1 / 45

Management of Small Impoundments

Management of Small Impoundments. Chapters 21 (22). Introduction. Pond = small impoundment <0.4 ha – 40 ha 0.2 ha – 2.4 ha (AFS Central States Pond Management Work Group) Dam constructed to impound water Various water sources Springs, streams, precipitation, runoff. Introduction.

farica
Download Presentation

Management of Small Impoundments

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Management of Small Impoundments Chapters 21 (22)

  2. Introduction • Pond = small impoundment • <0.4 ha – 40 ha • 0.2 ha – 2.4 ha (AFS Central States Pond Management Work Group) • Dam constructed to impound water • Various water sources • Springs, streams, precipitation, runoff

  3. Introduction • Usually privately owned • Farm ponds • Livestock water • Irrigation • Most numerous in central and southeast • Important contribution to sportfishing • Rarely regulated as a “water of the US”

  4. Management Philosophy • Sustained or improved fishing quality • High catch rates and above-average sizes

  5. Multiple Uses of Ponds • Boating • Fishing • Livestock • Bird hunting • Swimming • Aesthetics

  6. Ecological Principles • Trophic Relationships • Productivity and Biomass

  7. Ecological Principles • Carrying capacity: max mass or density supported over a certain time period • K Density Fish Size

  8. Ecological Principles • Average Fish Size varies as a function of overall pond productivity and population density

  9. Ecological Principles • Influence of Aquatic Vegetation • Increased primary productivity • Decreased predator foraging efficiency • Decreased harvest efficiency • Dense prey populations • Stunted predator populations

  10. Pond Types and Management Options • Warmwater • Bass and bluegill, sometimes catfish • Fall, winter, spring trout (summer kills) • Most Common and Most research • Coldwater • Trout, usually stocked • Coolwater • Rare; Walleye, hybrid striped bass, perch, etc.

  11. All-Purpose Option • Harvest of LMB, BG, and CC • 30-38 cm (12-15 in) slot limit for LMB after 4 years • Reduces mid-size BG and allow some BG to reach 8 in • Harvest 75 LMB per ha (8-12 in) • Harvest BG and CC at will • Importance of LMB slot limit • Over harvest = Over population of BG • Release slot fish and smaller = Over population and stunting of LBM

  12. Harvest Quota Option • Due to problems with length limits • Set harvest independent of length • Quota on number or weight per time • Difficult: • Need accurate record keeping • Tend to overharvest larger LMB and underharvest small LMB • Harvest BG and CC at will • Harvest 3-10 times the amount of LMB • C/R after quota is reached

  13. Panfish Option • Big panfish instead of LMB • 15 in min length for LMB • Abundance of 8-15 in LMB reduce BG density • Large BG survive and grow > 8 in • Small LMB generally • May compete with BG (remove some) • Easy: unmanaged ponds tend to move in this direction

  14. Big BASS Option • Reduce number of LMB 8-15 inches so remaining individuals grow large • Harvest 75 LMB 8-12 in and 13 LMB 12-15 in per ha per year • Release all LMB > 15 inches (except bucket mouths) • Stock gizzard shad as prey for large LMB • Catch rate is low but sizes are large • Larger ponds • Numerous small BG may reduce recruitment of LMB

  15. Catfish Only Option • In muddy or small ponds • No structure for spawning or they overpopulate and stunt • Fathead minnow prey • Unrestricted harvest • Restocking to replace harvested fish

  16. Black Bass Only Option • Shallow, weedy ponds with too much cover (BG stunting) • Feed on crayfish, bugs, own young • Need several year classes stocked • Prevents development of dominant year class • Inefficient use of pond resources?

  17. Trout Options • Coldwater ponds—spring fed • Usually rainbow trout • Easy to control by stocking rates (won’t reproduce in standing water—brook trout will) • Must Restock • Become accustomed to formulated fish foods • Fee-fishing ponds

  18. “All Purpose” Recipe • Initial Pond Survey • Population Status • Electrofishing and seining • Assess population “balance” • Alkalinity • Aquatic Weeds

  19. “All Purpose” Recipe • Kill the Pond • Initial Stocking • Forage species (bluegill, shell crackers, fat head minnows) • Predator species (largemouth bass) • Stocking Rates • Supplemental Stocking • Essential in large ponds (>2 acres) • Threadfin shad, golden shiners)

  20. “All Purpose” Recipe • Liming • Essential if pH < 7 and Alkalinity < 20 ppm • Agricultural limestone • Why useful?

  21. “All Purpose” Recipe • Fertilization • Can triple productivity • Can cause unwanted algal blooms • Once started, difficult to stop • Granular, water soluble, liquid

  22. “All Purpose” Recipe • Supplemental Feeding • Dramatically increase size and growth of BG and LMB. • Only recommended if Trophy Bass is the management objective. • Same negatives as fertilizer.

