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SCHEDULE 1

Regulation 3(6)
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SCHEDULE 1
PART 1
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Table 1Dissolved oxygen (percent saturation)
(10-percentile)
Column 1 Column 2 Column 3 Column 4 Column 5 Column 6
Type1 High Good Moderate Poor Bad
Upland and low alkalinity 80 75 64 50 < 50
Lowland and high alkalinity 70 60 54 45 < 45
1 Where a lowland, high alkalinity river is a salmonid river the standards for the upland, low alkalinity type will apply.

Table 2Total ammonia1(mg/l)
(90-percentile)
Column 1 Column 2 Column 3 Column 4 Column 5 Column 6
Type High Good Moderate Poor Bad
Upland and low alkalinity 0.2 0.3 0.75 1.1 > 1.1
Lowland and high alkalinity 0.3 0.6 1.1 2.5 > 2.5
1 Note that Ammonia is a Specific Pollutant and considered as such for compliance. It is included in this section as it is commonly assessed alongside the other inorganic chemistry elements.

Table 3Biochemical oxygen demand (mg/l)1
(90-percentile)
Column 1 Column 2 Column 3 Column 4 Column 5 Column 6
Type2 High Good Moderate Poor Bad
Upland and low alkalinity 3 4 6 7.5 > 7.5
Lowland and high alkalinity 4 5 6.5 9 > 9
1 The standard for Biochemical Oxygen Demand shall be used when deciding action to meet the standard for dissolved oxygen.
2 Where a lowland, high alkalinity river is a salmonid river the standards for the upland, low alkalinity type will apply.

Table 4Temperature (◦C) as an annual 98th percentile standard
Column 1 Column 2 Column 3 Column 4 Column 5
Type High Good Moderate Poor
Salmonid 20 23 28 30
Cyprinid 25 28 30 32

Table 5Permitted abstraction per day as a percentage of the natural mean daily flow(Q)1
High
Column 1 Column 2 Column 3
Maximum permitted % abstraction at Q exceeding Q952 Maximum permitted % abstraction at Q not exceeding Q95
A1, A2 (downstream), A2 (headwaters), B1, B2, C2, D2 10 5
1
                          ‘Q’ is the mean daily flow for a specified period of time
2
                          ‘Qx’ is the Q that is expected to be exceeded by  ‘x’ percent for a specified period of time

Table 6Permitted abstraction per day as a percentage of the natural mean daily flow(Q)
Good
Column 1 Column 2 Column 3 Column 4 Column 5
River type Maximum % abstraction at Q exceeding Q60 Maximum % abstraction at Q exceeding Q70 Maximum % abstraction at Q exceeding Q95 Maximum % abstraction at Q not exceeding Q95
A1 35 30 25 20
A2 (downstream), B1, B2 30 25 20 15
A2 (headwaters), C2, D2 25 20 15 10

Table 7Permitted abstraction per day as a percentage of the natural mean daily flow(Q)
Moderate
Column 1 Column 2 Column 3 Column 4 Column 5
River type Maximum % abstraction at Q exceeding Q60 Maximum % abstraction at Q exceeding Q90 Maximum % abstraction at Q exceeding Q95 Maximum % abstraction at Q not exceeding Q95
A1 70 50-701 50 45
A2 (downstream), B1, B2, 70 45-701 45 40
A2 (headwaters), C2, D2 70 40-701 40 35
1 incremental increase in allowable take at flows <Q60 to ≥ Q90

Table 8Permitted abstraction per day as a percentage of the natural mean daily flow(Q)
Poor
Column 1 Column 2 Column 3 Column 4 Column 5
River type Maximum % abstraction at Q exceeding Q60 Maximum % abstraction at Q exceeding Q90 Maximum % abstraction at Q exceeding Q95 Maximum % abstraction at Q not exceeding Q95
A1 Qx less 25% of Q90 Qx less 25% of Q90 75 70
A2 (downstream), B1, B2, Qx less 30% of Q90 Qx less 30% of Q90 70 65
A2 (headwaters), C2, D2 Qx less 35% of Q90 Qx less 35% of Q90 65 60

