Atomic force microscopy (AFM) was used to measure the chemical binding force of discrete electron donor-acceptor complexes formed at the interface between proximal self-assembled monolayers (
SAMs). Derivatives of the well-known electron donor N,N,N',N'-
tetramethylphenylenediamine (TMPD) and the electron acceptor
7,7,8,8-tetracyanoquinodimethane (
TCNQ) were immobilized on Au-coated AFM
tips and substrates by formation of
SAMs of N,N,N'-trimethyl-N'-(10-thiodecyl)-1,4-phenylenediamine (I) and bis(10-(2-((2,5-cyclohexadiene-1,4-diylidene)dimalonitrile))decyl)
disulfide (II), respectively. Pull-off forces between modified
tips and substrates were measured under CHCl(3)
solvent. The mean pull-off forces associated with TMPD/
TCNQ microcontacts were more than an order of magnitude larger than the pull-off forces for TMPD/TMPD and
TCNQ/
TCNQ microcontacts, consistent with the presence of specific charge-transfer interactions between proximal TMPD donors and
TCNQ acceptors. Furthermore, histograms of pull-off forces for TMPD/
TCNQ contacts displayed 70 +/- 15 pN periodicity, assigned to the
rupture of individual TMPD-
TCNQ donor-acceptor (charge-transfer) complexes. Both the mean pull-off force and the 70 pN force quantum compare favorably with a contact mechanics model that incorporates the effects of discrete chemical bonds,
solvent surface tensions, and random contact area variations in consecutive pull-offs. From the 70 pN force quantum, we estimate the
single bond energy to be approximately 4-5 kJ/mol, in reasonable agreement with thermodynamic data. These experiments establish that binding forces due to discrete chemical bonds can be detected directly in AFM pull-off measurements employing SAM modified probes and substrates. Because
SAMs can be prepared with a wide range of exposed functional groups, pull-off measurements between SAM-coated
tips and substrates may provide a general strategy for directly measuring binding forces associated with a variety of simple, discrete chemical bonds, e.g., single hydrogen bonds.