Solid state medium Molecular beams can be used to create nanocluster beams of virtually any element. They can be synthesized in high
vacuum by with molecular beam techniques combined with a mass spectrometer for mass selection, separation and analysis. And finally detected with detectors.
Cluster Sources Seeded supersonic nozzle Seeded supersonic nozzles are mostly used to create clusters of low-
boiling-point metal. In this source method metal is vaporized in a hot oven. The metal vapor is mixed with (seeded in) inert carrier gas. The vapor mixture is ejected into a vacuum chamber via a small hole, producing a supersonic
molecular beam. The expansion into vacuum proceeds
adiabatically cooling the vapor. The cooled metal vapor becomes
supersaturated, condensing in cluster form.
Gas aggregation Gas aggregation is mostly used to synthesize large clusters of nanoparticles. Metal is vaporized and introduced in a flow of cold inert gas, which causes the vapor to become highly supersaturated. Due to the low temperature of the inert gas, cluster production proceeds primarily by successive single-atom addition.
Laser vaporization Laser vaporization source can be used to create clusters of various size and polarity.
Pulse laser is used to vaporize the target metal rod and the rod is moved in a spiral so that a fresh area can be evaporated every time. The evaporated metal vapor is cooled by using cold
helium gas, which causes the cluster formation.
Pulsed arc cluster ion This is similar to laser vaporization, but an intense electric discharge is used to evaporate the target metal.
Ion sputtering Ion sputtering source produces an intense continuous beam of small singly ionized cluster of metals. Cluster ion beams are produced by bombarding the surface with high energetic inert gas (
krypton and
xenon) ions. The cluster production process is still not fully understood.
Liquid-metal ion In liquid-metal ion source a needle is wetted with the metal to be investigated. The metal is heated above the melting point and a potential difference is applied. A very high electric field at the tip of the needle causes a spray of small droplets to be emitted from the tip. Initially very hot and often multiply ionized droplets undergo evaporative cooling and fission to smaller clusters.
Mass Analyzer Wein filter In
Wien filter mass separation is done with crossed homogeneous electric and magnetic fields perpendicular to ionized cluster beam. The net force on a charged cluster with
mass M, charge
Q, and
velocity v vanishes if
E =
Bv/
c . The cluster ions are accelerated by a
voltage V to an energy
QV. Passing through the filter, clusters with
M/
Q = 2
V/(
Ec/
B) are not deflected. These cluster ions that are not deflected are selected with appropriately positioned
collimators.
Quadrupole mass filter The
quadrupole mass filter operates on the principle that ion
trajectories in a two-dimensional quadrupole field are stable if the field has an AC component superimposed on a DC component with appropriate
amplitudes and
frequencies. It is responsible for filtering sample ions based on their
mass-to-charge ratio.
Time of flight mass spectroscopy Time-of-flight spectroscopy consists of an
ion gun, a field-free
drift space and an ion cluster source. The neutral clusters are ionized, typically using pulsed laser or an
electron beam. The ion gun accelerates the ions that pass through the field-free drift space (flight tube) and ultimately impinge on an ion detector. Usually an
oscilloscope records the arrival time of the ions. The mass is calculated from the measured
time of flight.
Molecular beam chromatography In this method, cluster ions produced in a laser vaporized cluster source are mass selected and introduced in a long inert-gas-filled drift tube with an entrance and exit aperture. Since cluster mobility depends upon the
collision rate with the
inert gas, they are sensitive to the cluster shape and size.
Aqueous medium In general, metal nanoclusters in an aqueous medium are synthesized in two steps: reduction of metal ions to zero-valent state and stabilization of nanoclusters. Without stabilization, metal nanoclusters would strongly interact with each other and aggregate irreversibly to form larger particles.
Reduction There are several methods reported to reduce silver ion into zero-valent silver atoms: •
Chemical Reduction Chemical reductants can reduce silver ions into silver nanoclusters. Some examples of chemical reductants are
sodium borohydride (NaBH4) and
sodium hypophosphite (NaPO2H2.H2O). For instance, Dickson and his research team have synthesized silver nanoclusters in DNA using sodium borohydride.
DNA, proteins and peptides DNA
oligonucleotides are good templates for synthesizing metal nanoclusters. Silver ions possess a high affinity to
cytosine bases in single-stranded DNA which makes DNA a promising candidate for synthesizing small silver nanoclusters. The number of cytosines in the loop could tune the stability and fluorescence of Ag NCs. Biological
macromolecules such as
peptides and
proteins have also been utilized as templates for synthesizing highly fluorescent metal nanoclusters. Compared with short peptides, large and complicated proteins possess abundant binding sites that can potentially bind and further reduce metal
ions, thus offering better scaffolds for template-driven formation of small metal nanoclusters. Also the catalytic function of
enzymes can be combined with the fluorescence property of metal nanoclusters in a single cluster to make it possible to construct multi-functional nanoprobes. == Properties ==