Table 9Status Mean in July – August (mg/l)
Salmonid Cyprinid
High 9 8
Good 7 6
Moderate 4 4
Poor 1 1
Bad < 1 < 1

Table 10Status Proposed Boundary
Annual Mean (micro Siemens per centimetre)
Good 1000

Table 11Annual mean concentration of total phosphorous (µg/l)
Column 1 Column 2 Column 3 Column 4 Column 5
High Good Moderate Poor Bad
R ÷ H; or 5, whichever is the larger value R ÷ G; or 8, whichever is the larger value (R ÷ G) ÷ 0.5 (R ÷ G) ÷ 0.25 > (R ÷ G) ÷ 0.25

Table 12Annual mean concentration of total phosphorus (µg/l)
Column 1 Column 2 Column 3 Column 4 Column 5 Column 6
Geological and depth category High Good Moderate Poor Bad
High alkalinity; shallow 16 23 46 92 > 92
High alkalinity; very shallow 23 31 62 124 > 124
Moderate alkalinity; deep 8 12 24 48 > 48
Moderate alkalinity; shallow 11 16 32 64 > 64
Moderate alkalinity; very shallow 15 22 44 88 > 88
Low alkalinity; deep 5 8 16 32 > 32
Low alkalinity; shallow 7 10 20 40 > 40
Low alkalinity; very shallow 9 14 28 56 > 56
Marl; shallow 9 20 40 80 > 80
Marl; very shallow 10 24 48 96 > 96

Table 13Daily maximum % reduction in the habitable zone lake surface area for 99% of the days in any year
Column 1 Column 2 Column 3 Column 4
High Good Moderate Poor
1 5 10 20

The habitable zone lake surface is dependent on whether the lake is considered to have the geological sub-type  “Peat” or  “Non-Peat”.
The habitable zone lake surface area means the proportion of the reference conditions1 lake surface area from the shore to a depth 5 metres deeper than the depth to which light penetration to the lake bed would be sufficient to enable the growth of rooted plants (macrophytes) or bottom-living algae.
In the absence of field data to the contrary, the depth to which light penetration to the lake bed is sufficient to enable the growth of rooted plants (macrophytes) or bottom-living algae may be taken to be 2 metres for lakes with the geological sub-type of  “Peat” and 7 metres for  “Non-Peat” lakes. The lake habitable zone extends 5m below the level of light penetration to account for impacts on the aphotic habitat.

1 The reference conditions lake surface area means the natural lake surface area in the absence of any abstractions, discharges or other man-made influences

Table 14 Dissolved oxygen concentrations (mg/l) as 5-percentile values
High 5.7
Good 4.0
Moderate 2.4
Poor 1.6
Bad <1.6

Table 15 Dissolved oxygen concentrations (mg/l) as 5-percentile values
High ≥5.7
Good ≥4.0 and <5.7
Moderate ≥2.4 and <4.0
Poor ≥1.6 and <2.4
Bad <1.6

Table 16 Mean dissolved inorganic nitrogen concentration (micromoles per litre) during the period 1st December to 28th February
High 12
Good 18
Moderate 30
Poor 40.5
Bad >40.5

Table 17Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 21 Column 3 Column 41
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.3 1.3 0.3 1.3
1 The standards for 2,4 D specified in Column 2 and Column 4 must not be used for the purpose of classifying the ecological status or potential of bodies of surface water.

