demo/fluorescence_enhancement.r

## ----load, echo=FALSE,results='hide', message=FALSE--------------------------
library(knitr)
library(planar)
library(dielectric)
library(ggplot2)
require(reshape2)
require(plyr)
opts_chunk$set(fig.path="fluorescenceenhancement/", 
               warning=FALSE,error=FALSE,message=FALSE,tidy=FALSE)
library(ggplot2)
theme_set(theme_minimal() + theme(panel.border=element_rect(fill=NA)))


## ----setup, results='hide'----------------------------------------------------
## from left to right
## incident glass | metal | water
## local field enhancement for the excitation of the fluorophore

model <- function(d=seq(1,10),
                  lambdaex=632.8,
                  shift=1000,
                  thetaex=seq(50,55)*pi/180,
                  thetafluo=thetaex,
                  nPrism = 1.766,
                  nWater = 1.33,
                  material = "silver",
                  polarisation="p",
                  thickness = c(0, 50, 0),
                  Nquadrature1 = 200, Nquadrature2 = 500,
                  Nquadrature3 = 500,
                  qcut = NULL, rel.err= 1e-1,
                  GL=TRUE){
  
  lambdafluo <- as.vector(raman_shift(lambdaex, shift))
  
  epsilon.ex <- if(material == "silver") epsAg(lambdaex)$epsilon else epsAu(lambdaex)$epsilon 
  epsilon.fluo <- if(material == "silver") epsAg(lambdafluo)$epsilon else epsAu(lambdafluo)$epsilon 

  Mex <- multilayer(wavelength = lambdaex, angle = thetaex, polarisation = polarisation,  
                    thickness = thickness, d = d,
                    epsilon = list(nPrism^2, epsilon.ex, nWater^2))
  
  Mfluo <- multilayer(wavelength = lambdafluo, angle = thetafluo,
                      polarisation = polarisation,  
                      thickness = thickness, d=d,
                      epsilon = list(nPrism^2, epsilon.fluo, nWater^2))
  
  params <- list(wavelength = lambdafluo,
                 epsilon = list(nWater^2, epsilon.fluo, nPrism^2), # reversed order
                 thickness = thickness, 
                 Nquadrature1 = Nquadrature1, Nquadrature2 = Nquadrature2,
                 Nquadrature3 = Nquadrature3, qcut = qcut, rel.err=rel.err,  GL=GL)
  
  Mtot <-   sapply(d, function(.d){
    dl <- do.call(dipole, c(params, list(d=.d, show.messages = FALSE)))
  }, simplify=TRUE)
  
  ## incident left -> glass | metal | water
  last <- length(Mex$Mr.perp)
  Mex.perp <-  Mex$Mr.perp[[last]]
  Mfluo.perp <-  Mfluo$Mr.perp[[last]]
  Mex.par <-  Mex$Mr.par[[last]]
  Mfluo.par <-  Mfluo$Mr.par[[last]]
  
  Mtot.perp <- matrix(unlist(Mtot["Mtot.perp",]),
                      nrow=NROW(Mex.perp), ncol=NCOL(Mex.perp), byrow=TRUE)
  Mtot.par <- matrix(unlist(Mtot["Mtot.par",]),
                     nrow=NROW(Mex.perp), ncol=NCOL(Mex.perp), byrow=TRUE)
  
  d <- data.frame(d=rep(d, each=length(thetaex)),
                  thetaex=rep(thetaex, length(d)),
                  Mex.perp = c(Mex.perp),
                  Mex.par = c(Mex.par),
                  Mfluo.perp = c(Mfluo.perp),
                  Mfluo.par =  c(Mfluo.par),
                  Mtot.perp = c(Mtot.perp),
                  Mtot.par = c(Mtot.par),
                  F.perp = c(Mex.perp * Mfluo.perp / Mtot.perp),
                  F.par = c(Mex.par * Mfluo.par / Mtot.par))
  
  
  m <- melt(d, id=c("d", "thetaex"))
  ## reorder the levels
  levels(m$variable) <- c("Mex.perp", "Mex.par", "Mfluo.perp", "Mfluo.par",
                          "Mtot.perp", "Mtot.par", "F.perp", "F.par")
  m$type <- factor(m$variable)
  levels(m$type) <- list("Mex"="Mex.perp", "Mfluo"="Mfluo.perp", "Mtot"="Mtot.perp",
                         "Mex"="Mex.par", "Mfluo"="Mfluo.par", "Mtot"="Mtot.par",
                         "F"="F.perp", "F"="F.par")
  m$orientation <- factor(m$variable)
  levels(m$orientation) <- list("perp"="Mex.perp", "perp"="Mfluo.perp", "perp"="Mtot.perp",
                                "par"="Mex.par", "par"="Mfluo.par", "par"="Mtot.par",
                                "perp"="F.perp", "par"="F.par")
  
  m
}


results <- model(d=seq(1,50, length=300), thetaex=53*pi/180,
                 thetafluo=52.3*pi/180,
                 Nquadrature1 = 15, Nquadrature2 = 135,
                 Nquadrature3 = 135, GL=TRUE)

m <- results
m$value[m$type == "Mtot" ] <- log10(m$value[m$type == "Mtot" ])

m$variable <- modify_levels(m$variable,
                            list("log.Mtot.perp"="Mtot.perp",
                                 "log.Mtot.par"="Mtot.par"))


qplot(d, value, data=m, geom="line", colour=I("blue")) +
  facet_wrap(~variable,scales="free", ncol=2,as.table=FALSE)+
  scale_x_continuous("distance /nm", expand=c(0,0), lim=c(0, max(results$d)))+
  scale_y_continuous("") + 
  geom_hline(yintercept=0) + theme_minimal() + 
  theme(panel.background=element_rect(fill=NA))



## ----angles, fig.width=10------------------------------------------------

results <- model(d=20, thetaex=seq(50, 55,length=300)*pi/180,
                 Nquadrature1 = 15, Nquadrature2 = 135,
                 Nquadrature3 = 135, GL=TRUE)

m <- subset(results, variable %in% c("Mex.perp", "Mfluo.perp"))

qplot(thetaex*180/pi, value, data=m, geom="line", colour=variable) +
  scale_x_continuous("Angle /degrees", expand=c(0,0))+
  scale_y_continuous("M") + 
  geom_hline(yintercept=0) + theme_minimal() + 
  theme(panel.background=element_rect(fill=NA))

results <- model(d=seq(1,300, length=300), 
                 thetaex=seq(51, 54, length=300)*pi/180,
                 thetafluo = 52.3*pi/180,
                 Nquadrature1 = 15, Nquadrature2 = 135,
                 Nquadrature3 = 135, GL=TRUE)

m <- subset(results, variable == "F.perp")
ggplot(m, aes(d, thetaex*180/pi, fill=value)) + geom_raster()+
  scale_x_continuous("distance /nm", expand=c(0,0), lim=c(0, max(results$d)))+
  scale_y_continuous("Incident angle /degrees", expand=c(0,0)) + 
  labs(fill=expression(F==Mex %*% Mfluo/ Mtot))

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planar documentation built on May 29, 2017, 4:26 p.m.