FOUR (4) FACTORS AFFECTING DENSITY



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POPULATION SIZE REGULATION OF POPULATIONS POPULATION GROWTH RATES SPECIES INTERACTIONS DENSITY = NUMBER OF INDIVIDUALS PER UNIT AREA OR VOLUME POPULATION GROWTH = CHANGE IN DENSITY OVER TIME FOUR (4) FACTORS AFFECTING DENSITY NATALITY (+) IMMIGRATION (+) MORTALITY (-) FOUR (4) FACTORS AFFECTING DENSITY IMMIGRATION EMIGRATION ASSUME THESE TWO ARE EQUAL EMIGRATION DENSITY FUNCTIONS (CONT D) NATALITY: PROCESS OF ADDING NEW INDIVIDUALS TO POPUL. VIA BIRTHS FERTILITY = PERFORMANCE (ACTUAL?) BASED ON NUMBERS BORN (HUMANS) FECUNDITY = POTENTIAL LEVEL OF PERFORMANCE BASED UPON MEAN GESTATION TIME (HUMAN POPUL.) DENSITY FACTORS (CONT D) MORTALITY: DECREASE IN NUMBER OF INDIVIDUALS BY DEATH RATE PHYSIOLOGICAL LONGEVITY = MEAN LIFE SPAN UNDER OPTIMUM CONDITIONS SENESCENCE DEATH = OLD AGE ECOLOGICAL LONGEVITY = EMPERICAL MEAN LIFE SPAN UNDER ANY GIVEN CONDITIONS 1

DENSITY MEASUREMENTS ABSOLUTE DENSITY: TOTAL COUNTS (DIFFICULT/SOME ERROR) HUMAN POPULATION CENSUS BIRDS: ALL SINGING MALES INAREA LARGE PLANTS IN GIVEN AREA (TREES) DENSITY MEASUREMENTS (CONT D) DENSITY ESTIMATES USE OF QUADRATS (PLANTS, SMALL ANIMALS) CAPTURE-RECAPTURE (MOBILE POPUL) CLOSED: NOT CHANGE SIZE DURING SAMPLE PERIOD OPEN: CHANGES IN SIZE DURING SAMPLE PERIOD NOTE: REAL POPULATIONS ARE OPEN DENSITY ESTIMATES (CONT D) PETERSON INDEX: PROPORTIONAL COMPUTATION OF MARKED VS. UNMARKED INDIVIDUALS IN SAMPLE MARKED IND. = MARKED IN TOT. POPUL. TOTAL CAUGHT = TOTAL POPUL. SIZE POPULATION GROWTH RATE OF GROWTH: CHANGE IN NUMBERS PER UNIT TIME EXPONENTIAL GROWTH (UNRESTRICTED ENVIRONMENT) FUNCTION OF TWO (2) FACTORS SIZE OF POPULATION AT TIME ZERO CAPACITY OF POPULATION TO INCREASE (I.E., BIOTIC POTENTIAL) OR DECREASE IN SIZE OVER TIME INNATE CAPACITY FOR NATURAL INCREASE CHARACTERIZES J-SHAPED CURVE EXPONENTIAL GROWTH NET REPRODUCTION PER INDIVIDUAL PER UNIT OF TIME (r) = (BIRTH RATE PER INDIVIDUAL PER UNIT OF TIME) - (DEATH RATE PER INDIVIDUAL PER UNIT OF TIME) r = b - d N t +1 = r * N t 2

EXPONENTIAL GROWTH CURVE HUMAN POPULATION AGE CLASS DISTRIBRUTION HUMAN POPULATION MEANS OF COMPUTING r INNATE CAPACITY FOR NATURAL INCREASE LIFE TABLES SURVIVORSHIP CURVES r = b-d EFFECTS OF b-d ON POPULATION GROWTH BACTERIUM CULTURE PLOT GROWTH OF POPULATION OVER TIME BIOTIC POTENTIAL NOT CHANGE SIZE OF POPULATION CHANGES EXPONENTIALLY 3