Table 18Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
4.2 140 0.42 6

Table 19Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.2 5.4 0.2 5.4

Table 20Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 11 Column 21
Annual mean (µg/l) Annual mean (µg/l)
50 25
1 The standard for arsenic refers to the dissolved fraction of a water sample obtained by filtration through a 0.45µm filter or any equivalent pre-treatment

Table 21
Good standard for rivers and freshwater lakes
 Good standard for transitional and coastal waters
Column 1 Column 2 Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
7.5 51 0.75 10

Table 22Good standards for rivers and freshwater lakes
Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l)
0.15 0.7

Table 23Good standards for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 1 Column 21 Column 31
Annual mean concentration (µg/l) of total available chlorine 95-percentile concentration (µg/l) of total available chlorine 95-percentile concentration (µg/l) of total residual oxidant2
2 5 10
1 The standards for chlorine specified in Column 2 and 3 must not be used for the purpose of classifying the ecological status or potential of bodies of surface water.
2 The term  “total residual oxidants” refers to the sum of all oxidising agents existing in water, expressed as available chlorine.

Table 24Good standards for rivers and freshwater lakes
Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l)
0.035 1.2

Table 25Good standard for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 31
Annual mean concentration (µg/l) of dissolved chromium VI Annual mean concentration (µg/l) of dissolved chromium VI 95-percentile concentration (µg/l) of dissolved chromium VI
3.4 0.6 32
1 The standard for chromium VI specified in column 3 must not be used for the purpose of classifying the ecological status or potential of bodies of surface water.

Table 26Good standards for rivers and freshwater lakes
Column 1 Column 21
Annual mean concentration (µg/l) of dissolved chromium III 95-percentile concentration (µg/l) of dissolved chromium III
4.7 32
1 The standard for chromium III specified in column 2 must not be used for the purpose of classifying the ecological status or potential of bodies of surface water

Table 27Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters2
Column 1 Column 2
Annual mean concentration (µg/l) of dissolved copper Annual mean concentration (µg/l) of dissolved copper
1(bioavailable)1 3.76 µg/l dissolved, where DOC3 ≤ 1 mg/l
3.76 +(2.677 × ((DOC/2) - 0.5)) µg/l dissolved, where DOC > 1 mg/l
1 bioavailable means the fraction of the dissolved concentration of copper likely to result in toxic effects as determined using the Metal Bioavailability Assessment Tool (also referred to as a PNEC Estimator) for copper.
2 The recommended salt water standard applies to the fraction of a water sample that passes through a 0.45-µm filter or that is obtained by any equivalent pre-treatment.
3
                          “DOC” means the annual mean concentration of dissolved organic carbon in mg/l.

Table 28Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 21 Column 3 Column 41
Annual mean concentration (µg/l) of  ‘free’ cyanide (HCN and CN) 95-percentile concentration (µg/l) of  ‘free’cyanide (HCN and CN) Annual mean concentration (µg/l) of hydrogen cyanide 95-percentile concentration (µg/l) of hydrogen cyanide
1 5 1 5
1 The standards for cyanide specified in column 2 and column 4 must not be used for the purpose of classifying the ecological status or potential of bodies of surface water.

Table 29Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (ng/l) 0.1 Annual mean (ng/l) 0.1
95-percentile (ng/l) 0.4 95-percentile (ng/l) 0.41

Table 30Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.01 0.02 0.01 0.26

Table 31Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.48 4.0 0.48 4.0

Table 32Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
196 398 196 398

Table 33Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 1 Column 2
Annual mean concentration (mg/l) of dissolved iron Annual mean concentration (mg/l) of dissolved iron
1 1

Table 34Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.5 0.9 0.5 0.9

Table 35Good standard for rivers and freshwater lakes
Annual mean (µg/l) bioavailable
1231
1 bioavailable means the fraction of the dissolved concentration of manganese likely to result in toxic effects as determined in accordance with the Metal Bioavailability Assessment Tool for manganese.

