@phdthesis{Weidenmueller2001, author = {Weidenm{\"u}ller, Anja}, title = {From individual behavior to collective structure}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-2448}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2001}, abstract = {The social organization of insect colonies has long fascinated naturalists. One of the main features of colony organization is division of labor, whereby each member of the colony specializes in a subset of all tasks required for successful group functioning. The most striking aspect of division of labor is its plasticity: workers switch between tasks in response to external challenges and internal perturbations. The mechanisms underlying flexible division of labor are far from being understood. In order to comprehend how the behavior of individuals gives rise to flexible collective behavior, several questions need to be addressed: We need to know how individuals acquire information about their colony's current demand situation; how they then adjust their behavior according; and which mechanisms integrate dozens or thousands of insect into a higher-order unit. With these questions in mind I have examined two examples of collective and flexible behavior in social bees. First, I addressed the question how a honey bee colony controls its pollen collection. Pollen foraging in honey bees is precisely organized and carefully regulated according to the colony's needs. How this is achieved is unclear. I investigated how foragers acquire information about their colony's pollen need and how they then adjust their behavior. A detailed documentation of pollen foragers in the hive under different pollen need conditions revealed that individual foragers modulate their in-hive working tempo according to the actual pollen need of the colony: Pollen foragers slowed down and stayed in the hive longer when pollen need was low and spent less time in the hive between foraging trips when pollen need of their colony was high. The number of cells inspected before foragers unloaded their pollen load did not change and thus presumably did not serve as cue to pollen need. In contrast, the trophallactic experience of pollen foragers changed with pollen need conditions: trophallactic contacts were shorter when pollen need was high and the number and probability of having short trophallactic contacts increased when pollen need increased. Thus, my results have provided support for the hypothesis that trophallactic experience is one of the various information pathways used by pollen foragers to assess their colony's pollen need. The second example of collective behavior I have examined in this thesis is the control of nest climate in bumble bee colonies, a system differing from pollen collection in honey bees in that information about task need (nest climate parameters) is directly available to all workers. I have shown that an increase in CO2 concentration and temperature level elicits a fanning response whereas an increase in relative humidity does not. The fanning response to temperature and CO2 was graded; the number of fanning bees increased with stimulus intensity. Thus, my study has evidenced flexible colony level control of temperature and CO2. Further, I have shown that the proportion of total work force a colony invests into nest ventilation does not change with colony size. However, the dynamic of the colony response changes: larger colonies show a faster response to perturbations of their colony environment than smaller colonies. Thus, my study has revealed a size-dependent change in the flexible colony behavior underlying homeostasis. I have shown that the colony response to perturbations in nest climate is constituted by workers who differ in responsiveness. Following a brief review of current ideas and models of self-organization and response thresholds in insect colonies, I have presented the first detailed investigation of interindividual variability in the responsiveness of all workers involved in a collective behavior. My study has revealed that bumble bee workers evidence consistent responses to certain stimulus levels and differ in their response thresholds. Some consistently respond to low stimulus intensities, others consistently respond to high stimulus intensities. Workers are stimulus specialists rather than task specialists. Further, I have demonstrated that workers of a colony differ in two other parameters of responsiveness: response probability and fanning activity. Response threshold, response probability and fanning activity are independent parameters of individual behavior. Besides demonstrating and quantifying interindividual variability, my study has provided empirical support for the idea of specialization through reinforcement. Response thresholds of fanning bees decreased over successive trials. I have discussed the importance of interindividual variability for specialization and the collective control of nest climate and present a general discussion of self-organization and selection. This study contributes to our understanding of individual behavior and collective structure in social insects. A fascinating picture of social organization is beginning to emerge. In place of centralized systems of communication and information transmission, insect societies frequently employ mechanisms based upon self-organization. Self-organization promises to be an important and unifying principle in physical, chemical and biological systems.}, subject = {Hummeln}, language = {en} } @phdthesis{Bluem2001, author = {Bl{\"u}m, Martina}, title = {Reaktivation and stabilization phases of eolian deposits under climatic and anthropogenic influences in the Rolling Plains of Texas, U.S.A.}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-1179360}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2001}, abstract = {There are ample sand dune and sand sheets in the Texas Rolling Plains, U.S.A. Their varied location, morphology and paleosol content pointed to differnces in their historical develpment throughout the Holocene. Younger dunes, so called fence line dunes have been identified as remnants of unsound agricultural practices which just recently formed at the beginning of this century. Correspondingly soils were eroded, in parts, down to the C-horizon in some of these areas. More mature sand were dated with the radiocarbon method and identified having formed during the Altithermal warming period. This study identifies major eolian anthropogenic and climatic reactivation and stabilisation phases in the Rolling Plains of Texas during the Holocene, but also ties them into the existing Southern High Plains and Great Plains climatic record. This study also researched the reasons for the regional and local sand reactivation phases and contributes to the eolian history in the Great Plains region. The outline of this dissertation is oriented towards a comprehensive regional approach in cultural and physical geography. Chapter 1 covers the physiographic setting of the Rolling Plains region including geology, geomorphology, climate and vegetation. Here the prerequisites for eolian activity in the area are explained, followed by the criteria for the selection of the individual study sites. In chapter 2 selected dune fields and sand sheets are introduced. Chapter 3 outlines the methodology as a combination of field research, laboratory analysis and remote sensing techniques, along with a brief interpretation of their application and success rate. Chapter 4 investigates interactive processes between the cultural development and the physical landscape of the region. The next 4 chapters are focusing on research results and interpretation. Chapter 5 interprets the youngest eolian episodes resulting from the cultural de-velopment of the area, including a description and definition of so called "fenceline dunes" and "shinnery motts". Other dunes with very young buried horizons are also described in this chapter, and a comparison with outcrops in the Nebraska Sand Hills is performed. Chapter 6 interprets short-term, cyclic, drought related sand reactivations several hundred years ago by means of a Post Oak (Quercus stellata) tree ring record as established by STAHLE and CLEAVELAND (1988). In chapter 7 older Holocene reactivation cycles are introduced, investigating the idea of the existence of a warmer period, previously named the Altithermal, which so far has only been identified in the Southern High Plains. The last chapter (8) includes a brief statement of the study's purpose along with the summary and discussion of results presented. This chapter will end with further implications of this research.}, subject = {Texas }, language = {en} }