EXPONENTIAL GROWTH EXPONENTIAL GROWTH NUMBERS J-SHAPED GROWTH CURVE N t = N 0 e rt dn/dt = r * N TIME dn t+1 /dt = r * N t NOTE: DEPENDENT & INDEPENDENT VARIABLES IN CURVE CHANGE THROUGH TIME r IS CONSTANT FOR ANY PARTICULAR POINT IN TIME FOR GIVEN ENVIRONMENTAL CONDITIONS # IND > RAPIDLY; RATE OF CHANGE REMAINS CONSTANT dn/dt = r * N r = BIOTIC POTENTIAL OR INTRINSIC RATE OF NATURAL INCREASE POPULATION GROWTH RATE DEFINED PER INDIVIDUAL (FEMALE) ASSUME UNCROWDED CONDITIONS STABLE AGE CLASS DISTRIBUTION POTENTIAL GROWTH VS. ACTUAL r IS AN INNATE QUALITY OF A SPECIES JUST AS MEAN WT., SIZE, ETC INNATE CAPCITY FOR NATURAL INCREASE SIMILAR TO MEAN LONGEVITY, NATALITY, GROWTH RATE FUNCTION OF: ENVIRONMENTAL CONDITIONS INTRINSIC NATURE OF SPECIES IN QUESTION DIFFICULT TO MEASURE DUE TO DUE TO CHANGING ENVIRONMENTAL CONDITIONS ATTEMPTS TO STANDARDIZE (OPTIMIZE) dn/dt = r * N SHOULD BE CLEAR FROM EQUATION: IF r = 1: NO CHANGE (GROWTH) IN POPULATION SIZE IF r < 1--DECREASE IN SIZE IF r > 1--INCREASE IN SIZE ORDER OF MAGNITUDE OF r DETERMINES RATE OF CHANGE IF r REMAINS CONSTANT, THEN RATE OF CHANGE IS CONSTANT 4

ASSUMPTIONS UNREALISTIC--BUT GOOD BEGINNING POINT FOR CONSIDERATION OF POPULATION MODELS BIOTIC POTENTIAL DOES NOT REMAIN CONSTANT IN NATURE ATTEMPTS TO MEASURE IN NATURE NOT SIMPLE r VARIES WITH ENVIRONMENTAL CONDITIONS, AGE DIST., GENETIC COMPOSITION, SOCIAL STRUCTURE, ETC.. S-SHAPED GROWTH CURVE LOGISTIC GROWTH =K LOGISTIC GROWTH: dn/dt = r*n(k-n/k) dn/dt = r*n dn/dt = r*n(k-n/k) K = MAXIMUM NUMBER OF INDIVIDUALS THAT CAN BE SUPPORTED BY THE ENVIRONMENT AT THAT TIME K = CARRYING CAPACITY MAXIMUM NUMBER OF INDIVIDUALS THAT CAN BE SUPPORTED (INDEFINITELY--ASSUMING EVERYTHING REMAINS THE SAME) INA GIVEN AREA (ENVIRONMENT) LOGISTIC GROWTH: dn/dt = r*n(k-n/k) (K-N/K) IS A MEASURE OF ENVIRONMENTAL RESISTANCE DIRECT EFFECT OF CROWDING REPRESENTS AN INVERSE MEASURE OF ENVIRONMENTAL RESISTANCE WHEN ENVIR. RESIST. IS LOW, VALUE OF (K-N/K) APPROACHES VALUE OF 1 VARIOUS FACTORS AFFECT K ANYTHING WHICH AFFECTS BIRTH RATE OR DEATH RATE WILL IMPACT K REGULATION OF POPULATION SIZE & RATE OF CHANGE DENSITY DEPENDENT FACTORS CROWDING EFFECT DENSITY INDEPENDENT FACTORS OTHER ENVIRONMENTAL RESISTANCE FACTORS CARRYING CAPACITY EFFECTS LOGISTIC GROWTH 5

