This work is carried out as part of the COMMON SENSE European FP7 project. The COMMON SENSE project aims to provide a reliable sensing platform for in-situ measurements on key marine water quality parameters relating to eutrophication, heavy metal contaminants, marine litter and underwater noise. The COMMON SENSE nutrient sensor is based on a combination of microfluidic analytical systems, colorimetric reagent chemistry, low-cost LED-based optical detection, and wireless communications. 



The reliable quantification of nutrients in marine environments is challenging due to the low concentration of these solutes in the ocean and the nature of the matrix in which they are held. Initial studies are focussed on validating a method for the sequential determination of nitrite and nitrate in marine environments. Coupled with the traditional well established Griess–Ilosvay reaction for the determination of nitrite, a vanadium chloride (VCl3) solution is used as the reducing agent. The method shows potential as an alternative to the toxic cadmium column for the reduction of NO3- to NO2- in marine water as results indicate that there are no apparent interferences from variances in salinity. The method was tested on a series of samples with varying salinities and sample matrices (costal, estuarine and freshwater), the method is low cost, reproducible and requires low volumes of sample and reagents

Diamond, Dermot

McCaul, Margaret

McNamara, Eoghan

This work is carried out as part of the COMMON SENSE European FP7 project. The COMMON SENSE project aims to provide a reliable sensing platform for in-situ measurements on key marine water quality parameters relating to eutrophication, heavy metal contaminants, marine litter and underwater noise. The COMMON SENSE nutrient sensor is based on a combination of microfluidic analytical systems, colorimetric reagent chemistry, low-cost LED-based optical detection, and wireless communications. \ud
\ud
The reliable quantification of nutrients in marine environments is challenging due to the low concentration of these solutes in the ocean and the nature of the matrix in which they are held. Initial studies are focussed on validating a method for the sequential determination of nitrite and nitrate in marine environments. Coupled with the traditional well established Griess–Ilosvay reaction for the determination of nitrite, a vanadium chloride (VCl3) solution is used as the reducing agent. The method shows potential as an alternative to the toxic cadmium column for the reduction of NO3- to NO2- in marine water as results indicate that there are no apparent interferences from variances in salinity. The method was tested on a series of samples with varying salinities and sample matrices (costal, estuarine and freshwater), the method is low cost, reproducible and requires low volumes of sample and reagents