Table 36Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
18 187 18 187

Table 37Good standards for rivers and freshwater lakes
Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l)
0.01 0.77

Table 38Good standards for rivers and freshwater lakes
Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l)
0.3 0.58

Table 39Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.001 0.01 0.0002 0.001

Table 40Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
7.7 46 7.7 46

Table 41Good standards for rivers and freshwater lakes
Column 1 Column 2
Annual mean (µg/l) 95-percentile (µg/l)
140 1848

Table 42Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
74 380 74 370

Table 43Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2 Column 3 Column 4
Annual mean (µg/l) 95-percentile (µg/l) Annual mean (µg/l) 95-percentile (µg/l)
0.1 0.28 0.1 0.28

Table 44Good standard for rivers and freshwater lakes Good standard for transitional and coastal waters
Annual mean (µg/l) Annual mean (µg/l)
Not applicable 21

Table 45Good standards for rivers and freshwater lakes Good standards for transitional and coastal waters
Column 1 Column 2
Annual mean Annual mean
10.9 bioavailable1 plus Ambient Background Concentration2 (µg/l) dissolved 6.8 dissolved plus Ambient Background Concentration (µg/l)
1 bioavailable means the fraction of the dissolved concentration of zinc likely to result in toxic effects as determined using the Metal Bioavailability Assessment Tool (also referred to as a PNEC Estimator) for zinc.
2 Ambient Background Concentration is an estimate of background levels of zinc based on a low percentile of monitoring data. A figure of 1 µg/l has been estimated for freshwaters in Northern Ireland.

Table 46Name of substance Chemical Abstracts Service number All rivers and lakes All transitional and coastal waters
Good Good
Annual mean1 (AA-EQS) (µg/l) Maximum allowable concentration2 (MAC-EQS) (µg/l) Annual mean1 (AA-EQS) (µg/l) Maximum allowable concentration2 (MAC-EQS) (µg/l)
Alachlor 15972-60-8 0.3 0.7 0.3 0.7
Anthracene 120-12-7 0.1 0.4 0.1 0.4
Atrazine 1912-24-9 0.6 2.0 0.6 2.0
Benzene 71-43-2 10 50 8 50
Brominated diphenylether3 32534-81-9 0.0005 not applicable 0.0002 not applicable
Cadmium and its compounds (depending on water hardness classes)4 7440-43-9 
≤ 0.08
(class 1)
 
≤ 0.45
(class 1)
 0.2 
≤ 0.45
(class 1)


0.08
(class 2)
 
0.45
(class 2)
 
0.45
(class 2)


0.09
(class 3)
 
0.6
(class 3)
 
0.6
(class 3)


0.15
(class 4)
 
0.9
(class 4)
 
0.9
(class 4)


0.25
(class 5)
 
1.5
(class 5)
 
1.5
(class 5)

