effective size of the particles in solution such as dynamic light scattering (DLS) or analytical disc centrifugation. However, due to the unique optical properties of silver nanoparticles, a great deal of information about the physical state of the nanoparticles can be obtained by analyzing the spectral properties of silver nanoparticles in solution. The spectral response of silver nanoparticles as a function of diameter is shown in Figure 3, left. As the diameter increases, the peak plasmon resonance shifts to longer wavelengths and broadens. At diameters greater than 80 nm, a second peak becomes visible at a shorter wavelength than the primary peak. This secondary peak is due to a quadrupole resonance that has a different electron oscillation pattern than the primary dipole resonance. The peak wavelength, the peak width, and the effect of secondary resonances yield a unique spectral fingerprint for a plasmonic nanoparticle with a specific size and shape. Additionally, UV-Visible spectroscopy provides a mechanism to monitor how the nanoparticles change over time. When silver nanoparticles aggregate, the metal particles become electronically coupled and this coupled system has a different SPR than the individual particles. For the case of a multi-nanoparticle aggregate, the plasmon resonance will be red-shifted to a longer wavelength than the resonance of an individual nanoparticle, and aggregation is observable as an intensity increase in the red/infrared region of the spectrum. This effect can be observed in Figure 3, right, which displays the optical response of a silver nanoparticle solution destabilized by the addition of saline. Carefully monitoring the UV-Visible spectrum of the silver nanoparticles with time is a sensitive technique used in determining if any nanoparticle aggregation has occurred.
Figure 3. (Left) Extinction (scattering + absorption) spectra of silver nanoparticles with diameters ranging from 10-100 nm at mass concentrations of 0.02 mg/mL. (Right) Extinction spectra of silver nanoparticles after the addition of a destabilizing salt solution.
For silver nanoparticle solutions that have not agglomerated and have a spectral shape that is identical to the as-received suspension, the UV/Visible extinction spectra can be used to quantify the nanoparticle concentration. The concentration of silver nanoparticle solutions is calculated using the Beer-Lambert law, which correlates the optical density (OD, a measure of the amount of light transmitted through a solution) with concentration. Due to the linear relationship between OD and concentration, these values can be used to quantify the concentration of nanoparticle solutions.
Silver Nanoparticle Surface Chemistry
When nanoparticles are in solution, molecules associate with the nanoparticle surface to establish a double layer of charge that stabilizes the particles and prevents aggregation. Aldrich Materials Science offers several silver nanoparticles suspended in a dilute aqueous citrate buffer, which weakly associates with the nanoparticle surface. This citrate-based agent was selected because the weakly bound capping agent provides long term stability and is readily displaced by various other molecules including thiols, amines, polymers, antibodies, and proteins.
Silver Nanoparticle Applications
Silver nanoparticles are being used in numerous technologies and incorporated into a wide array of consumer products that take advantage of their desirable optical, conductive, and antibacterial properties.
  • Diagnostic Applications: Silver nanoparticles are used in biosensors and numerous assays where the silver nanoparticle materials can be used as biological tags for quantitative detection.
  • Antibacterial Applications: Silver nanoparticles are incorporated in apparel, footwear, paints, wound dressings, appliances, cosmetics, and plastics for their antibacterial properties.
  • Conductive Applications: Silver nanoparticles are used in conductive inks and integrated into composites to enhance thermal and electrical conductivity.
  • Optical Applications: Silver nanoparticles are used to efficiently harvest light and for enhanced optical spectroscopies including metal-enhanced fluorescence (MEF) and surface-enhanced Raman scattering (SERS).
Silver Nanoparticles for Nanotoxicology Research
There is growing interest in understanding the relationship between the physical and chemical properties of nanomaterials and their potential risk to the environment and human health. The availability of panels of nanoparticles where the size, shape, and surface of the nanoparticles are precisely controlled allows for the better correlation of nanoparticle properties to their toxicological effects. Sets of monodisperse, unaggregated, nanoparticles with precisely defined physical and chemical characteristics provide researchers with materials that can be used to understand how nanoparticles interact with biological systems and the environment.
Due to the increasing prevalence of silver nanoparticles in consumer products, there is a large international effort underway to verify silver nanoparticle safety and to understand the mechanism of action for antimicrobial effects. Colloidal silver has been consumed for decades for its perceived health benefits1 but detailed studies on its effect on the environment have just begun. Initial studies have demonstrated that effects on cells and microbes are primarily due to a low level of silver ion release from the nanoparticle surface.2 The ion release rate is a function of the nanoparticle size (smaller particles have a faster release rate), the temperature (higher temperatures accelerate dissolution), and exposure to oxygen, sulfur, and light. In all studies to date, silver nanoparticle toxicity is much less than the equivalent mass loading of silver salts.
Silver Nanowires
Silver nanowires are an exciting class of silver nanoparticles which have been studied as possible components in many advanced technology applications.