Name not available

Development	  of	  cost	  eﬀec/ve	  sensors	  for	  the	  in-­‐situ	  monitoring	  of	  Eutrophica/on	  	  	  Margaret	  McCaul,	  Eoghan	  McNamara,	  and	  Dermot	  Diamond	  Pi>con,	  New	  Orleans,	  2015	  	  	  Wavelength (nm) Absorbance 540 (nm) Project	  Overview	  	  Title:	  	  Cost-­‐eﬀec/ve	  sensors,	  interoperable	  with	  interna/onal	  exis/ng	  ocean	  observing	  systems,	  to	  meet	  EU	  policies	  requirements	  	  Total	  Budget: 	  €6,074,497	  	  Dura/on:	   	  40	  months	  	  Consor/um: 	  15	  partners	  from	  seven	  diﬀerent	  countries	  	  	  (the	  COMMON	  SENSE	  consor/um	  comprises	  six	  SMEs,	  ﬁve	  research	  development	  ins/tutes,	  three	  universi/es	  and	  one	  founda/on)	  	  	  	  	  Wavelength (nm) Absorbance 540 (nm) Consor/um	  Overview	  	  	  	  Under	   the	  Marine	   Strategy	   Framework	  Direc/ve	   (MSFD),	   EU	  Member	   States	   are	  expected	   to	   assess	   the	  overall	   status	   of	   their	  marine	   environments	   and	   to	  put	   in	  place	   the	   necessary	   measures	   to	   achieve	   Good	   Environmental	   Status	   (GES)	   by	  2020.	   Member	   States	   must	   implement	   cost-­‐eﬀec/ve	   monitoring	   programmes	   in	  order	  to	  achieve	  MSFD	  monitoring	  objec/ves,	  as	  well	  as	  other	  European	  mari/me	  and	  environmental	  policies	  such	  as	  the	  Common	  Fisheries	  Policy	  (CFP).	  COMMONSENSE	  and	  the	  Marine	  Framework	  direc/ve	  	  EU	  policies	  	  	  What	  will	  the	  COMMON	  SENSE	  project	  do:	  	  Develop	   innova+ve,	   cost-­‐eﬀec+ve	   sensors	   that	   will	   increase	   the	   availability	   of	  standardised	  data	  on:	  	  •  Eutrophica/on	  •  Concentra/ons	  of	  heavy	  metals;	  	  •  Micro-­‐plas/c	  frac/on	  within	  marine	  li>er;	  	  •  Underwater	  noise	  •  Parameters	  such	  as	  temperature	  and	  pressure.	  	  Sensors	  will	  assess	  environmental	  condi+ons	  aﬀec+ng	  marine	  ecosystems:	  	  	  •  Mi/ga/ng	  the	  anthropogenic	  impacts	  •  Climate	  change	  impacts	  	  •  Promo/ng	  basic	  research	  of	  marine	  science	  	  Elevated	  levels	  of	  nutrients	  causes	  Eutrophica+on	  which	  is	  an	  extensive	  problem	  within	  European	  marine	  waters	  (Bal+c	  and	  Mediterranean	  Seas)	  Impacts	  include:	  •  Increased	  biomass	  of	  phytoplankton	  and	  algae	  •  Forma/on	  of	  harmful	  algal	  blooms	  (HAB)	  •  Reduced	  water	  clarity	  •  Elevated	  pH	  and	  dissolved	  oxygen	  deple/on	  in	  the	  water	  colum	  •  Increased	  likelihood	  of	  kills	  of	  recrea/onally	  and	  commercially	  important	  species	  	  	  	  	  Nutrients	  in	  Marine	  Environments	  	  Descriptor	  5	  of	  the	  Marine	  Strategy	  Framework	  Direc+ve	  addresses	  Eutrophica+on:	  •  5.1.1	  Nutrient	  concentra/on	  in	  the	  water	  column	  •  5.1.2	  Nutrient	  ra/os	  Develop	  Sensors	  for	  nutrients	  (nitrite,	  nitrate,	  phosphate	  and	  ammonia)	  	  based	  on:	  	  •  Colorimetric	  chemical	  assays	  •  LED-­‐based	  op/cal	  detectors	  •  Microﬂuidic	  analy/cal	  systems	  •  Wireless	  communica/ons	  	  Phosphate	  sensors	  has	  been	  developed	  within	  DCU	  and	  validated	  in	  freshwater,	  wastewater	  deployments	  	  Marinisa+on	  of	  exis+ng	  sensors	  	  Sensor	  Development	  	  Colorimetric	  chemistries	  development	  and	  op/minsa/on	    Advantages:	  	  • One	  reagent	  solu/on	  added	  for	  Total	  N	  determina/on	  • No	  apparent	  interferences	  from	  	  Marine	  Matrix	  	  	  • Low	  detec/on	  limit	  (1µM	  Nitrate	  0.05µM	  Nitrite)	  • Uses	  small	  volumes	  (µL)	  Disadvantages: • Reac/on	  /me	  temperature	  dependant	  •  Nitrite	  determina/on	  using	  Griess	  Reagent	  	  •  Nitrate	  	  determina/on	  using	  	  Vanadium	  Chloride	  (VCl3)	  as	  reduc/on	  reagent.	  Methods	  adapted	  from	  García-­‐Robledo	  et	  al1	  and	  Schnetger	  B	  et	  al2.	   Nitrite & Nitrate Colorimetric	  Chemistries	  1. García-­‐Robledo	  E,	  Corzo	  A,	  Papaspyrou	  S.	  A	  fast	  and	  direct	  spectrophotometric	  method	  for	  the	  sequen/al	  determina/on	  of	  nitrate	  and	  nitrite	  at	  low	  concentra/ons	  in	  small	  volumes.	  Mar	  Chem	  2014;162:30-­‐6.	  2. Schnetger	  B,	  Lehners	  C.	  Determina/on	  of	  nitrate	  plus	  nitrite	  in	  small	  volume	  marine	  water	  samples	  using	  vanadium(III)chloride	  as	  a	  reduc/on	  agent.	  Mar	  Chem	  2014	  3/20;160:91-­‐8.	  0.0000	  0.2000	  0.4000	  0.6000	  0.8000	  1.0000	  1.2000	  400.0	   450.0	   500.0	   550.0	   600.0	   650.0	   700.0	  Wavelength	  (nm)	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  	  Absorbance	  1.5	  μM	  1.0	  μM	  0.5	  μM	  0.05μM	  545nm	  y	  =	  0.7098x	  R²	  =	  0.99244	  0	  0.2	  0.4	  0.6	  0.8	  1	  1.2	  1.4	  1.6	  0	   0.5	   1	   1.5	   2	   2.5	  Absorbance	  Concentra/on	  (μM)	  •  Wavelength	  scan	  from	  400	  nm	  to	  700	  nm.	  •  Maximum	  absorbance	  was	  observed	  at	  545	  nm	  	  	  •  Linear	  range	  from	  0.05	  to	  1.5μM	  .	  	  •  Linear	   response	   for	   nitrite	   analysis	   in	   ar/ﬁcial	   sea	  water.	   Reac/ons	   were	   carried	   out	   at	   ambient	  temperature	  (approximately	  25°C).	  •  This	  experiment	  was	  carried	  out	   in	   triplicate	  error	  bars	  minimal	  	  •  Standard	  Devia/on	  <0.001	  Nitrite	  analysis	  in	  salt	  water	  matrix	  1.0	   2.0	   5.0	   10.0	   20.0	   100.0	  •  Ar/ﬁcial	  Seawater	  was	  spiked	  with	  known	  concentra/ons	  of	  Nitrate	  	  	  •  Analysis	  carried	  out	  in	  triplicate	  •  Standard	  Devia/on	  <0.001	  Nitrate	  analysis	  in	  salt	  water	  matrix	  	  	  	  	  •  Maximum	  absorbance	  approx	  545	  nm	  •  Linear	  range	  from	  1-­‐20	  μM	  	  	  	  y	  =	  0.075x	  -­‐	  0.0585	  R²	  =	  0.99705	  0	  0.2	  0.4	  0.6	  0.8	  1	  1.2	  1.4	  1.6	  0	   5	   10	   15	   20	   25	  Absorbance	  Concentra/on	  (μM)	  	  y	  =	  0.3391x	  +	  0.0107	  R²	  =	  0.99253	  y	  =	  0.3421x	  +	  0.0129	  R²	  =	  0.99121	  y	  =	  0.3534x	  +	  0.0107	  R²	  =	  0.9925	  y	  =	  0.3422x	  +	  0.02	  R²	  =	  0.99674	  0	  0.2	  0.4	  0.6	  0.8	  1	  1.2	  0	   0.5	   1	   1.5	   2	   2.5	   3	   3.5	  Absorbance	  Concentra/on	  (μM)	  	  Nitrate	  Analysis	  	  	  Chamber	  A,	  545	  nm	  Chamber	  B,	  545	  nm	  Chamber	  C,	  545	  nm	  UV-­‐Vis,	  545nm	  Linear	  (Chamber	  A,	  545	  nm)	  Linear	  (Chamber	  B,	  545	  nm)	  Linear	  (Chamber	  C,	  545	  nm)	  Linear	  (UV-­‐Vis,	  545nm)	  In-­‐house	  developed	  bench	  top	  system	  calibra/on	  	  Fluidic	  system	  	  Fig. 6. A rendered image of the concept behind the dynamic flow measurement set up. This dynamic measurement will be performed in a microfluidic chip housed in the system shown in Fig. 4. A	   rendered	   image	   of	   the	  concept	   behind	   the	   dynamic	  ﬂow	   measurement	   set	   up.	  This	   dynamic	   measurement	  wil l	   be	   performed	   in	   a	  microﬂuidic	  chip. On	  going	  and	  Future	  Work	  Assays	  Ammonia	  	  (Berthelot	  reac/on),	  Phosphate	  (Yellow	  or	  Blue	  method)	  	  	  	  System	  development	  •  Miniaturisa/on	  •  Microﬂuidics	  •  Fluidic	  handling	  	  •  Power	  	  	  •  Analysis	  •  Harves/ng	  	  	  	  •  Detec/on	  limit	  •  Detectable	  range	  	  •  Accuracy	  	  	  Acknowledgements	  	  Adap/ve	  Sensors	  Group	  	  	  	  The	  COMMONSENSE	  consor/um	  	  The	   authors	   would	   also	   like	   to	   acknowledge	   funding	   from	   the	   European	  Union’s	   Seventh	   Framework	   Programme	   for	   research,	   technological	  development	  and	  demonstra/on	  under	  Grant	  Agreement	  No	  614155	  Thank	  you	  for	  your	  A>en/on	  margaret.mccaul@dcu.ie	  eoghan.mcnamara@dcu.ie	  dermot.diamond@dcu.ie	  	  	  	  www.commonsense	  project.eu	  