Carbon-tetrachloride 56-23-5 12 not applicable 12 not applicable
C10-13 Chloroalkanes 85535-84-8 0.4 1.4 0.4 1.4
Chlorfenvinphos 470-90-6 0.1 0.3 0.1 0.3
Chlorpyrifos (Chlorpyrifos-ethyl) 2921-88-2 0.03 0.1 0.03 0.1
Cyclodiene pesticides:     
Aldrin 309-00-2 Σ=0.01 not applicable Σ=0.005 not applicable
Dieldrin 60-57-1
Endrin 72-20-8
Isodrin 465-73-6
DDT total5 not applicable 0.025 not applicable 0.025 not applicable
Para-para-DDT 50-29-3 0.01 not applicable 0.01 not applicable
1,2-Dichloroethane 107-06-2 10 not applicable 10 not applicable
Dichloromethane 75-09-2 20 not applicable 20 not applicable
Di(2-ethylhexyl)-phthalate (DEHP) 117-81-7 1.3 not applicable 1.3 not applicable
Diuron 330-54-1 0.2 1.8 0.2 1.8
Endosulfan 115-29-7 0.005 0.01 0.0005 0.004
Fluoranthene 206-44-0 0.1 1 0.1 1
Hexachloro-benzene 118-74-1 0.016 0.05 0.016 0.05
Hexachloro-butadiene 87-68-3 0.16 0.6 0.16 0.6
Hexachloro-cyclohexane 608-73-1 0.02 0.04 0.002 0.02
Isoproturon 34123-59-6 0.3 1.0 0.3 1.0
Lead and its compounds 7439-92-1 7.2 not applicable 7.2 not applicable
Mercury and its compounds 7439-97-6 0.056 0.07 0.056 0.07
Naphthalene 91-20-3 2.4 not applicable 1.2 not applicable
Nickel and its compounds 7440-02-0 20 not applicable 20 not applicable
Nonylphenol (4-Nonylphenol) 104-40-5 0.3 2.0 0.3 2.0
Octylphenol ((4-(1,1',3,3'-tetramethylbutyl)-phenol)) 140-66-9 0.1 not applicable 0.01 not applicable
Pentachloro-benzene 608-93-5 0.007 not applicable 0.0007 not applicable
Pentachloro-phenol 87-86-5 0.4 1 0.4 1
Benzo(a)pyrene 50-32-8 0.05 0.1 0.05 0.1
Benzo(b)fluor-anthene 205-99-2 Σ=0.03 not applicable Σ=0.03 not applicable
Benzo(k)fluor-anthene 207-08-9
Benzo(g,h,i)-perylene 191-24-2 Σ=0.002 not applicable Σ=0.002 not applicable
Indeno(1,2,3-cd)-pyrene 193-39-5
Simazine 122-34-9 1 4 1 4
Tetrachloro-ethylene 127-18-4 10 not applicable 10 not applicable
Trichloro-ethylene 79-01-6 10 not applicable 10 not applicable
Tributyltin compounds (Tributhyltin-cation) 36643-28-4 0.0002 0.0015 0.0002 0.0015
Trichloro-benzenes 12002-48-1 0.4 not applicable 0.4 not applicable
Trichloro-methane 67-66-3 2.5 not applicable 2.5 not applicable
Trifluralin 1582-09-8 0.03 not applicable 0.03 not applicable
1 This parameter is the Environmental Quality Standard expressed as an annual average value (AA-EQS). Unless otherwise specified, it applies to the total concentrations of all isomers of the pollutant concerned.
2 This parameter is the Environmental Quality Standard expressed as a maximum allowable concentration (MAC-EQS). Where the MAC-EQS are marked as  “not applicable”, the AA-EQS values are considered protective against short-term pollution peaks in continuous discharges since they are significantly lower than the values derived on the basis of acute toxicity.
3 For the group of priority substances covered by brominated diphenylethers listed in Decision 2455/2001/EC, an EQS is established only for congener numbers 28, 47, 99, 100, 153 and 154.
4 For cadmium and its compounds the EQS values vary dependent upon the hardness of the water as specified in five class categories (class 1: <40mg CaCO3/l, class 2: 40 to <50mg CaCO3/l, class 3: 50 to <100mg CaCO3/l, class 4: 100 to <200mg CaCO3/l and class 5: ≥200mg CaCO3/l).
5 DDT total comprises the sum of the isomers 1,1,1-trichloro-2,2 bis (p-chlorophenyl) ethane (CAS number 50-29-3; EU number 200-024-3); 1,1,1-trichloro-2 (o-chlorophenyl)-2-(p-chlorophenyl) ethane (CAS number 789-02-6; EU number 212-332-5); 1,1-dichloro-2,2 bis (p-chlorophenyl) ethylene (CAS number 72-55-9; EU number 200-784-6); and 1,1-dichloro-2,2 bis (p-chlorophenyl) ethane (CAS number 72-54-8; EU number 200-783-0).
6 If the Department does not apply standards for biota it shall introduce stricter standards for water in order to achieve the same level of protection as the standards for biota set out in regulation 4. The Department shall notify the European Commission of the reasons and basis for using this approach, the alternative standards used, the data and the methodology by which the alternative standards were derived and the categories of surface water to which they would apply.
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PART 4
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”
SCHEDULE 2

Reg 3(7)
“
SCHEDULE 2
PART 1
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PART 5
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SCHEDULE 3

Reg 3(8)
“
SCHEDULE 3
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SCHEDULE 4

Reg 3(9)
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SCHEDULE 5
PART 1
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PART 2
1 
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2 
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3 
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