  23. “All Purpose” Recipe • Aquatic Vegetation Control • Optimum level at 20% in TX reservoir • Optimum level at 36% in IL pond

  24. Aquatic Vegetation • Natural Succession of lentic systems • Depressions accumulate material • Increased organic matter and nutrients • Cultural Eutrophication • Ponds become increasingly susceptible to nuisance algae and vegetation

  25. Aquatic Vegetation Control • Mechanical: • Harvesting and Dredging • Shading • Draw Down

  26. Aquatic Vegetation Control • Chemical: Herbicides • Copper sulfate • Nutrients stay • Depletes DO • Effective, quick, cheap in small impoundments

  27. Aquatic Vegetation Control • Biological • Grass carp • Non-native, illegal in some states • Escape hatcheries and reproduce • Triploid variety infertile • Can completely eliminate vegetation, eat invertebrates (crayfish) • Nutrients stay (convert macrophytes to phytoplankton) • Barley Straw • May inhibit additional algal growth • Mechanism uncertain: fungal chemicals? • Nutrients stay

  28. “All Purpose” Recipe • Aerators and Destratifiers • Often necessary in fertilized ponds or ponds that receive high nutrient runoff. • Avoid stratification and extremely low oxygen levels. • Expensive (especially with increasing gas prices)

  29. 8” 12” trophy No harvest harvest harvest “All Purpose” Recipe • Harvest Control • Limit over harvest • Maintain population “balance” • Minimum length limits • Low recruitment situations • Protects individuals until they reach maturity • Slot Limits • High recruitment where minimum length limits will lead to overpopulation and stunting • Grows bigger fish • Must harvest small fish

  30. Balance and Population Analysis • Are stocked ponds really in balance? • Likelihood declines with ponds that are simple are artificial • Artificial ecosystems? Must manage hard to get what you want • Big aquarium? • Ponds with a natural assemblage within a natural habitat are more likely to be a self-sustainable ecosystem • Diversity of habitat • Sustained source of water • Prey diversity

  31. Balanced Fish Populations • Characteristics • Continual reproduction of predator and prey • Diversity of prey for all predators • High growth rates • Harvestable fish in proportion to pond fertility

  32. Balanced Fish Populations • Indices to assess balance • Biomass Indices • Length-Frequencies Indices • Abundance-Weight Indices

  33. Biomass Indices: F:C Ratio • Total weight of all forage fishes (F) / total weight of all carnivorous fishes (C) • 3-6 = good • 1.4-10 = balanced • Low = too many carnivores • High = too many forage fishes

  34. Biomass Indices: Y:C ratio • Total weight of forage fishes small enough to be consumed by the average sized carnivore / Total weight of all carnivorous fishes (C) • 1-3 = good • 0.02-5 = balanced • Low = too many carnivores • High = too many forage fishes

  35. Biomass Indices: AT value • Total availability value • % that is “harvestable” • Total weight of harvestable fish / total weight of all fish • Need to define minimum weight harvestable • 60-85% = good • Low = stunted • High = too many big carnivores

  36. Length-Frequency Indices: Proportional stock Density (PSD) • # fish of a given species greater than or equal to quality length / # fish greater than or equal to stock length X 100 • Quality Length – size most anglers like to catch • Stock Length – size at which fish reach sexual maturity, minimum “recreational” length • 40-70 balance for LMB • 20-60 balance for BG • % of fish attractive to anglers

  37. Length-Frequency Indices: Relative stock Density (RSD) • # fish of a given species greater than or equal to length you want / # fish greater than or equal to stock length X 100 • Must ID the size you want • Special case of PSD • More sensitive to recognizing quality of the stock

  38. Pop 1 PSD = 50 RSD-38 = 0 PSD = quality size/stock size RSE = other size/stock size Pop 2 PSD = 50 RSD-38 = 15 Comparing PSD and RSD

  39. PSD and RSD: Size Categories • Base on percentage of world record lengths • Stock Length = 20-26% of the world record length for the species (LMB 20 cm) • Quality Length = 36-41% (LMB 30 cm) • Preferred Length (LMB 38 cm) • Memorable Length (LMB 51 cm) • Trophy Size = 80% (LMB 63 cm) • Table 21.1

  40. Abundance and Weight Indices • Relative Weight (Wr) • Measured weight (Wt) / predicted or standard weight (Ws)

  41. Length-Weight Relation • W = aLb • Exponential relationship • W is a function of L to some power • a (constant) and b are parameters from L vs W relation • log W = log a + b log L • Equation for a line! • Ws =standard weight LMB Length-Weight relation

  42. W = a L b • b = 3 • Isometric growth • Growing in all directions in proportion • Shape is not changing (rare) • b ≠ 3 • Allometric growth • Growing faster in girth than length or vise versa; changing shape • More common growth • Old fish grow more in girth than length

  43. Wr = Wt / Ws • Do fish weight what they should • < 85 = underweight and too abundant • 100 = in balance with food supply • > 105 = too plump; pond can support more fish

  44. Standard Weight Equations Largemouth Bass: Log10 Ws = -5.528 + 3.273 Log10 L Bluegill: Log10 Ws = -5.374 + 3.316 Log10 L Channel Catfish: Log10 Ws = -5.800 + 3.294 Log10 L

  45. Internet Resources • State Fish and Wildlife Agencies • http://www.tpwd.state.tx.us/fish/infish/ponds/ (TX) • http://www.dgif.state.va.us/fishing/Pond_Management/index.html (VA) • Cooperative Extension Services • http://www.wvdnr.gov/Fishing/FarmPondMgmt.shtm (WV) • http://msucares.com/wildfish/fisheries/farmpond/management/ (MS) • http://www.aces.edu/pubs/docs/A/ANR-0577/ (AL) • http://www.dnr.cornell.edu/ext/fish/pond1.htm (NY)

More Related