Development of cost effective sensors for the in-situ monitoring of eutrophication

DCU Online Research Access Service

This work is carried out as part of the COMMON SENSE European FP7 project. The COMMON SENSE project aims to provide a reliable sensing platform for in-situ measurements on key marine water quality parameters relating to eutrophication, heavy metal contaminants, marine litter and underwater noise. The COMMON SENSE nutrient sensor is based on a combination of microfluidic analytical systems, colorimetric reagent chemistry, low-cost LED-based optical detection, and wireless communications. 

The reliable quantification of nutrients in marine environments is challenging due to the low concentration of these solutes in the ocean and the nature of the matrix in which they are held. Initial studies are focussed on validating a method for the sequential determination of nitrite and nitrate in marine environments. Coupled with the traditional well established Griess–Ilosvay reaction for the determination of nitrite, a vanadium chloride (VCl3) solution is used as the reducing agent. The method shows potential as an alternative to the toxic cadmium column for the reduction of NO3- to NO2- in marine water as results indicate that there are no apparent interferences from variances in salinity. The method was tested on a series of samples with varying salinities and sample matrices (costal, estuarine and freshwater), the method is low cost, reproducible and requires low volumes of sample and reagents

Irish Universities

http://doras.dcu.ie/20630/1/Pittcon_Presentation_March_2015.pdf

Development of cost effective sensors for the in-situ monitoring of eutrophication

Abstract

Similar works

Full text

Available Versions

Name not available

DCU Online Research Access Service

Irish Universities