Applications include:
  • Conductive Coatings: Silver nanowires can be used to provide conductive coatings for transparent conductors and flexible electronics.
  • Plasmonic Antennas: Metallic nanoparticles attached to silver nanowires function as antennas enhancing plasmonic activity for sensing and imaging applications
  • Molecular Sensing: Single layers of silver nanowires have been used to construct arrays for molecule specific sensing in conjunction with Raman Spectroscopy.
  • Nanocomposites: Silver nanowires have been studied as components of nanocomposites and can show high dielectric constants in such systems.
The unique properties of silver nanoparticles make them ideal for numerous technologies, including biomedical, materials, optical, and antimicrobial applications, as well as for use in nanotoxicology studies. Aldrich Materials Science offers a variety of silver nanoparticles including: 10 nm, 20 nm, 40 nm, 60 nm, and 100 nm in diameter with a citrate-stabilized surface at concentrations of 0.02 mg/mL. A correlation of mass concentration to number concentration can be found below in Table 1
For a full list of Ag nanoparticles and nanoparticle dispersions, please visit our Online Product Catalog.
Table 1: Correlation between nanoparticle diameter, mass concentration, and number concentration.
Nanoparticle DiameterMass ConcentrationNumber concentration
10 nm0.02 mg/mL3.6x1012
20 nm0.02 mg/mL4.5x1011
40 nm0.02 mg/mL5.7x1010
60 nm0.02 mg/mL1.7x1010
100 nm0.02 mg/mL3.6x109



Popular posts from this blog

Hidden Wiki

Welcome to The Hidden WikiNew hidden wiki url 2015 http://zqktlwi4fecvo6ri.onion Add it to bookmarks and spread it!!!
Editor's picks Bored? Pick a random page from the article index and replace one of these slots with it.
The Matrix - Very nice to read. How to Exit the Matrix - Learn how to Protect yourself and your rights, online and off. Verifying PGP signatures - A short and simple how-to guide. In Praise Of Hawala - Anonymous informal value transfer system. Volunteer Here are five different things that you can help us out with.
Plunder other hidden service lists for links and place them here! File the SnapBBSIndex links wherever they go. Set external links to HTTPS where available, good certificate, and same content. Care to start recording onionland's history? Check out Onionland's Museum Perform Dead Services Duties. Introduction - Clearnet search engine for Tor Hidden Services (allows you to add new sites to its database). DuckDuckGo - A Hidden S…


Good News [May 08, 2015]: IDM developers got smarter, but the crackers are always a step ahead. Follow this article and send an email to if you are desperate. I can NOT post any crack here for legal reasons. Happy Downloading with IDM. ;) *********** first tip is to use latest crack for idm from idm universal web crack and make sure u are using all latest vers I am sure many of us are too much dependent on Internet Download Manager a.k.a. IDM. The main reason didn’t permanently switch to linux was IDM. I mainly use it for batch downloading and download streaming videos. Till yesterday, IDM was working fine with me (of course with fake serial numbers, keygen, crack, patch etc. which could be found with little effort). But few days ago, with the latest update version 6.18 build 7 (released on Nov 09, 2013) Internet Download Manager was literally had a breakthrough and crushed all the serial numbers, …

DoubleAgent Attack Turns Your Antivirus Into Malware And Hijacks Your PC

Short Bytes: Cybellum security researchers have uncovered a new attack mechanism that can be used to take control of your antivirus and turn it into a malware. Called DoubleAgent, this attack exploits an old and undocumented vulnerability in Windows operating system. This Zero Day code injection technique affects all major antivirus vendors and has the power to hijack permissions. The security researchers from Cybellum have found a new technique that can be used by the cybercriminals to hijack your computer by injecting malicious code. This new Zero-Day attack can be used to take full control over all the major antivirus software. Instead of hiding from the antivirus, this attack takes control of the antivirus itself. Called DoubleAgent, this attack makes use of a 15-year-old legitimate feature of Windows (read vulnerability)–that’s why it can’t be patched. It affects all versions of Microsoft Windows. Cybellum blog mentions that this flaw is still unpatched by most antivirus v…