DENSITY DEPENDENT FACTORS INTRINSIC-- POPULATION SIZE FACTORS EXTRINSIC--INTERACTIONS WITH OTHER PARTS OF COMMUNITY STRUCTURE PREDATION PARASITISM DISEASE STRESS (TERRITORIALITY INTRA & INTERSPECIFIC COMPETITION DENSITY INDEPENDENT FACTORS MANY CATASTOPHIC EVENTS OFTEN WEATHER RELATED MODIFICATION OF WEATHER CONDITIONS (REGIONAL?) FOOD QUALITY/QUANTITY NUTRIENT TYPE QUALITY & QUANTITY HABITAT SELECTION EXPONENTIAL GROWTH CURVE HUMAN POPULATION AGE CLASS DISTRIBRUTION HUMAN POPULATION SPECIES INTERACTIONS SPECIES DISTRIBUTION PATTERNS SPACING PATTERNS RANDOM CLUMPED (AGGREGATION) EVENLY SPACED--REGULAR-- (HYPERDISPERSION) EVALUATE TYPE OF DISPERSION (DISTRIBUTION) BY POISSON STATISTICS 6

SPECIES INTERACTIONS SPACING (PATTERNS OF DISTRIBUTION) PREDATOR-PREY INTERACTIONS INTERSPECIFIC COMPETITION EFFECTIVENESS OF COMPETITION LOTKA-VOLTERRA MODELS TWO SPECIES INTERACTIONS PREDATOR-PREY INTERACTIONS TIME LAGS COMPETITIVE INTERACTIONS INTRERSPECIFIC COMPETITION OCCURS WITH SYMPATRIC DISTRIBUTION OF TWO/MORE SPECIES IN SAME AREA PREDATOR-PREY INTERACTIONS TIME LAG EFFECTS ARRAY OF FACTORS AFFECTING EACH SPECIES IN QUESTION INDEPENDENT OF DIRECT INTERSPECIFIC COMPETITION INTERSPECIFIC COMPETITION WILL OCCUR WITH SYMPATRIC DISTRIBUTION OF TWO OR MORE SPECIES DEGREE OF INTERACTION (SEPARATION) MAY BE DEFINED WITH RESPECT TO SPECIFIC RESOURCES FOOD SIZE PREFERENCE EFFECTIVENESS OF COMPETTION ABILITY OF ONE SPECIES TO UTILIZE AVAILABLE RESOURCES THAN THE OTHER KEY LIMITING RESOURCES, OR MANY OTHERS FUNCTION OF ENVIRONMENTAL CONDITIONS GENETIC/SOCIAL STRUCTURE FACTORS SUPPORTED BY LAB STUDIES TEMP VARIATION, HUMIDITY, FOOD QUAL & QUANTITY, ACCUM. WASTE PRODUCTS COMPETITIVE EXCLUSION GAUSE: NO TWO (2) SPECIES CAN EXIST (SURVIVE) ON SAME LIMITING RESOURCES AT SAME TIME ALL OF THE TIME SPECIES WITH IDENTICAL RESOURCE REQUIREMENTS CANNOT CO-EXIST CONCEPT OF NICHE, NICHE OVERLAP 7

COMPETITIVE EXCLUSION PRINCIPLE (GAUSE) NO TWO (2) SPECIES CAN EXIST (SURVIVE) ON THE SAME LIMITING RSOURCE...AT THE SAME TIME, ALL OF THE TIME SPECIES WITH IDENTICAL RESOURCE REQUIREMENTS CANNOT CO-EXIST LEADS TO CONCEPT OF NICHE, NICHE OVERLAP, ETC. (LATER DISCUSSIONS) CONCEPT OF NICHE, NICHE OVERLAP 8

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