Supplemental Material Plasmonic Circular Dichroism of Peptide Functionalized Gold Nanoparticles Joseph M. Slocik, Alexander O. Govorov, and Rajesh R. Naik * Methods Nanoparticle functionalization. A peptide (1 µl,.1 M in deionized water) or coil peptide (1 µl,.1 M in deionized water) was added to 5 µl of 1 nm gold nanoparticles (1.14 x 1 1 particles/ml, Ted Pella) in double deionized water and incubated for hours. For removal of excess peptide, peptide coated particles were centrifuged at 14, rpm on an Eppendorf centrifuge 584 for 1 minutes and rinsed several times. The gold-peptide pellet was separated from supernatant and redissolved in 5 µl of deionized water. Nanoparticle assembly.. µl of AgNO or K PdCl 6 (.1 M in water) was added to 5 µl of peptide ( or ) coated gold nanoparticles and incubated for 15 minutes before CD characterization. The ph of the coil -gold nanoparticle solution was adjusted using NaOH or HCl to a ph of ~4 or 11. Characterization of peptide-nanoparticle interaction. CD spectra of the peptide-nanoparticle complexes was collected on a Jasco J-815 CD spectrometer using a quartz cuvette with a.5 cm pathlength from 7-19 nm at a scan rate of nm/min. Absorbance spectra were collected at the simultaneously during respective CD scans on Jasco J-815 CD spectrometer. For CD scans at variable temperatures, a single position peltier cell holder was used to control temperatures from 5 C to 85 C. Peptide coated gold particles were heated at 1 C intervals for 15 minutes before collecting CD spectra.
1 1 Transmittance 11 1 Au- peptide Transmittance 1 8 Au- peptide 6 9 4 5 5 15 1 5 Wavenumber (cm -1 ) 4 5 5 15 1 5 Wavenumber (cm -1 ) Figure S1. FT-IR spectra of free peptide and peptide coated gold nanoparticles for and peptides. Spectra were collected on a Perkin-Elmer FT-IR microscope and averaged over a 1 scans. Samples were prepared by depositing 1 µl of respective peptide or nanoparticle solution onto a double sided polished silicon wafer and air dried. 5 4 5 4 peptide Mass (ng/cm ) Mass (ng/cm ) 1 1 5 1 15 5 Time (sec) 5 1 15 5 Time (sec) Figure S. QCM binding plot of and coil peptides (5 µg/ml in deionized water) on a gold coated quartz crystal sensor (QSX-1, Q-Sense) at a flow rate of.17 ml/min using a Q- Sense E4 QCM-D system. The gold sensors were cleaned by UV ozone treatment for 1 minutes followed by heating in a 5:1:1 water/ammonia/h O solution for 1 minutes, and then thorough rinsing with deionized water. Mass was calculated using the third overtone frequency and Sauerbrey equation.
Ellipticity CD (mdeg) 1-1 - - 18 4 6 Abundance.6.5.4...1. Helix 1 Helix Turn PP Unord Figure S. (A) CD spectra of free peptide (8.6 µm in water) and peptide (5. µm in water) in a.5 cm path length quartz cuvette. (B) Analysis of secondary structure of (black) and (grey) using CDPro software. CD (mdeg) Ellipticity (mdeg) - -4-6 -8 peptide only 1 nm Au + purified 1 nm Au + crude -1-1 4 5 6 7 Figure S4. CD spectra of coated gold particles before and after excess peptide was removed. Excess peptide was removed by centrifugation at 14 rpm for 1 minutes, separation of gold pellet from supernatant, and dissolution in 5 µl of deionized water.
1 Au- + Pd 4+ 8 Absorption 6 4 4 6 8 Size (nm) Figure S5. Particle size distribution of Au- s and upon addition of Pd 4+ ions using CPS particle size analyzer. Calibrated against 77 nm polystyrene particles. 4 1. Ellipticity CD (mdeg) (mdeg) - -4 peptide peptide + Pd 4+ Absorbance 1..8.6.4. -6 4 5 6 7. 4 5 6 7 Figure S6. CD and absorbance spectra of peptide (8 µm) in water and after the addition of Pd 4+ ( µm) with a.5 cm pathlength.
Theoretical details. The plasmon-enhancement factor for a molecule in the vicinity of a metal nanoparticle is given by the matrix: β (1 ) R Px ˆ β P= Py (1 ) =, R P z β (1 + ) R where β = a ε ε ( ) ε + ε is the polarizability of nanoparticle. The system of coordinates is such that the center of molecular dipole is located at the z-axis coming through the metal nanoparticle center (Figure S6). Figure S7. Model and geometry of a system comprising a chiral molecule and metal nanoparticle.
The full equation for the CD signal for a spherical nanoparticle is given by [S1]: CDmolecule = CDmolecule + CD, 8 Γ1 ˆ r r CDmolecule = E εω Im ( P µ 1) m 1, CD ( hω hω + iγ G ) 1 ε a µ 1x m1x + µ 1 y m1y µ 1z m1z ω ε ε + ε ε R hω hω+ iγ1 Gω 8E = Im[ ] Im[ ], 9 r e r r m1 = [ p] 1, mc r r µ 1= e 1, ω where E is the amplitude of incident electromagnetic wave. The function G ω describes the broadening of the molecular resonance in the presence of a metal nanoparticle [S1]. The coefficient A used in the main text is 8E A=. 9 Extinctions in the standard units ( cm M 1 1 ) can be calculated from the above equations: π N 1 ε = ε + ε = + 4 A CD CD, molecule CD, molecule c. ε E ( CD CD ), where the CD absorption rates ( CD molecule and CD ) are now in the cgs units. In our calculations (Fig. 5 in the main text), we used typical parameters for the matrix elements µ 1 and m 1, resulting in a typical magnitude of molecular CD in the UV range. We also considered a particular case when an electric dipole moment of a molecule is normal to the nanoparticle surface.
[S1] Govorov, A. O.; Fan, Z.; Hernandez, P.; Slocik, J. M.; Naik, R. R. Nano Lett. 1, 1, 174-18.